/* * Copyright (C) 1984-2017 Mark Nudelman * * You may distribute under the terms of either the GNU General Public * License or the Less License, as specified in the README file. * * For more information, see the README file. */ /* * Routines to search a file for a pattern. */ #include "less.h" #include "position.h" #include "charset.h" #define MINPOS(a,b) (((a) < (b)) ? (a) : (b)) #define MAXPOS(a,b) (((a) > (b)) ? (a) : (b)) extern int sigs; extern int how_search; extern int caseless; extern int linenums; extern int sc_height; extern int jump_sline; extern int bs_mode; extern int ctldisp; extern int status_col; extern void *ml_search; extern POSITION start_attnpos; extern POSITION end_attnpos; extern int utf_mode; extern int screen_trashed; #if HILITE_SEARCH extern int hilite_search; extern int size_linebuf; extern int squished; extern int can_goto_line; static int hide_hilite; static POSITION prep_startpos; static POSITION prep_endpos; static int is_caseless; static int is_ucase_pattern; /* * Structures for maintaining a set of ranges for hilites and filtered-out * lines. Each range is stored as a node within a red-black tree, and we * try to extend existing ranges (without creating overlaps) rather than * create new nodes if possible. We remember the last node found by a * search for constant-time lookup if the next search is near enough to * the previous. To aid that, we overlay a secondary doubly-linked list * on top of the red-black tree so we can find the preceding/succeeding * nodes also in constant time. * * Each node is allocated from a series of pools, each pool double the size * of the previous (for amortised constant time allocation). Since our only * tree operations are clear and node insertion, not node removal, we don't * need to maintain a usage bitmap or freelist and can just return nodes * from the pool in-order until capacity is reached. */ struct hilite { POSITION hl_startpos; POSITION hl_endpos; }; struct hilite_node { struct hilite_node *parent; struct hilite_node *left; struct hilite_node *right; struct hilite_node *prev; struct hilite_node *next; int red; struct hilite r; }; struct hilite_storage { int capacity; int used; struct hilite_storage *next; struct hilite_node *nodes; }; struct hilite_tree { struct hilite_storage *first; struct hilite_storage *current; struct hilite_node *root; struct hilite_node *lookaside; }; #define HILITE_INITIALIZER() { NULL, NULL, NULL, NULL } #define HILITE_LOOKASIDE_STEPS 2 static struct hilite_tree hilite_anchor = HILITE_INITIALIZER(); static struct hilite_tree filter_anchor = HILITE_INITIALIZER(); #endif /* * These are the static variables that represent the "remembered" * search pattern and filter pattern. */ struct pattern_info { PATTERN_TYPE compiled; char* text; int search_type; }; #if NO_REGEX #define info_compiled(info) ((void*)0) #else #define info_compiled(info) ((info)->compiled) #endif static struct pattern_info search_info; static struct pattern_info filter_info; /* * Are there any uppercase letters in this string? */ static int is_ucase(str) char *str; { char *str_end = str + strlen(str); LWCHAR ch; while (str < str_end) { ch = step_char(&str, +1, str_end); if (IS_UPPER(ch)) return (1); } return (0); } /* * Compile and save a search pattern. */ static int set_pattern(info, pattern, search_type) struct pattern_info *info; char *pattern; int search_type; { #if !NO_REGEX if (pattern == NULL) CLEAR_PATTERN(info->compiled); else if (compile_pattern(pattern, search_type, &info->compiled) < 0) return -1; #endif /* Pattern compiled successfully; save the text too. */ if (info->text != NULL) free(info->text); info->text = NULL; if (pattern != NULL) { info->text = (char *) ecalloc(1, strlen(pattern)+1); strcpy(info->text, pattern); } info->search_type = search_type; /* * Ignore case if -I is set OR * -i is set AND the pattern is all lowercase. */ is_ucase_pattern = is_ucase(pattern); if (is_ucase_pattern && caseless != OPT_ONPLUS) is_caseless = 0; else is_caseless = caseless; return 0; } /* * Discard a saved pattern. */ static void clear_pattern(info) struct pattern_info *info; { if (info->text != NULL) free(info->text); info->text = NULL; #if !NO_REGEX uncompile_pattern(&info->compiled); #endif } /* * Initialize saved pattern to nothing. */ static void init_pattern(info) struct pattern_info *info; { CLEAR_PATTERN(info->compiled); info->text = NULL; info->search_type = 0; } /* * Initialize search variables. */ public void init_search() { init_pattern(&search_info); init_pattern(&filter_info); } /* * Determine which text conversions to perform before pattern matching. */ static int get_cvt_ops() { int ops = 0; if (is_caseless || bs_mode == BS_SPECIAL) { if (is_caseless) ops |= CVT_TO_LC; if (bs_mode == BS_SPECIAL) ops |= CVT_BS; if (bs_mode != BS_CONTROL) ops |= CVT_CRLF; } else if (bs_mode != BS_CONTROL) { ops |= CVT_CRLF; } if (ctldisp == OPT_ONPLUS) ops |= CVT_ANSI; return (ops); } /* * Is there a previous (remembered) search pattern? */ static int prev_pattern(info) struct pattern_info *info; { #if !NO_REGEX if ((info->search_type & SRCH_NO_REGEX) == 0) return (!is_null_pattern(info->compiled)); #endif return (info->text != NULL); } #if HILITE_SEARCH /* * Repaint the hilites currently displayed on the screen. * Repaint each line which contains highlighted text. * If on==0, force all hilites off. */ public void repaint_hilite(on) int on; { int sindex; POSITION pos; int save_hide_hilite; if (squished) repaint(); save_hide_hilite = hide_hilite; if (!on) { if (hide_hilite) return; hide_hilite = 1; } if (!can_goto_line) { repaint(); hide_hilite = save_hide_hilite; return; } for (sindex = TOP; sindex < TOP + sc_height-1; sindex++) { pos = position(sindex); if (pos == NULL_POSITION) continue; (void) forw_line(pos); goto_line(sindex); put_line(); } lower_left(); hide_hilite = save_hide_hilite; } /* * Clear the attn hilite. */ public void clear_attn() { int sindex; POSITION old_start_attnpos; POSITION old_end_attnpos; POSITION pos; POSITION epos; int moved = 0; if (start_attnpos == NULL_POSITION) return; old_start_attnpos = start_attnpos; old_end_attnpos = end_attnpos; start_attnpos = end_attnpos = NULL_POSITION; if (!can_goto_line) { repaint(); return; } if (squished) repaint(); for (sindex = TOP; sindex < TOP + sc_height-1; sindex++) { pos = position(sindex); if (pos == NULL_POSITION) continue; epos = position(sindex+1); if (pos <= old_end_attnpos && (epos == NULL_POSITION || epos > old_start_attnpos)) { (void) forw_line(pos); goto_line(sindex); put_line(); moved = 1; } } if (moved) lower_left(); } #endif /* * Hide search string highlighting. */ public void undo_search() { if (!prev_pattern(&search_info)) { if (hilite_anchor.first == NULL) { error("No previous regular expression", NULL_PARG); return; } clr_hilite(); /* Next time, hilite_anchor.first will be NULL. */ } clear_pattern(&search_info); #if HILITE_SEARCH hide_hilite = !hide_hilite; repaint_hilite(1); #endif } #if HILITE_SEARCH /* * Clear the hilite list. */ public void clr_hlist(anchor) struct hilite_tree *anchor; { struct hilite_storage *hls; struct hilite_storage *nexthls; for (hls = anchor->first; hls != NULL; hls = nexthls) { nexthls = hls->next; free((void*)hls->nodes); free((void*)hls); } anchor->first = NULL; anchor->current = NULL; anchor->root = NULL; anchor->lookaside = NULL; prep_startpos = prep_endpos = NULL_POSITION; } public void clr_hilite() { clr_hlist(&hilite_anchor); } public void clr_filter() { clr_hlist(&filter_anchor); } struct hilite_node* hlist_last(anchor) struct hilite_tree *anchor; { struct hilite_node *n = anchor->root; while (n != NULL && n->right != NULL) n = n->right; return n; } struct hilite_node* hlist_next(n) struct hilite_node *n; { return n->next; } struct hilite_node* hlist_prev(n) struct hilite_node *n; { return n->prev; } /* * Find the node covering pos, or the node after it if no node covers it, * or return NULL if pos is after the last range. Remember the found node, * to speed up subsequent searches for the same or similar positions (if * we return NULL, remember the last node.) */ struct hilite_node* hlist_find(anchor, pos) struct hilite_tree *anchor; POSITION pos; { struct hilite_node *n, *m; if (anchor->lookaside) { int steps = 0; int hit = 0; n = anchor->lookaside; for (;;) { if (pos < n->r.hl_endpos) { if (n->prev == NULL || pos >= n->prev->r.hl_endpos) { hit = 1; break; } } else if (n->next == NULL) { n = NULL; hit = 1; break; } /* * If we don't find the right node within a small * distance, don't keep doing a linear search! */ if (steps >= HILITE_LOOKASIDE_STEPS) break; steps++; if (pos < n->r.hl_endpos) anchor->lookaside = n = n->prev; else anchor->lookaside = n = n->next; } if (hit) return n; } n = anchor->root; m = NULL; while (n != NULL) { if (pos < n->r.hl_startpos) { if (n->left != NULL) { m = n; n = n->left; continue; } break; } if (pos >= n->r.hl_endpos) { if (n->right != NULL) { n = n->right; continue; } if (m != NULL) { n = m; } else { m = n; n = NULL; } } break; } if (n != NULL) anchor->lookaside = n; else if (m != NULL) anchor->lookaside = m; return n; } /* * Should any characters in a specified range be highlighted? */ static int is_hilited_range(pos, epos) POSITION pos; POSITION epos; { struct hilite_node *n = hlist_find(&hilite_anchor, pos); return (n != NULL && (epos == NULL_POSITION || epos > n->r.hl_startpos)); } /* * Is a line "filtered" -- that is, should it be hidden? */ public int is_filtered(pos) POSITION pos; { struct hilite_node *n; if (ch_getflags() & CH_HELPFILE) return (0); n = hlist_find(&filter_anchor, pos); return (n != NULL && pos >= n->r.hl_startpos); } /* * If pos is hidden, return the next position which isn't, otherwise * just return pos. */ public POSITION next_unfiltered(pos) POSITION pos; { struct hilite_node *n; if (ch_getflags() & CH_HELPFILE) return (pos); n = hlist_find(&filter_anchor, pos); while (n != NULL && pos >= n->r.hl_startpos) { pos = n->r.hl_endpos; n = n->next; } return (pos); } /* * If pos is hidden, return the previous position which isn't or 0 if * we're filtered right to the beginning, otherwise just return pos. */ public POSITION prev_unfiltered(pos) POSITION pos; { struct hilite_node *n; if (ch_getflags() & CH_HELPFILE) return (pos); n = hlist_find(&filter_anchor, pos); while (n != NULL && pos >= n->r.hl_startpos) { pos = n->r.hl_startpos; if (pos == 0) break; pos--; n = n->prev; } return (pos); } /* * Should any characters in a specified range be highlighted? * If nohide is nonzero, don't consider hide_hilite. */ public int is_hilited(pos, epos, nohide, p_matches) POSITION pos; POSITION epos; int nohide; int *p_matches; { int match; if (p_matches != NULL) *p_matches = 0; if (!status_col && start_attnpos != NULL_POSITION && pos < end_attnpos && (epos == NULL_POSITION || epos > start_attnpos)) /* * The attn line overlaps this range. */ return (1); match = is_hilited_range(pos, epos); if (!match) return (0); if (p_matches == NULL) /* * Kinda kludgy way to recognize that caller is checking for * hilite in status column. In this case we want to return * hilite status even if hiliting is disabled or hidden. */ return (1); /* * Report matches, even if we're hiding highlights. */ *p_matches = 1; if (hilite_search == 0) /* * Not doing highlighting. */ return (0); if (!nohide && hide_hilite) /* * Highlighting is hidden. */ return (0); return (1); } /* * Tree node storage: get the current block of nodes if it has spare * capacity, or create a new one if not. */ static struct hilite_storage* hlist_getstorage(anchor) struct hilite_tree *anchor; { int capacity = 1; struct hilite_storage *s; if (anchor->current) { if (anchor->current->used < anchor->current->capacity) return anchor->current; capacity = anchor->current->capacity * 2; } s = (struct hilite_storage *) ecalloc(1, sizeof(struct hilite_storage)); s->nodes = (struct hilite_node *) ecalloc(capacity, sizeof(struct hilite_node)); s->capacity = capacity; s->used = 0; s->next = NULL; if (anchor->current) anchor->current->next = s; else anchor->first = s; anchor->current = s; return s; } /* * Tree node storage: retrieve a new empty node to be inserted into the * tree. */ static struct hilite_node* hlist_getnode(anchor) struct hilite_tree *anchor; { struct hilite_storage *s = hlist_getstorage(anchor); return &s->nodes[s->used++]; } /* * Rotate the tree left around a pivot node. */ static void hlist_rotate_left(anchor, n) struct