зеркало из https://github.com/github/putty.git
460 строки
13 KiB
C
460 строки
13 KiB
C
/*
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* Wildcard matching engine for use with SFTP-based file transfer
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* programs (PSFTP, new-look PSCP): since SFTP has no notion of
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* getting the remote side to do globbing (and rightly so) we have
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* to do it locally, by retrieving all the filenames in a directory
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* and checking each against the wildcard pattern.
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*/
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#include <assert.h>
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#include <stdlib.h>
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#include <string.h>
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/*
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* Definition of wildcard syntax:
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*
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* - * matches any sequence of characters, including zero.
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* - ? matches exactly one character which can be anything.
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* - [abc] matches exactly one character which is a, b or c.
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* - [a-f] matches anything from a through f.
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* - [^a-f] matches anything _except_ a through f.
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* - [-_] matches - or _; [^-_] matches anything else. (The - is
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* non-special if it occurs immediately after the opening
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* bracket or ^.)
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* - [a^] matches an a or a ^. (The ^ is non-special if it does
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* _not_ occur immediately after the opening bracket.)
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* - \*, \?, \[, \], \\ match the single characters *, ?, [, ], \.
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* - All other characters are non-special and match themselves.
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*/
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/*
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* The wildcard matching technique we use is very simple and
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* potentially O(N^2) in running time, but I don't anticipate it
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* being that bad in reality (particularly since N will be the size
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* of a filename, which isn't all that much). Perhaps one day, once
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* PuTTY has grown a regexp matcher for some other reason, I might
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* come back and reimplement wildcards by translating them into
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* regexps or directly into NFAs; but for the moment, in the
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* absence of any other need for the NFA->DFA translation engine,
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* anything more than the simplest possible wildcard matcher is
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* vast code-size overkill.
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*
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* Essentially, these wildcards are much simpler than regexps in
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* that they consist of a sequence of rigid fragments (? and [...]
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* can never match more or less than one character) separated by
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* asterisks. It is therefore extremely simple to look at a rigid
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* fragment and determine whether or not it begins at a particular
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* point in the test string; so we can search along the string
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* until we find each fragment, then search for the next. As long
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* as we find each fragment in the _first_ place it occurs, there
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* will never be a danger of having to backpedal and try to find it
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* again somewhere else.
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*/
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enum {
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WC_TRAILINGBACKSLASH = 1,
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WC_UNCLOSEDCLASS,
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WC_INVALIDRANGE
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};
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/*
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* Error reporting is done by returning various negative values
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* from the wildcard routines. Passing any such value to wc_error
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* will give a human-readable message.
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*/
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const char *wc_error(int value)
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{
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value = abs(value);
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switch (value) {
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case WC_TRAILINGBACKSLASH:
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return "'\' occurred at end of string (expected another character)";
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case WC_UNCLOSEDCLASS:
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return "expected ']' to close character class";
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case WC_INVALIDRANGE:
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return "character range was not terminated (']' just after '-')";
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}
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return "INTERNAL ERROR: unrecognised wildcard error number";
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}
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/*
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* This is the routine that tests a target string to see if an
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* initial substring of it matches a fragment. If successful, it
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* returns 1, and advances both `fragment' and `target' past the
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* fragment and matching substring respectively. If unsuccessful it
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* returns zero. If the wildcard fragment suffers a syntax error,
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* it returns <0 and the precise value indexes into wc_error.
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*/
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static int wc_match_fragment(const char **fragment, const char **target)
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{
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const char *f, *t;
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f = *fragment;
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t = *target;
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/*
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* The fragment terminates at either the end of the string, or
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* the first (unescaped) *.
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*/
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while (*f && *f != '*' && *t) {
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/*
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* Extract one character from t, and one character's worth
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* of pattern from f, and step along both. Return 0 if they
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* fail to match.
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*/
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if (*f == '\\') {
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/*
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* Backslash, which means f[1] is to be treated as a
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* literal character no matter what it is. It may not
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* be the end of the string.
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*/
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if (!f[1])
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return -WC_TRAILINGBACKSLASH; /* error */
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if (f[1] != *t)
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return 0; /* failed to match */
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f += 2;
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} else if (*f == '?') {
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/*
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* Question mark matches anything.
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*/
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f++;
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} else if (*f == '[') {
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int invert = 0;
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int matched = 0;
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/*
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* Open bracket introduces a character class.
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*/
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f++;
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if (*f == '^') {
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invert = 1;
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f++;
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}
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while (*f != ']') {
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if (*f == '\\')
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f++; /* backslashes still work */
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if (!*f)
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return -WC_UNCLOSEDCLASS; /* error again */
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if (f[1] == '-') {
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int lower, upper, ourchr;
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lower = (unsigned char) *f++;
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f++; /* eat the minus */
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if (*f == ']')
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return -WC_INVALIDRANGE; /* different error! */
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if (*f == '\\')
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f++; /* backslashes _still_ work */
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if (!*f)
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return -WC_UNCLOSEDCLASS; /* error again */
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upper = (unsigned char) *f++;
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ourchr = (unsigned char) *t;
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if (lower > upper) {
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int t = lower; lower = upper; upper = t;
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}
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if (ourchr >= lower && ourchr <= upper)
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matched = 1;
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} else {
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matched |= (*t == *f++);
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}
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}
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if (invert == matched)
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return 0; /* failed to match character class */
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f++; /* eat the ] */
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} else {
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/*
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* Non-special character matches itself.
