/* $OpenBSD: re_search.c,v 1.27 2013/05/31 18:03:45 lum Exp $ */ /* This file is in the public domain. */ /* * regular expression search commands for Mg * * This file contains functions to implement several of gnuemacs's regular * expression functions for Mg. Several of the routines below are just minor * re-arrangements of Mg's non-regular expression search functions. Some of * them are similar in structure to the original MicroEMACS, others are * modifications of Rich Ellison's code. Peter Newton re-wrote about half of * them from scratch. */ #ifdef REGEX #include "def.h" #include #include #include "macro.h" #define SRCH_BEGIN (0) /* search sub-codes */ #define SRCH_FORW (-1) #define SRCH_BACK (-2) #define SRCH_NOPR (-3) #define SRCH_ACCM (-4) #define SRCH_MARK (-5) #define RE_NMATCH 10 /* max number of matches */ #define REPLEN 256 /* max length of replacement string */ char re_pat[NPAT]; /* regex pattern */ int re_srch_lastdir = SRCH_NOPR; /* last search flags */ int casefoldsearch = TRUE; /* does search ignore case? */ static int re_doreplace(RSIZE, char *); static int re_forwsrch(void); static int re_backsrch(void); static int re_readpattern(char *); static int killmatches(int); static int countmatches(int); /* * Search forward. * Get a search string from the user and search for it starting at ".". If * found, move "." to just after the matched characters. display does all * the hard stuff. If not found, it just prints a message. */ /* ARGSUSED */ int re_forwsearch(int f, int n) { int s; if ((s = re_readpattern("RE Search")) != TRUE) return (s); if (re_forwsrch() == FALSE) { ewprintf("Search failed: \"%s\"", re_pat); return (FALSE); } re_srch_lastdir = SRCH_FORW; return (TRUE); } /* * Reverse search. * Get a search string from the user, and search, starting at "." * and proceeding toward the front of the buffer. If found "." is left * pointing at the first character of the pattern [the last character that * was matched]. */ /* ARGSUSED */ int re_backsearch(int f, int n) { int s; if ((s = re_readpattern("RE Search backward")) != TRUE) return (s); if (re_backsrch() == FALSE) { ewprintf("Search failed: \"%s\"", re_pat); return (FALSE); } re_srch_lastdir = SRCH_BACK; return (TRUE); } /* * Search again, using the same search string and direction as the last search * command. The direction has been saved in "srch_lastdir", so you know which * way to go. * * XXX: This code has problems -- some incompatibility(?) with extend.c causes * match to fail when it should not. */ /* ARGSUSED */ int re_searchagain(int f, int n) { if (re_srch_lastdir == SRCH_NOPR) { ewprintf("No last search"); return (FALSE); } if (re_srch_lastdir == SRCH_FORW) { if (re_forwsrch() == FALSE) { ewprintf("Search failed: \"%s\"", re_pat); return (FALSE); } return (TRUE); } if (re_srch_lastdir == SRCH_BACK) if (re_backsrch() == FALSE) { ewprintf("Search failed: \"%s\"", re_pat); return (FALSE); } return (TRUE); } /* Compiled regex goes here-- changed only when new pattern read */ static regex_t re_buff; static regmatch_t re_match[RE_NMATCH]; /* * Re-Query Replace. * Replace strings selectively. Does a search and replace operation. */ /* ARGSUSED */ int re_queryrepl(int f, int n) { int rcnt = 0; /* replacements made so far */ int plen, s; /* length of found string */ char news[NPAT]; /* replacement string */ if ((s = re_readpattern("RE Query replace")) != TRUE) return (s); if (eread("Query replace %s with: ", news, NPAT, EFNUL | EFNEW | EFCR, re_pat) == NULL) return (ABORT); ewprintf("Query replacing %s with %s:", re_pat, news); /* * Search forward repeatedly, checking each time whether to insert * or not. The "!" case makes the check always true, so it gets put * into a tighter loop for efficiency. */ while (re_forwsrch() == TRUE) { retry: update(CMODE); switch (getkey(FALSE)) { case ' ': plen = re_match[0].rm_eo - re_match[0].rm_so; if (re_doreplace((RSIZE)plen, news) == FALSE) return (FALSE); rcnt++; break; case '.': plen = re_match[0].rm_eo - re_match[0].rm_so; if (re_doreplace((RSIZE)plen, news) == FALSE) return (FALSE); rcnt++; goto stopsearch; case CCHR('G'): /* ^G */ (void)ctrlg(FFRAND, 0); goto stopsearch; case CCHR('['): /* ESC */ case '`': goto stopsearch; case '!': do { plen = re_match[0].rm_eo - re_match[0].rm_so; if (re_doreplace((RSIZE)plen, news) == FALSE) return (FALSE); rcnt++; } while (re_forwsrch() == TRUE); goto stopsearch; case CCHR('?'): /* To not replace */ break; default: ewprintf(" replace, [.] rep-end, don't, [!] repl rest quit"); goto retry; } } stopsearch: curwp->w_rflag |= WFFULL; update(CMODE); if (!inmacro) { if (rcnt == 0) ewprintf("(No replacements done)"); else if (rcnt == 1) ewprintf("(1 replacement done)"); else ewprintf("(%d replacements done)", rcnt); } return (TRUE); } /* * Routine re_doreplace calls lreplace to make replacements needed by * re_query replace. Its reason for existence is to deal with \1, \2. etc. * plen: length to remove * st: replacement string */ static int re_doreplace(RSIZE plen, char *st) { int j, k, s, more, num, state; struct line *clp; char repstr[REPLEN]; clp = curwp->w_dotp; more = TRUE; j = 0; state = 0; num = 0; /* The following FSA parses the replacement string */ while (more) { switch (state) { case 0: if (*st == '\\') { st++; state = 1; } else if (*st == '\0') more = FALSE; else { repstr[j] = *st; j++; if (j >= REPLEN) return (FALSE); st++; } break; case 1: if (*st >= '0' && *st <= '9') { num = *st - '0'; st++; state = 2; } else if (*st == '\0') more = FALSE; else { repstr[j] = *st; j++; if (j >= REPLEN) return (FALSE); st++; state = 0; } break; case 2: if (*st >= '0' && *st <= '9') { num = 10 * num + *st - '0'; st++; } else { if (num >= RE_NMATCH) return (FALSE); k = re_match[num].rm_eo - re_match[num].rm_so; if (j + k >= REPLEN) return (FALSE); bcopy(&(clp->l_text[re_match[num].rm_so]), &repstr[j], k); j += k; if (*st == '\0') more = FALSE; if (*st == '\\') { st++; state = 1; } else { repstr[j] = *st; j++; if (j >= REPLEN) return (FALSE); st++; state = 0; } } break; } /* switch (state) */ } /* while (more) */ repstr[j] = '\0'; s = lreplace(plen, repstr); return (s); } /* * This routine does the real work of a forward search. The pattern is * sitting in the external variable "pat". If found, dot is updated, the * window system is notified of the change, and TRUE is returned. If the * string isn't found, FALSE is returned. */ static int re_forwsrch(void) { int tbo, error; struct line *clp; clp = curwp->w_dotp; tbo = curwp->w_doto; if (tbo == clp->l_used) /* * Don't start matching past end of line -- must move to * beginning of next line, unless at end of file. */ if (clp != curbp->b_headp) { clp = lforw(clp); tbo = 0; } /* * Note this loop does not process the last line, but this editor * always makes the last line empty so this is good. */ while (clp != (curbp->b_headp)) { re_match[0].rm_so = tbo; re_match[0].rm_eo = llength(clp); error = regexec(&re_buff, ltext(clp), RE_NMATCH, re_match, REG_STARTEND); if (error != 0) { clp = lforw(clp); tbo = 0; } else { curwp->w_doto = re_match[0].rm_eo; curwp->w_dotp = clp; curwp->w_rflag |= WFMOVE; return (TRUE); } } return (FALSE); } /* * This routine does the real work of a backward search. The pattern is sitting * in the external variable "re_pat". If found, dot is updated, the window * system is notified of the change, and TRUE is returned. If the string isn't * found, FALSE is returned. */ static int re_backsrch(void) { struct line *clp; int tbo; regmatch_t lastmatch; clp = curwp->w_dotp; tbo = curwp->w_doto; /* Start search one position to the left of dot */ tbo = tbo - 1; if (tbo < 0) { /* must move up one line */ clp = lback(clp); tbo = llength(clp); } /* * Note this loop does not process the last line, but this editor * always makes the last line empty so this is good. */ while (clp != (curbp->b_headp)) { re_match[0].rm_so = 0; re_match[0].rm_eo = llength(clp); lastmatch.rm_so = -1; /* * Keep searching until we don't match any longer. Assumes a * non-match does not modify the re_match array. We have to * do this character-by-character after the first match since * POSIX regexps don't give you a way to do reverse matches. */ while (!regexec(&re_buff, ltext(clp), RE_NMATCH, re_match, REG_STARTEND) && re_match[0].rm_so < tbo) { memcpy(&lastmatch, &re_match[0], sizeof(regmatch_t)); re_match[0].rm_so++; re_match[0].rm_eo = llength(clp); } if (lastmatch.rm_so == -1) { clp = lback(clp); tbo = llength(clp); } else { memcpy(&re_match[0], &lastmatch, sizeof(regmatch_t)); curwp->w_doto = re_match[0].rm_so; curwp->w_dotp = clp; curwp->w_rflag |= WFMOVE; return (TRUE); } } return (FALSE); } /* * Read a pattern. * Stash it in the external variable "re_pat". The "pat" is * not updated if the user types in an empty line. If the user typed * an empty line, and there is no old pattern, it is an error. * Display the old pattern, in the style of Jeff Lomicka. There is * some do-it-yourself control expansion. */ static int re_readpattern(char *prompt) { static int dofree = 0; int flags, error, s; char tpat[NPAT], *rep; if (re_pat[0] == '\0') rep = eread("%s: ", tpat, NPAT, EFNEW | EFCR, prompt); else rep = eread("%s: (default %s) ", tpat, NPAT, EFNUL | EFNEW | EFCR, prompt, re_pat); if (rep == NULL) return (ABORT); if (rep[0] != '\0') { /* New pattern given */ (void)strlcpy(re_pat, tpat, sizeof(re_pat)); if (casefoldsearch) flags = REG_EXTENDED | REG_ICASE; else flags = REG_EXTENDED; if (dofree) regfree(&re_buff); error = regcomp(&re_buff, re_pat, flags); if (error != 0) { char message[256]; regerror(error, &re_buff, message, sizeof(message)); ewprintf("Regex Error: %s", message); re_pat[0] = '\0'; return (FALSE); } dofree = 1; s = TRUE; } else if (rep[0] == '\0' && re_pat[0] != '\0') /* Just using old pattern */ s = TRUE; else s = FALSE; return (s); } /* * Cause case to not matter in searches. This is the default. If called * with argument cause case to matter. */ /* ARGSUSED*/ int setcasefold(int f, int n) { if (f & FFARG) { casefoldsearch = FALSE; ewprintf("Case-fold-search unset"); } else { casefoldsearch = TRUE; ewprintf("Case-fold-search set"); } /* * Invalidate the regular expression pattern since I'm too lazy to * recompile it. */ re_pat[0] = '\0'; return (TRUE); } /* * Delete all lines after dot that contain a string matching regex. */ /* ARGSUSED */ int delmatchlines(int f, int n) { int s; if ((s = re_readpattern("Flush lines (containing match for regexp)")) != TRUE) return (s); s = killmatches(TRUE); return (s); } /* * Delete all lines after dot that don't contain a string matching regex. */ /* ARGSUSED */ int delnonmatchlines(int f, int n) { int s; if ((s = re_readpattern("Keep lines (containing match for regexp)")) != TRUE) return (s); s = killmatches(FALSE); return (s); } /* * This function does the work of deleting matching lines. */ static int killmatches(int cond) { int s, error; int count = 0; struct line *clp; clp = curwp->w_dotp; if (curwp->w_doto == llength(clp)) /* Consider dot on next line */ clp = lforw(clp); while (clp != (curbp->b_headp)) { /* see if line matches */ re_match[0].rm_so = 0; re_match[0].rm_eo = llength(clp); error = regexec(&re_buff, ltext(clp), RE_NMATCH, re_match, REG_STARTEND); /* Delete line when appropriate */ if ((cond == FALSE && error) || (cond == TRUE && !error)) { curwp->w_doto = 0; curwp->w_dotp = clp; count++; s = ldelete(llength(clp) + 1, KNONE); clp = curwp->w_dotp; curwp->w_rflag |= WFMOVE; if (s == FALSE) return (FALSE); } else clp = lforw(clp); } ewprintf("%d line(s) deleted", count); if (count > 0) curwp->w_rflag |= WFMOVE; return (TRUE); } /* * Count lines matching regex. */ /* ARGSUSED */ int cntmatchlines(int f, int n) { int s; if ((s = re_readpattern("Count lines (matching regexp)")) != TRUE) return (s); s = countmatches(TRUE); return (s); } /* * Count lines that fail to match regex. */ /* ARGSUSED */ int cntnonmatchlines(int f, int n) { int s; if ((s = re_readpattern("Count lines (not matching regexp)")) != TRUE) return (s); s = countmatches(FALSE); return (s); } /* * This function does the work of counting matching lines. */ int countmatches(int cond) { int error; int count = 0; struct line *clp; clp = curwp->w_dotp; if (curwp->w_doto == llength(clp)) /* Consider dot on next line */ clp = lforw(clp); while (clp != (curbp->b_headp)) { /* see if line matches */ re_match[0].rm_so = 0; re_match[0].rm_eo = llength(clp); error = regexec(&re_buff, ltext(clp), RE_NMATCH, re_match, REG_STARTEND); /* Count line when appropriate */ if ((cond == FALSE && error) || (cond == TRUE && !error)) count++; clp = lforw(clp); } if (cond) ewprintf("Number of lines matching: %d", count); else ewprintf("Number of lines not matching: %d", count); return (TRUE); } #endif /* REGEX */