hilite_tree *anchor; struct hilite_node *n; { struct hilite_node *np = n->parent; struct hilite_node *nr = n->right; struct hilite_node *nrl = n->right->left; if (np != NULL) { if (n == np->left) np->left = nr; else np->right = nr; } else { anchor->root = nr; } nr->left = n; n->right = nrl; nr->parent = np; n->parent = nr; if (nrl != NULL) nrl->parent = n; } /* * Rotate the tree right around a pivot node. */ static void hlist_rotate_right(anchor, n) struct hilite_tree *anchor; struct hilite_node *n; { struct hilite_node *np = n->parent; struct hilite_node *nl = n->left; struct hilite_node *nlr = n->left->right; if (np != NULL) { if (n == np->right) np->right = nl; else np->left = nl; } else { anchor->root = nl; } nl->right = n; n->left = nlr; nl->parent = np; n->parent = nl; if (nlr != NULL) nlr->parent = n; } /* * Add a new hilite to a hilite list. */ static void add_hilite(anchor, hl) struct hilite_tree *anchor; struct hilite *hl; { struct hilite_node *p, *n, *u; /* Ignore empty ranges. */ if (hl->hl_startpos >= hl->hl_endpos) return; p = anchor->root; /* Inserting the very first node is trivial. */ if (p == NULL) { n = hlist_getnode(anchor); n->r = *hl; anchor->root = n; anchor->lookaside = n; return; } /* * Find our insertion point. If we come across any overlapping * or adjoining existing ranges, shrink our range and discard * if it become empty. */ for (;;) { if (hl->hl_startpos < p->r.hl_startpos) { if (hl->hl_endpos > p->r.hl_startpos) hl->hl_endpos = p->r.hl_startpos; if (p->left != NULL) { p = p->left; continue; } break; } if (hl->hl_startpos < p->r.hl_endpos) { hl->hl_startpos = p->r.hl_endpos; if (hl->hl_startpos >= hl->hl_endpos) return; } if (p->right != NULL) { p = p->right; continue; } break; } /* * Now we're at the right leaf, again check for contiguous ranges * and extend the existing node if possible to avoid the * insertion. Otherwise insert a new node at the leaf. */ if (hl->hl_startpos < p->r.hl_startpos) { if (hl->hl_endpos == p->r.hl_startpos) { p->r.hl_startpos = hl->hl_startpos; return; } if (p->prev != NULL && p->prev->r.hl_endpos == hl->hl_startpos) { p->prev->r.hl_endpos = hl->hl_endpos; return; } p->left = n = hlist_getnode(anchor); n->next = p; if (p->prev != NULL) { n->prev = p->prev; p->prev->next = n; } p->prev = n; } else { if (p->r.hl_endpos == hl->hl_startpos) { p->r.hl_endpos = hl->hl_endpos; return; } if (p->next != NULL && hl->hl_endpos == p->next->r.hl_startpos) { p->next->r.hl_startpos = hl->hl_startpos; return; } p->right = n = hlist_getnode(anchor); n->prev = p; if (p->next != NULL) { n->next = p->next; p->next->prev = n; } p->next = n; } n->parent = p; n->red = 1; n->r = *hl; /* * The tree is in the correct order and covers the right ranges * now, but may have become unbalanced. Rebalance it using the * standard red-black tree constraints and operations. */ for (;;) { /* case 1 - current is root, root is always black */ if (n->parent == NULL) { n->red = 0; break; } /* case 2 - parent is black, we can always be red */ if (!n->parent->red) break; /* * constraint: because the root must be black, if our * parent is red it cannot be the root therefore we must * have a grandparent */ /* * case 3 - parent and uncle are red, repaint them black, * the grandparent red, and start again at the grandparent. */ u = n->parent->parent->left; if (n->parent == u) u = n->parent->parent->right; if (u != NULL && u->red) { n->parent->red = 0; u->red = 0; n = n->parent->parent; n->red = 1; continue; } /* * case 4 - parent is red but uncle is black, parent and * grandparent on opposite sides. We need to start * changing the structure now. This and case 5 will shorten * our branch and lengthen the sibling, between them * restoring balance. */ if (n == n->parent->right && n->parent == n->parent->parent->left) { hlist_rotate_left(anchor, n->parent); n = n->left; } else if (n == n->parent->left && n->parent == n->parent->parent->right) { hlist_rotate_right(anchor, n->parent); n = n->right; } /* * case 5 - parent is red but uncle is black, parent and * grandparent on same side */ n->parent->red = 0; n->parent->parent->red = 1; if (n == n->parent->left) hlist_rotate_right(anchor, n->parent->parent); else hlist_rotate_left(anchor, n->parent->parent); break; } } /* * Hilight every character in a range of displayed characters. */ static void create_hilites(linepos, start_index, end_index, chpos) POSITION linepos; int start_index; int end_index; int *chpos; { struct hilite hl; int i; /* Start the first hilite. */ hl.hl_startpos = linepos + chpos[start_index]; /* * Step through the displayed chars. * If the source position (before cvt) of the char is one more * than the source pos of the previous char (the usual case), * just increase the size of the current hilite by one. * Otherwise (there are backspaces or something involved), * finish the current hilite and start a new one. */ for (i = start_index+1; i <= end_index; i++) { if (chpos[i] != chpos[i-1] + 1 || i == end_index) { hl.hl_endpos = linepos + chpos[i-1] + 1; add_hilite(&hilite_anchor, &hl); /* Start new hilite unless this is the last char. */ if (i < end_index) { hl.hl_startpos = linepos + chpos[i]; } } } } /* * Make a hilite for each string in a physical line which matches * the current pattern. * sp,ep delimit the first match already found. */ static void hilite_line(linepos, line, line_len, chpos, sp, ep, cvt_ops) POSITION linepos; char *line; int line_len; int *chpos; char *sp; char *ep; int cvt_ops; { char *searchp; char *line_end = line + line_len; /* * sp and ep delimit the first match in the line. * Mark the corresponding file positions, then * look for further matches and mark them. * {{ This technique, of calling match_pattern on subsequent * substrings of the line, may mark more than is correct * if the pattern starts with "^". This bug is fixed * for those regex functions that accept a notbol parameter * (currently POSIX, PCRE and V8-with-regexec2). }} */ searchp = line; do { if (sp == NULL || ep == NULL) return; create_hilites(linepos, sp-line, ep-line, chpos); /* * If we matched more than zero characters, * move to the first char after the string we matched. * If we matched zero, just move to the next char. */ if (ep > searchp) searchp = ep; else if (searchp != line_end) searchp++; else /* end of line */ break; } while (match_pattern(info_compiled(&search_info), search_info.text, searchp, line_end - searchp, &sp, &ep, 1, search_info.search_type)); } #endif #if HILITE_SEARCH /* * Find matching text which is currently on screen and highlight it. */ static void hilite_screen() { struct scrpos scrpos; get_scrpos(&scrpos, TOP); if (scrpos.pos == NULL_POSITION) return; prep_hilite(scrpos.pos, position(BOTTOM_PLUS_ONE), -1); repaint_hilite(1); } /* * Change highlighting parameters. */ public void chg_hilite() { /* * Erase any highlights currently on screen. */ clr_hilite(); hide_hilite = 0; if (hilite_search == OPT_ONPLUS) /* * Display highlights. */ hilite_screen(); } #endif /* * Figure out where to start a search. */ static POSITION search_pos(search_type) int search_type; { POSITION pos; int sindex; if (empty_screen()) { /* * Start at the beginning (or end) of the file. * The empty_screen() case is mainly for * command line initiated searches; * for example, "+/xyz" on the command line. * Also for multi-file (SRCH_PAST_EOF) searches. */ if (search_type & SRCH_FORW) { pos = ch_zero(); } else { pos = ch_length(); if (pos == NULL_POSITION) { (void) ch_end_seek(); pos = ch_length(); } } sindex = 0; } else { int add_one = 0; if (how_search == OPT_ON) { /* * Search does not include current screen. */ if (search_type & SRCH_FORW) sindex = sc_height-1; /* BOTTOM_PLUS_ONE */ else sindex = 0; /* TOP */ } else if (how_search == OPT_ONPLUS && !