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*/
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if (*f != *t)
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return 0;
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f++;
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}
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/*
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* Now we've done that, increment t past the character we
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* matched.
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*/
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t++;
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}
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if (!*f || *f == '*') {
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/*
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* We have reached the end of f without finding a mismatch;
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* so we're done. Update the caller pointers and return 1.
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*/
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*fragment = f;
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*target = t;
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return 1;
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}
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/*
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* Otherwise, we must have reached the end of t before we
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* reached the end of f; so we've failed. Return 0.
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*/
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return 0;
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}
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/*
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* This is the real wildcard matching routine. It returns 1 for a
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* successful match, 0 for an unsuccessful match, and <0 for a
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* syntax error in the wildcard.
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*/
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int wc_match(const char *wildcard, const char *target)
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{
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int ret;
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/*
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* Every time we see a '*' _followed_ by a fragment, we just
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* search along the string for a location at which the fragment
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* matches. The only special case is when we see a fragment
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* right at the start, in which case we just call the matching
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* routine once and give up if it fails.
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*/
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if (*wildcard != '*') {
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ret = wc_match_fragment(&wildcard, &target);
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if (ret <= 0)
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return ret; /* pass back failure or error alike */
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}
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while (*wildcard) {
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assert(*wildcard == '*');
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while (*wildcard == '*')
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wildcard++;
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/*
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* It's possible we've just hit the end of the wildcard
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* after seeing a *, in which case there's no need to
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* bother searching any more because we've won.
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*/
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if (!*wildcard)
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return 1;
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/*
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* Now `wildcard' points at the next fragment. So we
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* attempt to match it against `target', and if that fails
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* we increment `target' and try again, and so on. When we
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* find we're about to try matching against the empty
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* string, we give up and return 0.
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*/
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ret = 0;
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while (*target) {
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const char *save_w = wildcard, *save_t = target;
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ret = wc_match_fragment(&wildcard, &target);
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if (ret < 0)
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return ret; /* syntax error */
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if (ret > 0 && !*wildcard && *target) {
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/*
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* Final special case - literally.
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*
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* This situation arises when we are matching a
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* _terminal_ fragment of the wildcard (that is,
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* there is nothing after it, e.g. "*a"), and it
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* has matched _too early_. For example, matching
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* "*a" against "parka" will match the "a" fragment
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* against the _first_ a, and then (if it weren't
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* for this special case) matching would fail
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* because we're at the end of the wildcard but not
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* at the end of the target string.
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*
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* In this case what we must do is measure the
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* length of the fragment in the target (which is
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* why we saved `target'), jump straight to that
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* distance from the end of the string using
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* strlen, and match the same fragment again there
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* (which is why we saved `wildcard'). Then we
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* return whatever that operation returns.
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*/
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target = save_t + strlen(save_t) - (target - save_t);
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wildcard = save_w;
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return wc_match_fragment(&wildcard, &target);
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}
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if (ret > 0)
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break;
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target++;
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}
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if (ret > 0)
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continue;
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return 0;
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}
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/*
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* If we reach here, it must be because we successfully matched
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* a fragment and then found ourselves right at the end of the
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* wildcard. Hence, we return 1 if and only if we are also
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* right at the end of the target.
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*/
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return (*target ? 0 : 1);
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}
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/*
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* Another utility routine that translates a non-wildcard string
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* into its raw equivalent by removing any escaping backslashes.
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* Expects a target string buffer of anything up to the length of
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* the original wildcard. You can also pass NULL as the output
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* buffer if you're only interested in the return value.
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*
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* Returns 1 on success, or 0 if a wildcard character was
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* encountered. In the latter case the output string MAY not be
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* zero-terminated and you should not use it for anything!
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*/
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int wc_unescape(char *output, const char *wildcard)
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{
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while (*wildcard) {
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if (*wildcard == '\\') {
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wildcard++;
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/* We are lenient about trailing backslashes in non-wildcards. */
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if (*wildcard) {
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if (output)
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*output++ = *wildcard;
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wildcard++;
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}
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} else if (*wildcard == '*' || *wildcard == '?' ||
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*wildcard == '[' || *wildcard == ']') {
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return 0; /* it's a wildcard! */
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} else {
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if (output)
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*output++ = *wildcard;
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wildcard++;
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}
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}
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*output = '\0';
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return 1; /* it's clean */
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}
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#ifdef TESTMODE
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struct test {
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const char *wildcard;
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const char *target;
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int expected_result;
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};
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const struct test fragment_tests[] = {
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/*
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* We exhaustively unit-test the fragment matching routine
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* itself, which should save us the need to test all its
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* intricacies during the full wildcard tests.
