diff options
Diffstat (limited to 'Src/Zle')
-rw-r--r-- | Src/Zle/comp.h | 41 | ||||
-rw-r--r-- | Src/Zle/complete.c | 188 | ||||
-rw-r--r-- | Src/Zle/compmatch.c | 735 | ||||
-rw-r--r-- | Src/Zle/computil.c | 293 |
4 files changed, 1043 insertions, 214 deletions
diff --git a/Src/Zle/comp.h b/Src/Zle/comp.h index bcad3df05..7ac051c25 100644 --- a/Src/Zle/comp.h +++ b/Src/Zle/comp.h @@ -162,12 +162,49 @@ struct cmatcher { #define CMF_RIGHT 4 #define CMF_INTER 8 +/* + * Types of cpattern structure. + * Note freecpattern() assumes any <= CPAT_EQUIV have string. + */ +enum { + CPAT_CCLASS, /* [...]: ordinary character class */ + CPAT_NCLASS, /* [!...]: ordinary character class, negated */ + CPAT_EQUIV, /* {...}: equivalence class */ + CPAT_ANY, /* ?: any character */ + CPAT_CHAR /* Single character given explicitly */ +}; + +/* + * A pattern element in a matcher specification. + * Unlike normal patterns this only presents one character in + * either the test completion or the word on the command line. + */ struct cpattern { Cpattern next; /* next sub-pattern */ - unsigned char tab[256]; /* table of matched characters */ - int equiv; /* if this is a {...} class */ + int tp; /* type of object as above */ + union { + char *str; /* if a character class, the objects + * in it in a similar form to normal + * pattern matching (a metafied string + * with tokens). + * Note the allocated length may be longer + * than the null-terminated string. + */ + int chr; /* if a single character, it + * TODO: eventually should be a + * convchar_t. + */ + } u; }; +/* + * For now this just handles single-byte characters. + * TODO: this will change. + */ +#define PATMATCHRANGE(r, c, ip, mtp) patmatchrange(r, c, ip, mtp) +#define PATMATCHINDEX(r, i, cp, mtp) patmatchindex(r, i, cp, mtp) +#define CONVCAST(c) (c) + /* This is a special return value for parse_cmatcher(), * * signalling an error. */ diff --git a/Src/Zle/complete.c b/Src/Zle/complete.c index 36c4c8a3d..4b947834b 100644 --- a/Src/Zle/complete.c +++ b/Src/Zle/complete.c @@ -122,13 +122,15 @@ freecpattern(Cpattern p) while (p) { n = p->next; + if (p->tp <= CPAT_EQUIV) + free(p->u.str); zfree(p, sizeof(struct cpattern)); p = n; } } -/* Copy a completion matcher list. */ +/* Copy a completion matcher list into permanent storage. */ /**/ mod_export Cmatcher @@ -157,22 +159,51 @@ cpcmatcher(Cmatcher m) return r; } +/* + * Copy a single entry in a matcher pattern. + * If useheap is 1, it comes from the heap. + */ + +/**/ +mod_export Cpattern +cp_cpattern_element(Cpattern o) +{ + Cpattern n = zalloc(sizeof(struct cpattern)); + + n->next = NULL; + + n->tp = o->tp; + switch (o->tp) + { + case CPAT_CCLASS: + case CPAT_NCLASS: + case CPAT_EQUIV: + n->u.str = ztrdup(o->u.str); + break; + + case CPAT_CHAR: + n->u.chr = o->u.chr; + break; + + default: + /* just to keep compiler quiet */ + break; + } + + return n; +} + /* Copy a completion matcher pattern. */ /**/ static Cpattern cpcpattern(Cpattern o) { - Cpattern r = NULL, *p = &r, n; + Cpattern r = NULL, *p = &r; while (o) { - *p = n = (Cpattern) zalloc(sizeof(struct cpattern)); - - n->next = NULL; - memcpy(n->tab, o->tab, 256); - n->equiv = o->equiv; - - p = &(n->next); + *p = cp_cpattern_element(o); + p = &((*p)->next); o = o->next; } return r; @@ -331,14 +362,26 @@ parse_cmatcher(char *name, char *s) return ret; } -/* Parse a pattern for matcher control. */ +/* + * Parse a pattern for matcher control. + * name is the name of the builtin from which this is called, for errors. + * *sp is the input string and will be updated to the end of the parsed + * pattern. + * *lp will be set to the number of characters (possibly multibyte) + * that the pattern will match. This must be deterministic, given + * the syntax allowed here. + * e, if non-zero, is the ASCII end character to match; if zero, + * stop on a blank. + * *err is set to 1 to indicate an error, else to 0. + */ /**/ static Cpattern parse_pattern(char *name, char **sp, int *lp, char e, int *err) { Cpattern ret = NULL, r = NULL, n; - unsigned char *s = (unsigned char *) *sp; + char *s = *sp; + int inchar; int l = 0; *err = 0; @@ -346,25 +389,18 @@ parse_pattern(char *name, char **sp, int *lp, char e, int *err) while (*s && (e ? (*s != e) : !inblank(*s))) { n = (Cpattern) hcalloc(sizeof(*n)); n->next = NULL; - n->equiv = 0; - if (*s == '[') { - s = parse_class(n, s + 1, ']'); - if (!*s) { - *err = 1; - zwarnnam(name, "unterminated character class"); - return NULL; - } - } else if (*s == '{') { - n->equiv = 1; - s = parse_class(n, s + 1, '}'); + if (*s == '[' || *s == '{') { + s = parse_class(n, s); if (!