(search_type & SRCH_AFTER_TARGET)) { /* * Search includes all of displayed screen. */ if (search_type & SRCH_FORW) sindex = 0; /* TOP */ else sindex = sc_height-1; /* BOTTOM_PLUS_ONE */ } else { /* * Search includes the part of current screen beyond the jump target. * It starts at the jump target (if searching backwards), * or at the jump target plus one (if forwards). */ sindex = sindex_from_sline(jump_sline); if (search_type & SRCH_FORW) add_one = 1; } pos = position(sindex); if (add_one) pos = forw_raw_line(pos, (char **)NULL, (int *)NULL); } /* * If the line is empty, look around for a plausible starting place. */ if (search_type & SRCH_FORW) { while (pos == NULL_POSITION) { if (++sindex >= sc_height) break; pos = position(sindex); } } else { while (pos == NULL_POSITION) { if (--sindex < 0) break; pos = position(sindex); } } return (pos); } /* * Search a subset of the file, specified by start/end position. */ static int search_range(pos, endpos, search_type, matches, maxlines, plinepos, pendpos) POSITION pos; POSITION endpos; int search_type; int matches; int maxlines; POSITION *plinepos; POSITION *pendpos; { char *line; char *cline; int line_len; LINENUM linenum; char *sp, *ep; int line_match; int cvt_ops; int cvt_len; int *chpos; POSITION linepos, oldpos; linenum = find_linenum(pos); oldpos = pos; for (;;) { /* * Get lines until we find a matching one or until * we hit end-of-file (or beginning-of-file if we're * going backwards), or until we hit the end position. */ if (ABORT_SIGS()) { /* * A signal aborts the search. */ return (-1); } if ((endpos != NULL_POSITION && pos >= endpos) || maxlines == 0) { /* * Reached end position without a match. */ if (pendpos != NULL) *pendpos = pos; return (matches); } if (maxlines > 0) maxlines--; if (search_type & SRCH_FORW) { /* * Read the next line, and save the * starting position of that line in linepos. */ linepos = pos; pos = forw_raw_line(pos, &line, &line_len); if (linenum != 0) linenum++; } else { /* * Read the previous line and save the * starting position of that line in linepos. */ pos = back_raw_line(pos, &line, &line_len); linepos = pos; if (linenum != 0) linenum--; } if (pos == NULL_POSITION) { /* * Reached EOF/BOF without a match. */ if (pendpos != NULL) *pendpos = oldpos; return (matches); } /* * If we're using line numbers, we might as well * remember the information we have now (the position * and line number of the current line). * Don't do it for every line because it slows down * the search. Remember the line number only if * we're "far" from the last place we remembered it. */ if (linenums && abs((int)(pos - oldpos)) > 2048) add_lnum(linenum, pos); oldpos = pos; if (is_filtered(linepos)) continue; /* * If it's a caseless search, convert the line to lowercase. * If we're doing backspace processing, delete backspaces. */ cvt_ops = get_cvt_ops(); cvt_len = cvt_length(line_len, cvt_ops); cline = (char *) ecalloc(1, cvt_len); chpos = cvt_alloc_chpos(cvt_len); cvt_text(cline, line, chpos, &line_len, cvt_ops); #if HILITE_SEARCH /* * Check to see if the line matches the filter pattern. * If so, add an entry to the filter list. */ if (((search_type & SRCH_FIND_ALL) || prep_startpos == NULL_POSITION || linepos < prep_startpos || linepos >= prep_endpos) && prev_pattern(&filter_info)) { int line_filter = match_pattern(info_compiled(&filter_info), filter_info.text, cline, line_len, &sp, &ep, 0, filter_info.search_type); if (line_filter) { struct hilite hl; hl.hl_startpos = linepos; hl.hl_endpos = pos; add_hilite(&filter_anchor, &hl); free(cline); free(chpos); continue; } } #endif /* * Test the next line to see if we have a match. * We are successful if we either want a match and got one, * or if we want a non-match and got one. */ if (prev_pattern(&search_info)) { line_match = match_pattern(info_compiled(&search_info), search_info.text, cline, line_len, &sp, &ep, 0, search_type); if (line_match) { /* * Got a match. */ if (search_type & SRCH_FIND_ALL) { #if HILITE_SEARCH /* * We are supposed to find all matches in the range. * Just add the matches in this line to the * hilite list and keep searching. */ hilite_line(linepos, cline, line_len, chpos, sp, ep, cvt_ops); #endif } else if (--matches <= 0) { /* * Found the one match we're looking for. * Return it. */ #if HILITE_SEARCH if (hilite_search == OPT_ON) { /* * Clear the hilite list and add only * the matches in this one line. */ clr_hilite(); hilite_line(linepos, cline, line_len, chpos, sp, ep, cvt_ops); } #endif free(cline); free(chpos); if (plinepos != NULL) *plinepos = linepos; return (0); } } } free(cline); free(chpos); } } /* * search for a pattern in history. If found, compile that