mirror of
https://github.com/alliedmodders/amxmodx.git
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425 lines
15 KiB
Groff
425 lines
15 KiB
Groff
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.\" Start example.
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.de EX
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. nr mE \\n(.f
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. nf
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. nh
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. ft CW
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..
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.
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.
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.\" End example.
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.de EE
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. ft \\n(mE
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. fi
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. hy \\n(HY
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..
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.
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.EX
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/*************************************************
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* PCRE DEMONSTRATION PROGRAM *
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*************************************************/
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/* This is a demonstration program to illustrate the most straightforward ways
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of calling the PCRE regular expression library from a C program. See the
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pcresample documentation for a short discussion ("man pcresample" if you have
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the PCRE man pages installed).
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In Unix-like environments, if PCRE is installed in your standard system
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libraries, you should be able to compile this program using this command:
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gcc -Wall pcredemo.c -lpcre -o pcredemo
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If PCRE is not installed in a standard place, it is likely to be installed with
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support for the pkg-config mechanism. If you have pkg-config, you can compile
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this program using this command:
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gcc -Wall pcredemo.c `pkg-config --cflags --libs libpcre` -o pcredemo
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If you do not have pkg-config, you may have to use this:
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gcc -Wall pcredemo.c -I/usr/local/include -L/usr/local/lib \e
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-R/usr/local/lib -lpcre -o pcredemo
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Replace "/usr/local/include" and "/usr/local/lib" with wherever the include and
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library files for PCRE are installed on your system. Only some operating
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systems (e.g. Solaris) use the -R option.
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Building under Windows:
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If you want to statically link this program against a non-dll .a file, you must
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define PCRE_STATIC before including pcre.h, otherwise the pcre_malloc() and
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pcre_free() exported functions will be declared __declspec(dllimport), with
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unwanted results. So in this environment, uncomment the following line. */
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/* #define PCRE_STATIC */
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#include <stdio.h>
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#include <string.h>
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#include <pcre.h>
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#define OVECCOUNT 30 /* should be a multiple of 3 */
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int main(int argc, char **argv)
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{
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pcre *re;
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const char *error;
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char *pattern;
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char *subject;
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unsigned char *name_table;
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unsigned int option_bits;
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int erroffset;
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int find_all;
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int crlf_is_newline;
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int namecount;
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int name_entry_size;
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int ovector[OVECCOUNT];
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int subject_length;
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int rc, i;
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int utf8;
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/**************************************************************************
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* First, sort out the command line. There is only one possible option at *
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* the moment, "-g" to request repeated matching to find all occurrences, *
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* like Perl's /g option. We set the variable find_all to a non-zero value *
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* if the -g option is present. Apart from that, there must be exactly two *
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* arguments. *
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**************************************************************************/
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find_all = 0;
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for (i = 1; i < argc; i++)
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{
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if (strcmp(argv[i], "-g") == 0) find_all = 1;
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else break;
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}
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/* After the options, we require exactly two arguments, which are the pattern,
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and the subject string. */
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if (argc - i != 2)
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{
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printf("Two arguments required: a regex and a subject string\en");
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return 1;
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}
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pattern = argv[i];
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subject = argv[i+1];
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subject_length = (int)strlen(subject);
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/*************************************************************************
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* Now we are going to compile the regular expression pattern, and handle *
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* and errors that are detected. *
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*************************************************************************/
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re = pcre_compile(
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pattern, /* the pattern */
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0, /* default options */
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&error, /* for error message */
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&erroffset, /* for error offset */
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NULL); /* use default character tables */
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/* Compilation failed: print the error message and exit */
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if (re == NULL)
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{
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printf("PCRE compilation failed at offset %d: %s\en", erroffset, error);
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return 1;
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}
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/*************************************************************************
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* If the compilation succeeded, we call PCRE again, in order to do a *
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* pattern match against the subject string. This does just ONE match. If *
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* further matching is needed, it will be done below. *
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*************************************************************************/
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rc = pcre_exec(
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re, /* the compiled pattern */
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NULL, /* no extra data - we didn't study the pattern */
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subject, /* the subject string */
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subject_length, /* the length of the subject */
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0, /* start at offset 0 in the subject */
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0, /* default options */
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ovector, /* output vector for substring information */
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OVECCOUNT); /* number of elements in the output vector */
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/* Matching failed: handle error cases */
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if (rc < 0)