*s) { *err = 1; zwarnnam(name, "unterminated character class"); return NULL; } + s++; } else if (*s == '?') { - memset(n->tab, 1, 256); + n->tp = CPAT_ANY; + s++; } else if (*s == '*' || *s == '(' || *s == ')' || *s == '=') { *err = 1; zwarnnam(name, "invalid pattern character `%c'", *s); @@ -373,8 +409,13 @@ parse_pattern(char *name, char **sp, int *lp, char e, int *err) if (*s == '\\' && s[1]) s++; - memset(n->tab, 0, 256); - n->tab[*s] = 1; + if (*s == Meta) + inchar = STOUC(*++s) ^ 32; + else + inchar = STOUC(*s); + s++; + n->tp = CPAT_CHAR; + n->u.chr = inchar; } if (ret) r->next = n; @@ -384,7 +425,6 @@ parse_pattern(char *name, char **sp, int *lp, char e, int *err) r = n; l++; - s++; } *sp = (char *) s; *lp = l; @@ -394,28 +434,86 @@ parse_pattern(char *name, char **sp, int *lp, char e, int *err) /* Parse a character class for matcher control. */ /**/ -static unsigned char * -parse_class(Cpattern p, unsigned char *s, unsigned char e) +static char * +parse_class(Cpattern p, char *iptr) { - int n = 0, i = 1, j, eq = (e == '}'), k = 1; - - if (!eq && (*s == '!' || *s == '^') && s[1] != e) { n = 1; s++; } - - memset(p->tab, n, 256); - - n = !n; - while (*s && (k || *s != e)) { - if (s[1] == '-' && s[2] && s[2] != e) { - /* a run of characters */ - for (j = (int) *s; j <= (int) s[2]; j++) - p->tab[j] = (eq ? i++ : n); - - s += 3; + int endchar, firsttime = 1; + char *optr, *nptr; + + if (*iptr++ == '[') { + endchar = ']'; + /* TODO: surely [^]] is valid? */ + if ((*iptr == '!' || *iptr == '^') && iptr[1] != ']') { + p->tp = CPAT_NCLASS; + iptr++; } else - p->tab[*s++] = (eq ? i++ : n); - k = 0; + p->tp = CPAT_CCLASS; + } else { + endchar = '}'; + p->tp = CPAT_EQUIV; } - return s; + + /* find end of class. End character can appear literally first. */ + for (optr = iptr; optr == iptr || *optr != endchar; optr++) + if (!*optr) + return optr; + /* + * We can always fit the parsed class within the same length + * because of the tokenization (including a null byte). + * + * As the input string is metafied, but shouldn't contain shell + * tokens, we can just add our own tokens willy nilly. + */ + optr = p->u.str = zalloc((optr-iptr) + 1); + + while (firsttime || *iptr != endchar) { + int ch; + + if (*iptr == '[' && iptr[1] == ':' && + (nptr = strchr((char *)iptr + 2, ':')) && nptr[1] == ']') { + /* Range type */ + iptr += 2; + ch = range_type((char *)iptr, nptr-iptr); + iptr = nptr + 2; + if (ch != PP_UNKWN) + *optr++ = STOUC(Meta) + ch; + } else { + /* characters stay metafied */ + char *ptr1 = iptr; + if (*iptr == Meta) + iptr++; + iptr++; + if (*iptr == '-' && iptr[1] && iptr[1] != endchar) { + /* a run of characters */ + iptr++; + /* range token */ + *optr++ = Meta + PP_RANGE; + + /* start of range character */ + if (*ptr1 == Meta) { + *optr++ = Meta; + *optr++ = ptr1[1] ^ 32; + } else + *optr++ = *ptr1; + + if (*iptr == Meta) { + *optr++ = *iptr++; + *optr++ = *iptr++; + } else + *optr++ = *iptr++; + } else { + if (*ptr1 == Meta) { + *optr++ = Meta; + *optr++ = ptr1[1] ^ 32; + } else + *optr++ = *ptr1; + } + } + firsttime = 0; + } + + *optr = '\0'; + return iptr; } /**/ diff --git a/Src/Zle/compmatch.c b/Src/Zle/compmatch.c index bf9d2cb0d..e59443c01 100644 --- a/Src/Zle/compmatch.c +++ b/Src/Zle/compmatch.c @@ -30,37 +30,68 @@ #include "complete.mdh" #include "compmatch.pro" -/* This compares two cpattern lists and returns non-zero if they are - * equal. */ +/* + * This compares two cpattern lists and returns non-zero if they are + * equal (N.B. opposite sense to usual *cmp()). + * + * The old version of this didn't worry about whether the lists + * were the same length. This one does. It's hard to see how + * that can be wrong even if it's unnecessary. + */ /**/ static int -cmp_cpatterns(Cpattern a, Cpattern b) +cpatterns_same(Cpattern a, Cpattern b) { while (a) { - if (a->equiv != b->equiv || memcmp(a->tab, b->tab, 256)) + if (!b) + return 0; + if (a->tp != b->tp) return 0; + switch (a->tp) { + case CPAT_CCLASS: + case CPAT_NCLASS: + case CPAT_EQUIV: + /* + * Patterns can actually match the same even if + * the range strings don't compare differently, but + * I don't think we need to handle that subtlety. + */ + if (strcmp(a->u.str, b->u.str) != 0) + return 0; + break; + + case CPAT_CHAR: + if (a->u.chr != b->u.chr) + return 0; + break; + + default: + /* here to silence compiler */ + break; + } + a = a->next; b = b->next; } - return 1; + return !b; } /* This compares two cmatchers and returns non-zero if they are equal. */ /**/ static int -cmp_cmatchers(Cmatcher a, Cmatcher b) +cmatchers_same(Cmatcher a, Cmatcher b) { return (a == b || (a->flags == b->flags && a->llen == b->llen && a->wlen == b->wlen && - (!a->llen || cmp_cpatterns(a->line, b->line)) && - (a->wlen <= 0 || cmp_cpatterns(a->word, b->word)) && + (!a->llen || cpatterns_same(a->line, b->line)) && + (a->wlen <= 0 || cpatterns_same(a->word, b->word)) && (!