pattern. */ static int hist_pattern(search_type) int search_type; { #if CMD_HISTORY char *pattern; set_mlist(ml_search, 0); pattern = cmd_lastpattern(); if (pattern == NULL) return (0); if (set_pattern(&search_info, pattern, search_type) < 0) return (0); #if HILITE_SEARCH if (hilite_search == OPT_ONPLUS && !hide_hilite) hilite_screen(); #endif return (1); #else /* CMD_HISTORY */ return (0); #endif /* CMD_HISTORY */ } /* * Change the caseless-ness of searches. * Updates the internal search state to reflect a change in the -i flag. */ public void chg_caseless() { if (!is_ucase_pattern) /* * Pattern did not have uppercase. * Just set the search caselessness to the global caselessness. */ is_caseless = caseless; else { /* * Pattern did have uppercase. * Regenerate the pattern using the new state. */ clear_pattern(&search_info); hist_pattern(search_info.search_type); } } /* * Search for the n-th occurrence of a specified pattern, * either forward or backward. * Return the number of matches not yet found in this file * (that is, n minus the number of matches found). * Return -1 if the search should be aborted. * Caller may continue the search in another file * if less than n matches are found in this file. */ public int search(search_type, pattern, n) int search_type; char *pattern; int n; { POSITION pos; if (pattern == NULL || *pattern == '\0') { /* * A null pattern means use the previously compiled pattern. */ search_type |= SRCH_AFTER_TARGET; if (!prev_pattern(&search_info) && !hist_pattern(search_type)) { error("No previous regular expression", NULL_PARG); return (-1); } if ((search_type & SRCH_NO_REGEX) != (search_info.search_type & SRCH_NO_REGEX)) { error("Please re-enter search pattern", NULL_PARG); return -1; } #if HILITE_SEARCH if (hilite_search == OPT_ON || status_col) { /* * Erase the highlights currently on screen. * If the search fails, we'll redisplay them later. */ repaint_hilite(0); } if (hilite_search == OPT_ONPLUS && hide_hilite) { /* * Highlight any matches currently on screen, * before we actually start the search. */ hide_hilite = 0; hilite_screen(); } hide_hilite = 0; #endif } else { /* * Compile the pattern. */ if (set_pattern(&search_info, pattern, search_type) < 0) return (-1); #if HILITE_SEARCH if (hilite_search || status_col) { /* * Erase the highlights currently on screen. * Also permanently delete them from the hilite list. */ repaint_hilite(0); hide_hilite = 0; clr_hilite(); } if (hilite_search == OPT_ONPLUS || status_col) { /* * Highlight any matches currently on screen, * before we actually start the search. */ hilite_screen(); } #endif } /* * Figure out where to start the search. */ pos = search_pos(search_type); if (pos == NULL_POSITION) { /* * Can't find anyplace to start searching from. */ if (search_type & SRCH_PAST_EOF) return (n); if (hilite_search == OPT_ON || status_col) repaint_hilite(1); error("Nothing to search", NULL_PARG); return (-1); } n = search_range(pos, NULL_POSITION, search_type, n, -1, &pos, (POSITION*)NULL); if (n != 0) { /* * Search was unsuccessful. */ #if HILITE_SEARCH if ((hilite_search == OPT_ON || status_col) && n > 0) /* * Redisplay old hilites. */ repaint_hilite(1); #endif return (n); } if (!(search_type & SRCH_NO_MOVE)) { /* * Go to the matching line. */ jump_loc(pos, jump_sline); } #if HILITE_SEARCH if (hilite_search == OPT_ON || status_col) /* * Display new hilites in the matching line. */ repaint_hilite(1); #endif return (0); } #if HILITE_SEARCH /* * Prepare hilites in a given range of the file. * * The pair (prep_startpos,prep_endpos) delimits a contiguous region * of the file that has been "prepared"; that is, scanned for matches for * the current search pattern, and hilites have been created for such matches. * If prep_startpos == NULL_POSITION, the prep region is empty. * If prep_endpos == NULL_POSITION, the prep region extends to EOF. * prep_hilite asks that the range (spos,epos) be covered by the prep region. */ public void prep_hilite(spos, epos, maxlines) POSITION spos; POSITION epos; int maxlines; { POSITION nprep_startpos = prep_startpos; POSITION nprep_endpos = prep_endpos; POSITION new_epos; POSITION