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{
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switch(rc)
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{
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case PCRE_ERROR_NOMATCH: printf("No match\en"); break;
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/*
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Handle other special cases if you like
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*/
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default: printf("Matching error %d\en", rc); break;
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}
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pcre_free(re); /* Release memory used for the compiled pattern */
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return 1;
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}
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/* Match succeded */
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printf("\enMatch succeeded at offset %d\en", ovector[0]);
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/*************************************************************************
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* We have found the first match within the subject string. If the output *
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* vector wasn't big enough, say so. Then output any substrings that were *
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* captured. *
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*************************************************************************/
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/* The output vector wasn't big enough */
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if (rc == 0)
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{
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rc = OVECCOUNT/3;
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printf("ovector only has room for %d captured substrings\en", rc - 1);
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}
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/* Show substrings stored in the output vector by number. Obviously, in a real
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application you might want to do things other than print them. */
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for (i = 0; i < rc; i++)
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{
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char *substring_start = subject + ovector[2*i];
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int substring_length = ovector[2*i+1] - ovector[2*i];
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printf("%2d: %.*s\en", i, substring_length, substring_start);
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}
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/**************************************************************************
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* That concludes the basic part of this demonstration program. We have *
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* compiled a pattern, and performed a single match. The code that follows *
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* shows first how to access named substrings, and then how to code for *
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* repeated matches on the same subject. *
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**************************************************************************/
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/* See if there are any named substrings, and if so, show them by name. First
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we have to extract the count of named parentheses from the pattern. */
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(void)pcre_fullinfo(
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re, /* the compiled pattern */
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NULL, /* no extra data - we didn't study the pattern */
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PCRE_INFO_NAMECOUNT, /* number of named substrings */
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&namecount); /* where to put the answer */
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if (namecount <= 0) printf("No named substrings\en"); else
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{
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unsigned char *tabptr;
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printf("Named substrings\en");
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/* Before we can access the substrings, we must extract the table for
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translating names to numbers, and the size of each entry in the table. */
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(void)pcre_fullinfo(
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re, /* the compiled pattern */
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NULL, /* no extra data - we didn't study the pattern */
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PCRE_INFO_NAMETABLE, /* address of the table */
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&name_table); /* where to put the answer */
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(void)pcre_fullinfo(
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re, /* the compiled pattern */
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NULL, /* no extra data - we didn't study the pattern */
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PCRE_INFO_NAMEENTRYSIZE, /* size of each entry in the table */
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&name_entry_size); /* where to put the answer */
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/* Now we can scan the table and, for each entry, print the number, the name,
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and the substring itself. */
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tabptr = name_table;
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for (i = 0; i < namecount; i++)
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{
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int n = (tabptr[0] << 8) | tabptr[1];
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printf("(%d) %*s: %.*s\en", n, name_entry_size - 3, tabptr + 2,
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ovector[2*n+1] - ovector[2*n], subject + ovector[2*n]);
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tabptr += name_entry_size;
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}
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}
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/*************************************************************************
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* If the "-g" option was given on the command line, we want to continue *
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* to search for additional matches in the subject string, in a similar *
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* way to the /g option in Perl. This turns out to be trickier than you *
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* might think because of the possibility of matching an empty string. *
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* What happens is as follows: *
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* *
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* If the previous match was NOT for an empty string, we can just start *
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* the next match at the end of the previous one. *
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* *
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* If the previous match WAS for an empty string, we can't do that, as it *
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* would lead to an infinite loop. Instead, a special call of pcre_exec() *
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* is made with the PCRE_NOTEMPTY_ATSTART and PCRE_ANCHORED flags set. *
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* The first of these tells PCRE that an empty string at the start of the *
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* subject is not a valid match; other possibilities must be tried. The *
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* second flag restricts PCRE to one match attempt at the initial string *
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* position. If this match succeeds, an alternative to the empty string *
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* match has been found, and we can print it and proceed round the loop, *
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* advancing by the length of whatever was found. If this match does not *
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* succeed, we still stay in the loop, advancing by just one character. *
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* In UTF-8 mode, which can be set by (*UTF8) in the pattern, this may be *
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* more than one byte. *
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* *
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* However, there is a complication concerned with newlines. When the *
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* newline convention is such that CRLF is a valid newline, we must *
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* advance by two characters rather than one. The newline convention can *
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* be set in the regex by (*CR), etc.; if not, we must find the default. *
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*************************************************************************/
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if (!find_all) /* Check for -g */
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{
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pcre_free(re); /* Release the memory used for the compiled pattern */
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return 0; /* Finish unless -g was given */
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}
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/* Before running the loop, check for UTF-8 and whether CRLF is a valid newline
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sequence. First, find the options with which the regex was compiled; extract