(a->flags & (CMF_LEFT | CMF_RIGHT)) || (a->lalen == b->lalen && a->ralen == b->ralen && - (!a->lalen || cmp_cpatterns(a->left, b->left)) && - (!a->ralen || cmp_cpatterns(a->right, b->right)))))); + (!a->lalen || cpatterns_same(a->left, b->left)) && + (!a->ralen || cpatterns_same(a->right, b->right)))))); } /* Add the given matchers to the bmatcher list. */ @@ -97,7 +128,7 @@ update_bmatchers(void) t = 0; for (ms = mstack; ms && !t; ms = ms->next) for (mp = ms->matcher; mp && !t; mp = mp->next) - t = cmp_cmatchers(mp, p->matcher); + t = cmatchers_same(mp, p->matcher); p = p->next; if (!t) { @@ -449,7 +480,7 @@ add_match_sub(Cmatcher m, char *l, int ll, char *w, int wl) } } -/* This tests if the string from the line l matches the word w. In bp +/* This tests if the string from the line l matches the word w. In *bpp * the offset for the brace is returned, in rwlp the length of the * matched prefix or suffix, not including the stuff before or after * the last anchor is given. When sfx is non-zero matching is done from @@ -1113,55 +1144,330 @@ comp_match(char *pfx, char *sfx, char *w, Patprog cp, Cline *clp, int qu, return r; } -/* Check if the given pattern matches the given string. * + +/* + * Guts of a single pattern for pattern_match(). + * Return non-zero if match successful. + * If the class was an equivalence, return 1 + the index into + * the equivalence class (see pattern.c for how this is calculated). + */ + +/**/ +mod_export int +pattern_match1(Cpattern p, int c, int *mtp) +{ + /* TODO: should become convchar_t */ + int ind; + + *mtp = 0; + switch (p->tp) { + case CPAT_CCLASS: + return PATMATCHRANGE(p->u.str, CONVCAST(c), NULL, NULL); + + case CPAT_NCLASS: + return !PATMATCHRANGE(p->u.str, CONVCAST(c), NULL, NULL); + + case CPAT_EQUIV: + if (PATMATCHRANGE(p->u.str, CONVCAST(c), &ind, mtp)) + return ind + 1; + else + return 0; + + case CPAT_ANY: + return 1; + + case CPAT_CHAR: + return (p->u.chr == c); + + default: + DPUTS(1, "bad matcher pattern type"); + return 0; + } +} + + +/* + * Use an equivalence to deduce the line character from the word, or + * vice versa. (If vice versa, then "line" and "word" are reversed + * in what follows. The logic is symmetric.) + * lp is the line pattern. + * wind is the index returned by a pattern match on the word pattern, + * with type wmtp. + * wchr is the word character. + * Return -1 if no matching character, else the character. + * + * Only makes sense if lp->tp == CPAT_EQUIV and the (unseen) word + * pattern also has that type. + */ +static int +pattern_match_equivalence(Cpattern lp, int wind, int wmtp, int wchr) +{ + int lchr, lmtp; + + if (!PATMATCHINDEX(lp->u.str, wind-1, &lchr, &lmtp)) { + /* + * No equivalent. No possible match; give up. + */ + return -1; + } + /* + * If we matched an exact character rather than a range + * type, return it. + */ + if (lchr != -1) + return lchr; + + /* + * Check the match types. We may want a case-changed + * version of the word character. + */ + if (wmtp == PP_UPPER && lmtp == PP_LOWER) + return tulower(wchr); + else if (wmtp == PP_LOWER && lmtp == PP_UPPER) + return tuupper(wchr); + else if (wmtp == lmtp) { + /* + * Be lenient and allow identical replacements + * for character classes, although in fact this + * doesn't give special functionality for equivalence + * classes. + */ + return wchr; + } else { + /* + * Non-matching generic types; this can't work. + */ + return -1; + } +} + +/* + * Check if the given pattern matches the given string. * p and s are either anchor or line pattern and string; * wp and ws are word (candidate) pattern and string * - * If only one pattern is given, we just check if characters match + * If only one pattern is given, we just check if characters match. * If both line and word are given, we check that characters match - * for {...} classes by comparing relative numbers in sequence. + * for {...} classes by comparing positions in the strings. * * Patterns and strings are always passed in pairs, so it is enough * to check for non-NULL wp. p should always be present. + * + * If prestrict is not NULL, it is a chain of patterns at least as long + * as the line string. In this case we are still assembling the line at + * s (which has been allocated but doesn't yet contain anything useful) + * and must continue to do so as we go along; prestrict gives + * restrictions on the line character to be applied along side the other + * patterns. In the simple case a restriction is a character to be put + * in place; otherwise it is a set of possible characters and we have to + * deduce an actual matching character. Note prestrict is never an + * equivalence class. In extreme cases we can't deduce a unique + * character; then the match fails. */ /**/ mod_export int -pattern_match(Cpattern p, char *s, Cpattern wp, char *ws) +pattern_match_restrict(Cpattern p, char *s, Cpattern wp, char *ws, + Cpattern prestrict) { - unsigned char c; - unsigned char wc; + int c, ind; + int wc, wind; + int len, wlen, mt, wmt; while (p && wp && *s && *ws) { - c = p->tab[*((unsigned char *) s)]; - wc = wp->tab[*((unsigned char *) ws)]; - - if (!c || !wc || c != wc) + /* First test the word character */ + if (*ws == Meta) { + wc = STOUC(ws[1]) ^ 32; + wlen = 2; + } else { + wc = STOUC(*ws); + wlen = 1; + } + wind = pattern_match1(wp, wc, &wmt); + if (!wind) return 0; - s++; - ws++; + /* + * Now the line character; deal with the case where + * we don't yet have it, only a restriction on it. + */ + if (prestrict) { + if (prestrict->tp == CPAT_CHAR) { + /* + * Easy case: restricted to an exact character on + * the line. Procede as normal. + */ + c = prestrict->u.chr; + } else { + if (p->tp == CPAT_CHAR) { + /* + * Normal line pattern is an exact character: as + * long as this matches prestrict, we can proceed + * as usual. + */ + c = p->u.chr; + } else if (p->tp == CPAT_EQUIV) { + /* + * An equivalence, so we can deduce the character + * backwards from the word pattern and see if it + * matches prestrict. + */ + if ((c = pattern_match_equivalence(p, wind, wmt, wc)) == -1) + return 0; + } else { + /* + * Not an equivalence, so that means we must match + * the word (not just the word pattern), so grab it + * and make sure it fulfills our needs. I think. + * Not 100% sure about that, but what else can + * we do? We haven't actually been passed a string + * from the command line. + */ + c = wc; + } + /* Character so deduced must match the restriction. */ + if (!pattern_match1(prestrict, c, &mt)) + return 0; + } + len = imeta(c) ? 2 : 1; + } else { + /* We have the character itself. */ + if (*s == Meta) { + c = STOUC(s[1]) ^ 32; + len = 2; + } else { + c = STOUC(*s); + len = 1; + } + } + /* + * If either is "?", they match each other; no further tests. + * Apply this even if the character wasn't convertable; + * there's no point trying to be clever in that case. + */ + if (p->tp != CPAT_ANY || wp->tp != CPAT_ANY) + { + ind = pattern_match1(p, c, &mt); + if (!ind) + return 0; + if (ind != wind) + return 0; + if (mt != wmt) { + /* + * Special case if matching lower vs. upper or + * vice versa. The transformed characters must match. + * We don't need to check the transformation is + * the appropriate one for each character separately, + * since that was done in pattern_match1(), so just + * compare lower-cased versions of both. + */ + if ((mt == PP_LOWER || mt == PP_UPPER) && + (wmt == PP_LOWER || wmt == PP_UPPER)) { + if (tulower(c) != tulower(wc)) + return 0; + } else { + /* Other different classes can't match. */ + return 0; + } + } + } + + if (prestrict) { + /* We need to assemble the line */ + if (imeta(c)) { + *s++ = Meta; + *s++ = c ^ 32; + } else { + *s++ = c; + } + prestrict = prestrict->next; + } else + s += len; + ws += wlen; p = p->next; wp = wp->next; } while (p && *s) { - if (!p->tab[*((unsigned char *) s)]) + if (prestrict) { + /* + * As above, but with even less info to go on. + * (Can this happen?) At least handle the cases where + * one of our patterns has given us a specific character. + */ + if (prestrict->tp == CPAT_CHAR) { + c = prestrict->u.chr; + } else { + if (p->tp == CPAT_CHAR) { + c = p->u.chr; + } else { + /* + * OK. Here we are in a function with just a line + * pattern and another pattern to restrict the + * characters that can go on the line, and no actual + * characters. We're matching two patterns against + * one another to generate a character to insert. + * This is a bit too psychedelic, so I'm going to + * bale out now. See you on the ground. + */ + return 0; + } + if (!pattern_match1(prestrict, c, &mt)) + return 0; + } + } else { + if (*s == Meta) { + c = STOUC(s[1]) ^ 32; + len = 2; + } else { + c = STOUC(*s); + len = 1; + } + } + if (!pattern_match1(p, c, &mt)) return 0; p = p->next; - s++; + if (prestrict) { + if (imeta(c)) { + *s++ = Meta; + *s++ = c ^ 32; + } else { + *s++ = c; + } + prestrict = prestrict->next; + } else + s += len; } while (wp && *ws) { - if (!wp->tab[*((unsigned char *) ws)]) + /* No funny business when we only have the word pattern. */ + if (*ws == Meta) { + wc = STOUC(ws[1]) ^ 32; + wlen = 2; + } else { + wc = STOUC(*ws); + wlen = 1; + } + if (!pattern_match1(wp, wc, &wmt)) return 0; wp = wp->next; - ws++; + ws += wlen; } return 1; } +/* + * The usual version of pattern matching, without the line string + * being handled by restriction. + */ +/**/ +mod_export int +pattern_match(Cpattern p, char *s, Cpattern wp, char *ws) +{ + return