max_epos; int result; int i; /* * Search beyond where we're asked to search, so the prep region covers * more than we need. Do one big search instead of a bunch of small ones. */ #define SEARCH_MORE (3*size_linebuf) if (!prev_pattern(&search_info) && !is_filtering()) return; /* * Make sure our prep region always starts at the beginning of * a line. (search_range takes care of the end boundary below.) */ spos = back_raw_line(spos+1, (char **)NULL, (int *)NULL); /* * If we're limited to a max number of lines, figure out the * file position we should stop at. */ if (maxlines < 0) max_epos = NULL_POSITION; else { max_epos = spos; for (i = 0; i < maxlines; i++) max_epos = forw_raw_line(max_epos, (char **)NULL, (int *)NULL); } /* * Find two ranges: * The range that we need to search (spos,epos); and the range that * the "prep" region will then cover (nprep_startpos,nprep_endpos). */ if (prep_startpos == NULL_POSITION || (epos != NULL_POSITION && epos < prep_startpos) || spos > prep_endpos) { /* * New range is not contiguous with old prep region. * Discard the old prep region and start a new one. */ clr_hilite(); clr_filter(); if (epos != NULL_POSITION) epos += SEARCH_MORE; nprep_startpos = spos; } else { /* * New range partially or completely overlaps old prep region. */ if (epos == NULL_POSITION) { /* * New range goes to end of file. */ ; } else if (epos > prep_endpos) { /* * New range ends after old prep region. * Extend prep region to end at end of new range. */ epos += SEARCH_MORE; } else /* (epos <= prep_endpos) */ { /* * New range ends within old prep region. * Truncate search to end at start of old prep region. */ epos = prep_startpos; } if (spos < prep_startpos) { /* * New range starts before old prep region. * Extend old prep region backwards to start at * start of new range. */ if (spos < SEARCH_MORE) spos = 0; else spos -= SEARCH_MORE; nprep_startpos = spos; } else /* (spos >= prep_startpos) */ { /* * New range starts within or after old prep region. * Trim search to start at end of old prep region. */ spos = prep_endpos; } } if (epos != NULL_POSITION && max_epos != NULL_POSITION && epos > max_epos) /* * Don't go past the max position we're allowed. */ epos = max_epos; if (epos == NULL_POSITION || epos > spos) { int search_type = SRCH_FORW | SRCH_FIND_ALL; search_type |= (search_info.search_type & SRCH_NO_REGEX); for (;;) { result = search_range(spos, epos, search_type, 0, maxlines, (POSITION*)NULL, &new_epos); if (result < 0) return; if (prep_endpos == NULL_POSITION || new_epos > prep_endpos) nprep_endpos = new_epos; /* * Check both ends of the resulting prep region to * make sure they're not filtered. If they are, * keep going at least one more line until we find * something that isn't filtered, or hit the end. */ if (prep_endpos == NULL_POSITION || nprep_endpos > prep_endpos) { if (new_epos >= nprep_endpos && is_filtered(new_epos-1)) { spos = nprep_endpos; epos = forw_raw_line(nprep_endpos, (char **)NULL, (int *)NULL); if (epos == NULL_POSITION) break; maxlines = 1; continue; } } if (prep_startpos == NULL_POSITION || nprep_startpos < prep_startpos) { if (nprep_startpos > 0 && is_filtered(nprep_startpos)) { epos = nprep_startpos; spos = back_raw_line(nprep_startpos, (char **)NULL, (int *)NULL); if (spos == NULL_POSITION) break; nprep_startpos = spos; maxlines = 1; continue; } } break; } } prep_startpos = nprep_startpos; prep_endpos = nprep_endpos; } /* * Set the pattern to be used for line filtering. */ public void set_filter_pattern(pattern, search_type) char *pattern; int search_type; { clr_filter(); if (pattern == NULL || *pattern == '\0') clear_pattern(&filter_info); else set_pattern(&filter_info, pattern, search_type); screen_trashed = 1; } /* * Is there a line filter in effect? */ public int is_filtering() { if (ch_getflags() & CH_HELPFILE) return (0); return prev_pattern(&filter_info); } #endif #if HAVE_V8_REGCOMP /* * This function is called by the V8 regcomp to report * errors in regular expressions. */ public int reg_show_error = 1; void regerror(s) char *s; { PARG parg; if (!reg_show_error) return; parg.p_string = s; error("%s", &parg); } #endif