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the UTF-8 state, and mask off all but the newline options. */
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(void)pcre_fullinfo(re, NULL, PCRE_INFO_OPTIONS, &option_bits);
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utf8 = option_bits & PCRE_UTF8;
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option_bits &= PCRE_NEWLINE_CR|PCRE_NEWLINE_LF|PCRE_NEWLINE_CRLF|
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PCRE_NEWLINE_ANY|PCRE_NEWLINE_ANYCRLF;
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/* If no newline options were set, find the default newline convention from the
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build configuration. */
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if (option_bits == 0)
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{
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int d;
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(void)pcre_config(PCRE_CONFIG_NEWLINE, &d);
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/* Note that these values are always the ASCII ones, even in
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EBCDIC environments. CR = 13, NL = 10. */
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option_bits = (d == 13)? PCRE_NEWLINE_CR :
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(d == 10)? PCRE_NEWLINE_LF :
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(d == (13<<8 | 10))? PCRE_NEWLINE_CRLF :
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(d == -2)? PCRE_NEWLINE_ANYCRLF :
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(d == -1)? PCRE_NEWLINE_ANY : 0;
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}
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/* See if CRLF is a valid newline sequence. */
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crlf_is_newline =
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option_bits == PCRE_NEWLINE_ANY ||
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option_bits == PCRE_NEWLINE_CRLF ||
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option_bits == PCRE_NEWLINE_ANYCRLF;
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/* Loop for second and subsequent matches */
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for (;;)
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{
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int options = 0; /* Normally no options */
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int start_offset = ovector[1]; /* Start at end of previous match */
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/* If the previous match was for an empty string, we are finished if we are
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at the end of the subject. Otherwise, arrange to run another match at the
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same point to see if a non-empty match can be found. */
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if (ovector[0] == ovector[1])
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{
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if (ovector[0] == subject_length) break;
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options = PCRE_NOTEMPTY_ATSTART | PCRE_ANCHORED;
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}
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/* Run the next matching operation */
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rc = pcre_exec(
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re, /* the compiled pattern */
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NULL, /* no extra data - we didn't study the pattern */
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subject, /* the subject string */
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subject_length, /* the length of the subject */
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start_offset, /* starting offset in the subject */
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options, /* options */
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ovector, /* output vector for substring information */
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OVECCOUNT); /* number of elements in the output vector */
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/* This time, a result of NOMATCH isn't an error. If the value in "options"
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is zero, it just means we have found all possible matches, so the loop ends.
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Otherwise, it means we have failed to find a non-empty-string match at a
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point where there was a previous empty-string match. In this case, we do what
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Perl does: advance the matching position by one character, and continue. We
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do this by setting the "end of previous match" offset, because that is picked
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up at the top of the loop as the point at which to start again.
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There are two complications: (a) When CRLF is a valid newline sequence, and
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the current position is just before it, advance by an extra byte. (b)
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Otherwise we must ensure that we skip an entire UTF-8 character if we are in
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UTF-8 mode. */
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if (rc == PCRE_ERROR_NOMATCH)
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{
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if (options == 0) break; /* All matches found */
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ovector[1] = start_offset + 1; /* Advance one byte */
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if (crlf_is_newline && /* If CRLF is newline & */
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start_offset < subject_length - 1 && /* we are at CRLF, */
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subject[start_offset] == '\er' &&
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subject[start_offset + 1] == '\en')
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ovector[1] += 1; /* Advance by one more. */
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else if (utf8) /* Otherwise, ensure we */
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{ /* advance a whole UTF-8 */
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while (ovector[1] < subject_length) /* character. */
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{
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if ((subject[ovector[1]] & 0xc0) != 0x80) break;
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ovector[1] += 1;
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}
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}
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continue; /* Go round the loop again */
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}
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/* Other matching errors are not recoverable. */
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if (rc < 0)
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{
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printf("Matching error %d\en", rc);
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pcre_free(re); /* Release memory used for the compiled pattern */
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return 1;
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}
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/* Match succeded */
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printf("\enMatch succeeded again at offset %d\en", ovector[0]);
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/* The match succeeded, but the output vector wasn't big enough. */
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if (rc == 0)
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{
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rc = OVECCOUNT/3;
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printf("ovector only has room for %d captured substrings\en", rc - 1);
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}
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/* As before, show substrings stored in the output vector by number, and then
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also any named substrings. */
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for (i = 0; i < rc; i++)
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{
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char *substring_start = subject + ovector[2*i];
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int substring_length = ovector[2*i+1] - ovector[2*i];
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printf("%2d: %.*s\en", i, substring_length, substring_start);
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}
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if (namecount <= 0) printf("No named substrings\en"); else
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{
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unsigned char *tabptr = name_table;
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printf("Named substrings\en");
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for (i = 0; i < namecount; i++)
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{
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int n = (tabptr[0] << 8) | tabptr[1];
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printf("(%d) %*s: %.*s\en", n, name_entry_size - 3, tabptr + 2,
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ovector[2*n+1] - ovector[2*n], subject + ovector[2*n]);
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tabptr += name_entry_size;
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}
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}
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} /* End of loop to find second and subsequent matches */
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printf("\en");
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pcre_free(re); /* Release memory used for the compiled pattern */
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return 0;
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}
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/* End of pcredemo.c */
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.EE
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