pattern_match_restrict(p, s, wp, ws, NULL); +} + /* This splits the given string into a list of cline structs, separated * at those places where one of the anchors of an `*' pattern was found. * plen gives the number of characters on the line that matched this @@ -1256,11 +1562,11 @@ bld_parts(char *str, int len, int plen, Cline *lp, Cline *lprem) return ret; } -/* This builds all the possible line patterns for the pattern pat in the - * buffer line. Initially line is the same as lp, but during recursive - * calls lp is incremented for storing successive characters. Whenever - * a full possible string is build, we test if this line matches the - * string given by wlen and word. + +/* + * This builds all the possible line patterns for the pattern pat in the + * buffer line. Then we test if this line matches the string given by + * wlen and word. * * wpat contains pattern that matched previously * lpat contains the pattern for line we build @@ -1269,91 +1575,297 @@ bld_parts(char *str, int len, int plen, Cline *lp, Cline *lprem) * * The return value is the length of the string matched in the word, it * is zero if we couldn't build a line that matches the word. + * + * TODO: a lot of the nastiness associated with variable string + * lengths can go when we switch to wide characters. (Why didn't + * I just keep line unmetafied and metafy into place at the end? Er...) */ - /**/ static int -bld_line(Cpattern wpat, Cpattern lpat, char *line, char *lp, - char *mword, char *word, int wlen, int sfx) +bld_line(Cmatcher mp, char **linep, char *mword, char *word, int wlen, int sfx) { - if (lpat) { - /* Still working on the pattern. */ - - int i, l; - unsigned char c = 0; - - /* Get the number of the character for a correspondence class - * if it has a corresponding class. */ - if (lpat->equiv) - if (wpat && *mword) { - c = wpat->tab[STOUC(*mword)]; - wpat = wpat->next; - mword++; + Cpattern lpat = mp->line; + Cpattern wpat = mp->word; + Cpattern curgenpat; + VARARR(struct cpattern, genpatarr, mp->llen); + Cmlist ms; + int llen, rl; + char *oword = word, *line = *linep; + + /* + * Loop over all characters. At this stage, line is an empty + * space of length llen (not counting the null byte) which we assemble as + * we go along. + * + * However, first we need to know what characters can appear at each + * point in the line. For this we assemble an list genpatarr of the + * same length as the line. (It's convenient to store this as an + * array but it's linked as a list, too.) If there are equivalences + * we use mword to derive the equivalent character; when we've + * reached the end of mword, equivalences are treated just like + * ordinary character classes. For character classes we just attach + * the class to the genpatarr list and apply it as a restriction + * when we finally match the line against the set of matchers. + */ + curgenpat = genpatarr; + while (lpat) { + int wchr = (*mword == Meta) ? STOUC(mword[1]) ^ 32 : STOUC(*mword); + int wmtp, wind; + /* + * If the line pattern is an equivalence, query wpat to find the + * word part of the equivalence. If we don't find one we don't try + * equivalencing but use lpat as an ordinary match. (It's not + * entirely clear to me this is the correct behaviour on a + * failed character match within the equivalence, but that was + * the behaviour of the old logic that this replaces.) + */ + if (lpat->tp == CPAT_EQUIV && wpat && *mword) { + wind = pattern_match1(wpat, wchr, &wmtp); + wpat = wpat->next; + mword += (*mword == Meta) ? 2 : 1; + } else + wind = 0; + if (wind) { + /* + * Successful match for word side of equivalence. + * Find the line equivalent. + */ + int lchr; + if ((lchr = pattern_match_equivalence(lpat, wind, wmtp, wchr)) + == -1) { + /* + * No equivalent. No possible match; give up. + */ + return 0; + } + /* + * We now have an exact character to match, + * so make up a pattern element for it. + */ + curgenpat->tp = CPAT_CHAR; + curgenpat->u.chr = lchr; + } else { + /* + * Not an equivalence class, so we just keep the + * test in the lpat as it is. + */ + curgenpat->tp = lpat->tp; + if (lpat->tp == CPAT_CHAR) + curgenpat->u.chr = lpat->u.chr; + else if (lpat->tp != CPAT_ANY) { + /* + * The string isn't modified and is only needed in calls from + * this function, so we don't even need to copy it. + */ + curgenpat->u.str = lpat->u.str; } + } + lpat = lpat->next; + /* + * This linked list is defined above as an array. + * We could get away with just keeping it as an array + * and passing it down as such, but that's a bit icky + * since the generic linkage of Cpatterns is as a linked + * list and we should keep our local memory management + * problems to ourselvess. + */ + if (lpat) + curgenpat->next = curgenpat+1; + else + curgenpat->next = NULL; + curgenpat++; + } + /* + * We now know how to match the word with the line patterns; let's + * see if it does. We will use the information in curgenpat if we + * are successful to work out what character goes on the line. This + * is a bit hairy, as in "the Yeti is a creature that is a bit + * hairy". + */ + llen = mp->llen; + rl = 0; - /* Walk through the table in the pattern and try the characters - * that may appear in the current position. */ - for (i = 0; i < 256; i++) - if ((lpat->equiv && c) ? (c == lpat->tab[i]) : lpat->tab[i]) { - *lp = i; - /* We stored the character, now call ourselves to build - * the rest. */ - if ((l = bld_line(wpat, lpat->next, line, lp + 1, - mword, word, wlen, sfx))) - return l; - } - } else { - /* We reached the end, i.e. the line string is fully build, now - * see if it matches the given word. */ + if (sfx) + { + /* + * We need to work backwards from the end of both the + * word and the line strings. + * + * Position at the end of the word by counting characters. + */ + int l = wlen; + while (l--) + word += (*word == Meta) ? 2 : 1; - Cmlist ms; - Cmatcher mp; - int l = lp - line, t, rl = 0, ind, add; + /* + * We construct the line from the end. We've left + * enough space for possible Meta's. + */ + line += 2 * llen; + *line = '\0'; + curgenpat = genpatarr + llen; + } else + curgenpat = genpatarr; - /* Quick test if the strings are exactly the same. */ - if (l == wlen && !strncmp(line, word, l)) - return l; + /* we now reuse mp, lpat, wpat for the global matchers */ + while (llen && wlen) { + int wchr, wmtp; + char *wp; + Cpattern tmpgenpat; if (sfx) { - line = lp; word += wlen; - ind = -1; add = -1; - } else { - ind = 0; add = 1; - } - /* We loop through the whole line string built. */ - while (l && wlen) { - if (word[ind] == line[ind]) { - /* The same character in both strings, skip over. */ - line += add; word += add; - l--; wlen--; rl++; + if (word > oword + 1 && word[-2] == Meta) + wp = word - 2; + else + wp = word - 1; + curgenpat--; + } else + wp = word; + if (*wp == Meta) + wchr = STOUC(wp[1]) ^ 32; + else + wchr = STOUC(*wp); + if (pattern_match1(curgenpat, wchr, &wmtp)) + { + int lchr; + /* + * We can match the line character directly with the word + * character. If the line character is a fixed one, + * keep it, since we went to all that trouble above, + * else if it's generic, keep the word character, + * since we have no choice. + */ + if (curgenpat->tp == CPAT_CHAR) + lchr = curgenpat->u.chr; + else + lchr = wchr; + if (imeta(lchr)) { + if (sfx) + line -= 2; + line[0] = Meta; + line[1] = lchr ^ 32; + if (!sfx) + line += 2; } else { - t = 0; - for (ms = bmatchers; ms && !t; ms = ms->next) { - mp = ms->matcher; - if (mp && !mp->flags && mp->wlen <= wlen && mp->llen <= l && - pattern_match(mp->line, (sfx ? line - mp->llen : line), - mp->word, (sfx ? word - mp->wlen : word))) { - /* Both the line and the word pattern matched, - * now skip over the matched portions. */ + if (sfx) + line--; + line[0] = lchr; + if (!sfx) + line++; + } + + llen--; + wlen--; + rl++; + + if (sfx) + word = wp; + else { + if (llen) + curgenpat++; + word += (*word == Meta) ? 2 : 1; + } + } + else + { + char *lp; + /* + * Need to loop over pattern matchers. + */ + for (ms = bmatchers; ms; ms = ms->next) { + mp = ms->matcher; + /* + * This is the nightmare case: we have line and + * and word matchers and some pattern which restricts + * the value on the line without us knowing exactly + * what it is. Despatch to the special function + * for that. + */ + if (mp && !mp->flags && mp->wlen <= wlen && + mp->llen <= llen) + { + if (sfx) { + /* + * We haven't assembled the line yet, and with + * Meta characters we don't yet know the length. + * We'll fix this up later. + */ + lp = line - 2 * mp->llen; + } else + lp = line; + wp = word; + if (sfx) { + int l = mp->wlen; + while (l--) { + if (wp > oword + 1 && wp[-2] == Meta) + wp -= 2; + else + wp--; + } + + tmpgenpat = curgenpat - mp->llen; + } else + tmpgenpat = curgenpat; + if (pattern_match_restrict(mp->line, lp, + mp->word, wp, tmpgenpat)) { + /* + * Matched: advance over as many characters + * of the patterns and strings as + * we've done matches. + */ if (sfx) { - line -= mp->llen; word -= mp->wlen; + int imove = mp->llen, nchar; + char *pmove = lp; + word = wp; + + /* Close the gap we left in the line string */ + while (imove--) + pmove += (*pmove == Meta) ? 2 : 1; + /* Number of bytes to move */ + nchar = (int)(pmove - lp); + /* The size of the gap */ + imove = 2 * mp->llen - nchar; + if (imove) { + lp = line - imove; + /* Moving up, so start at the top */ + while (nchar--) + *--line = *--lp; + /* line is at the start of the moved text */ + } + + curgenpat = tmpgenpat; } else { - line += mp->llen; word += mp->wlen; + int cnt = mp->llen; + while (cnt--) { + line += (*line == Meta) ? 