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*/
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{"abc", "abc", 1},
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{"abc", "abd", 0},
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{"abc", "abcd", 1},
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{"abcd", "abc", 0},
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{"ab[cd]", "abc", 1},
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{"ab[cd]", "abd", 1},
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{"ab[cd]", "abe", 0},
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{"ab[^cd]", "abc", 0},
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{"ab[^cd]", "abd", 0},
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{"ab[^cd]", "abe", 1},
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{"ab\\", "abc", -WC_TRAILINGBACKSLASH},
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{"ab\\*", "ab*", 1},
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{"ab\\?", "ab*", 0},
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{"ab?", "abc", 1},
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{"ab?", "ab", 0},
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{"ab[", "abc", -WC_UNCLOSEDCLASS},
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{"ab[c-", "abb", -WC_UNCLOSEDCLASS},
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{"ab[c-]", "abb", -WC_INVALIDRANGE},
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{"ab[c-e]", "abb", 0},
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{"ab[c-e]", "abc", 1},
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{"ab[c-e]", "abd", 1},
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{"ab[c-e]", "abe", 1},
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{"ab[c-e]", "abf", 0},
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{"ab[e-c]", "abb", 0},
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{"ab[e-c]", "abc", 1},
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{"ab[e-c]", "abd", 1},
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{"ab[e-c]", "abe", 1},
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{"ab[e-c]", "abf", 0},
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{"ab[^c-e]", "abb", 1},
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{"ab[^c-e]", "abc", 0},
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{"ab[^c-e]", "abd", 0},
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{"ab[^c-e]", "abe", 0},
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{"ab[^c-e]", "abf", 1},
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{"ab[^e-c]", "abb", 1},
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{"ab[^e-c]", "abc", 0},
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{"ab[^e-c]", "abd", 0},
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{"ab[^e-c]", "abe", 0},
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{"ab[^e-c]", "abf", 1},
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{"ab[a^]", "aba", 1},
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{"ab[a^]", "ab^", 1},
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{"ab[a^]", "abb", 0},
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{"ab[^a^]", "aba", 0},
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{"ab[^a^]", "ab^", 0},
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{"ab[^a^]", "abb", 1},
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{"ab[-c]", "ab-", 1},
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{"ab[-c]", "abc", 1},
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{"ab[-c]", "abd", 0},
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{"ab[^-c]", "ab-", 0},
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{"ab[^-c]", "abc", 0},
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{"ab[^-c]", "abd", 1},
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{"ab[\\[-\\]]", "abZ", 0},
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{"ab[\\[-\\]]", "ab[", 1},
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{"ab[\\[-\\]]", "ab\\", 1},
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{"ab[\\[-\\]]", "ab]", 1},
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{"ab[\\[-\\]]", "ab^", 0},
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{"ab[^\\[-\\]]", "abZ", 1},
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{"ab[^\\[-\\]]", "ab[", 0},
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{"ab[^\\[-\\]]", "ab\\", 0},
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{"ab[^\\[-\\]]", "ab]", 0},
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{"ab[^\\[-\\]]", "ab^", 1},
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{"ab[a-fA-F]", "aba", 1},
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{"ab[a-fA-F]", "abF", 1},
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{"ab[a-fA-F]", "abZ", 0},
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};
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const struct test full_tests[] = {
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{"a", "argh", 0},
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{"a", "ba", 0},
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{"a", "a", 1},
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{"a*", "aardvark", 1},
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{"a*", "badger", 0},
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{"*a", "park", 0},
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{"*a", "pArka", 1},
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{"*a", "parka", 1},
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{"*a*", "park", 1},
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{"*a*", "perk", 0},
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{"?b*r?", "abracadabra", 1},
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{"?b*r?", "abracadabr", 0},
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{"?b*r?", "abracadabzr", 0},
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};
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int main(void)
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{
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int i;
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int fails, passes;
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fails = passes = 0;
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for (i = 0; i < sizeof(fragment_tests)/sizeof(*fragment_tests); i++) {
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const char *f, *t;
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int eret, aret;
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f = fragment_tests[i].wildcard;
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t = fragment_tests[i].target;
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eret = fragment_tests[i].expected_result;
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aret = wc_match_fragment(&f, &t);
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if (aret != eret) {
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printf("failed test: /%s/ against /%s/ returned %d not %d\n",
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fragment_tests[i].wildcard, fragment_tests[i].target,
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aret, eret);
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fails++;
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} else
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passes++;
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}
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for (i = 0; i < sizeof(full_tests)/sizeof(*full_tests); i++) {
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const char *f, *t;
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int eret, aret;
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f = full_tests[i].wildcard;
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t = full_tests[i].target;
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eret = full_tests[i].expected_result;
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aret = wc_match(f, t);
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if (aret != eret) {
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printf("failed test: /%s/ against /%s/ returned %d not %d\n",
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full_tests[i].wildcard, full_tests[i].target,
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aret, eret);
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fails++;
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} else
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passes++;
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}
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printf("passed %d, failed %d\n", passes, fails);
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return 0;
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}
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#endif
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