2 : 1; + } + + cnt = mp->wlen; + while (cnt--) + word += (*word == Meta) ? 2 : 1; + + curgenpat += mp->llen; } - l -= mp->llen; wlen -= mp->wlen; rl += mp->wlen; - t = 1; + llen -= mp->llen; + wlen -= mp->wlen; + rl += mp->wlen; + break; } } - if (!t) - /* Didn't match, give up. */ - return 0; } + if (!ms) + return 0; /* Didn't match, give up */ } - if (!l) - /* Unmatched portion in the line built, return matched length. */ - return rl; + } + if (!llen) { + /* Unmatched portion in the line built, return matched length. */ + if (sfx) + *linep = line; + else + *line = '\0'; + return rl; } return 0; } @@ -1386,8 +1898,10 @@ join_strs(int la, char *sa, int lb, char *sb) if ((t = pattern_match(mp->word, sa, NULL, NULL)) || pattern_match(mp->word, sb, NULL, NULL)) { /* It matched one of the strings, t says which one. */ - VARARR(char, line, mp->llen + 1); - char **ap, **bp; + /* TODO: double to allow Meta, not necessary + when properly unmetafied */ + VARARR(char, linearr, 2*mp->llen + 1); + char **ap, **bp, *line = linearr; int *alp, *blp; if (t) { @@ -1399,10 +1913,8 @@ join_strs(int la, char *sa, int lb, char *sb) } /* Now try to build a string that matches the other * string. */ - if ((bl = bld_line(mp->word, mp->line, line, line, - *ap, *bp, *blp, 0))) { + if ((bl = bld_line(mp, &line, *ap, *bp, *blp, 0))) { /* Found one, put it into the return string. */ - line[mp->llen] = '\0'; if (rr <= mp->llen) { char *or = rs; @@ -1444,7 +1956,11 @@ join_strs(int la, char *sa, int lb, char *sb) return rs; } -/* This compares the anchors stored in two top-level clines. */ +/* + * This compares the anchors stored in two top-level clines. + * It returns 1 if the anchors are the same, 2 if they are + * compatible (and have been combined in "o"), 0 otherwise. + */ /**/ static int @@ -1591,9 +2107,11 @@ join_sub(Cmdata md, char *str, int len, int *mlen, int sfx, int join) NULL, NULL)) || pattern_match(mp->word, nw - (sfx ? mp->wlen : 0), NULL, NULL))) { - VARARR(char, line, mp->llen + 1); + /* TODO: doubled to allow Meta, not necessary + * when properly unmetafied */ + VARARR(char, linearr, 2*mp->llen + 1); int bl; - char *mw; + char *mw, *line = linearr; /* Then build all the possible lines and see * if one of them matches the other string. */ @@ -1602,11 +2120,10 @@ join_sub(Cmdata md, char *str, int len, int *mlen, int sfx, int join) else mw = nw - (sfx ? mp->wlen : 0); - if ((bl = bld_line(mp->word, mp->line, line, line, - mw, (t ? nw : ow), (t ? nl : ol), sfx))) { + if ((bl = bld_line(mp, &line, mw, (t ? nw : ow), + (t ? nl : ol), sfx))) { /* Yep, one of the lines matched the other * string. */ - line[mp->llen] = '\0'; if (t) { ol = mp->wlen; nl = bl; diff --git a/Src/Zle/computil.c b/Src/Zle/computil.c index 9d116b93a..2b3efa776 100644 --- a/Src/Zle/computil.c +++ b/Src/Zle/computil.c @@ -3997,6 +3997,239 @@ cfp_test_exact(LinkList names, char **accept, char *skipped) return (found ? ret : NULL); } + +/* + * This code constructs (from heap) and returns a string that + * corresponds to a series of matches; when compiled as a pattern, at + * each position it matches either the character from the string "add" + * or the corresponding single-character match from the set of matchers. + * To take a simple case, if add is "a" and the single matcher for the + * character position matches "[0-9]", the pattern returned is "[0-9a]". + * We take account of equivalences between the word and line, too. + * + * As there are virtually no comments in this file, I don't really + * know why we're doing this, but it's to do with a matcher which + * is passed as an argument to the utility compfiles -p/-P. + */ +static char * +cfp_matcher_range(Cmatcher *ms, char *add) +{ + Cmatcher *mp, m; + int len = 0, mt; + char *ret = NULL, *p = NULL, *adds = add; + + /* + * Do this twice: once to work out the length of the + * string in len, the second time to build it in ret. + * This is probably worthwhile because otherwise memory + * management is difficult. + */ + for (;;) { + for (mp = ms; *add; add++, mp++) { + if (!(m = *mp)) { + /* + * No matcher, so just match the character + * itself. + * + * TODO: surely this needs quoting if it's a + * metacharacter? + */ + if (ret) { + if (imeta(*add)) { + *p++ = Meta; + *p++ = *add ^ 32; + } else + *p++ = *add; + } else + len += imeta(*add) ? 2 : 1; + } else if (m->flags & CMF_RIGHT) { + /* + * Right-anchored: match anything followed + * by the character itself. + */ + if (ret) { + *p++ = '*'; + /* TODO: quote again? */ + if (imeta(*add)) { + *p++ = Meta; + *p++ = *add ^ 32; + } else + *p++ = *add; + } else + len += imeta(*add) ? 3 : 2; + } else { + /* The usual set of matcher possibilities. */ + int ind; + if (m->line->tp == CPAT_EQUIV && + m->word->tp == CPAT_EQUIV) { + /* + * Genuine equivalence. Add the character to match + * and the equivalent character from the word + * pattern. + * + * TODO: we could be more careful here with special + * cases as we are in the basic character class + * code below. + */ + if (ret) { + *p++ = '['; + if (imeta(*add)) { + *p++ = Meta; + *p++ = *add ^ 32; + } else + *p++ = *add; + } else + len += imeta(*add) ? 3 : 2; + if (PATMATCHRANGE(m->line->u.str, CONVCAST(*add), + &ind, &mt)) { + /* + * Find the equivalent match for ind in the + * word pattern. + */ + if ((ind = pattern_match_equivalence + (m->word, ind, mt, CONVCAST(*add))) != -1) { + if (ret) { + if (imeta(ind)) { + *p++ = Meta; + *p++ = ind ^ 32; + } else + *p++ = ind; + } else + len += imeta(ind) ? 2 : 1; + } + } + if (ret) + *p++ = ']'; + else + len++; + } else { + int newlen, addadd; + + switch (m->word->tp) { + case CPAT_NCLASS: + /* + * TODO: the old logic implies that we need to + * match *add, i.e. it should be deleted from + * the set of character's we're not allowed to + * match. That's too much like hard work for + * now. Indeed, in general it's impossible + * without trickery. Consider *add == 'A', + * range == "[^[:upper:]]": we would have to + * resort to something like "(A|[^[:upper:]])"; + * and in an expression like that *add may or + * may not need backslashing. So we're deep + * into see-if-we-can-get-away-without + * territory. + */ + if (ret) { + *p++ = '['; + *p++ = '^'; + } else + len += 2; + /* + * Convert the compiled range string back + * to an ordinary string. + */ + newlen = + pattern_range_to_string(m->word->u.str, p); + DPUTS(!newlen, "empty character range"); + if (ret) { + p += newlen; + *p++ = ']'; + } else + len += newlen + 1; + break; + + case CPAT_CCLASS: + /* + * If there is an equivalence only on one + * side it's not equivalent to anything. + * Treat it as an ordinary character class. + */ + case CPAT_EQUIV: + case CPAT_CHAR: + if (ret) + *p++ = '['; + else + len++; + /* + * We needed to add *add specially only if + * it is not covered by the range. This + * is necessary for correct syntax---consider + * if *add is ] and ] is also the first + * character in the range. + */ + addadd = !pattern_match1(m->word, CONVCAST(*add), &mt); + if (addadd && *add == ']') { + if (ret) + *p++ = *add; + else + len++; + } + if (m->word->tp == CPAT_CHAR) { + /* + * The matcher just matches a single + * character, but we need to be able + * to match *add, too, hence we do + * this as a [...]. + */ + if (ret) { + if (imeta(m->word->u.chr)) { + *p++ = Meta; + *p++ = m->word->u.chr ^ 32; + } else + *p++ = m->word->u.chr; + } else + len += imeta(m->word->u.chr) ? 2 : 1; + } else { + /* + * Convert the compiled range string back + * to an ordinary string. + */ + newlen = + pattern_range_to_string(m->word->u.str, p); + DPUTS(!newlen, "empty character range"); + if (ret) + p += newlen; + else + len += newlen; + } + if (addadd && *add != ']') { + if (ret) { + if (imeta(*add)) { + *p++ = Meta; + *p++ = *add ^ 32; + } else + *p++ = *add; + } else + len += imeta(*add) ? 2 : 1; + } + if (ret) + *p++ = ']'; + else + len++; + break; + + case CPAT_ANY: + if (ret) + *p++ = '?'; + else + len++; + break; + } + } + } + } + if (ret) { + *p = '\0'; + return ret; + } + p = ret = zhalloc(len + 1); + add = adds; + } +} + + static char * cfp_matcher_pats(char *matcher, char *add) { @@ -4064,64 +4297,8 @@ cfp_matcher_pats(char *matcher, char *add) break; } } - if (*add) { - char *ret = "", buf[259]; - - for (mp = ms; *add; add++, mp++) { - if (!(m = *mp)) { - buf[0] = *add; - buf[1] = '\0'; - } else if (m->flags & CMF_RIGHT) { - buf[0] = '*'; - buf[1] = *add; - buf[2] = '\0'; - } else { - unsigned char *t, c; - char *p = buf; - int i; - - for (i = 256, t = m->word->tab; i--; t++) - if (*t) - break; - if (i) { - t = m->word->tab; - *p++ = '['; - if (m->line->equiv && m->word->equiv) { - *p++ = *add; - c = m->line->tab[STOUC(*add)]; - for (i = 0; i < 256; i++) - if (m->word->tab[i] == c) { - *p++ = (char) i; - break; - } - } else { - if (*add == ']' || t[STOUC(']')]) - *p++ = ']'; - for (i = 0; i < 256; i++, t++) - if (*t && ((char) i) != *add && - i != ']' && i != '-' && - i != '^' && i != '!') - *p++ = (char) i; - *p++ = *add; - t = m->word->tab; - if (*add != '^' && t[STOUC('^')]) - *p++ = '^'; - if (*add != '!' && t[STOUC('!')]) - *p++ = '!'; - if (*add != '-' && t[STOUC('-')]) - *p++ = '-'; - } - *p++ = ']'; - *p = '\0'; - } else { - *p = '?'; - p[1] = '\0'; - } - } - ret = dyncat(ret, buf); - } - return ret; - } + if (*add) + return cfp_matcher_range(ms, add); } return add; } |