/* $NetBSD: search.c,v 1.1.1.1 2016/01/14 00:11:29 christos Exp $ */ /* search.c -- searching large bodies of text. Id: search.c,v 1.3 2004/04/11 17:56:46 karl Exp Copyright (C) 1993, 1997, 1998, 2002, 2004 Free Software Foundation, Inc. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. Written by Brian Fox (bfox@ai.mit.edu). */ #include "info.h" #include "search.h" #include "nodes.h" /* The search functions take two arguments: 1) a string to search for, and 2) a pointer to a SEARCH_BINDING which contains the buffer, start, and end of the search. They return a long, which is the offset from the start of the buffer at which the match was found. An offset of -1 indicates failure. */ /* A function which makes a binding with buffer and bounds. */ SEARCH_BINDING * make_binding (char *buffer, long int start, long int end) { SEARCH_BINDING *binding; binding = (SEARCH_BINDING *)xmalloc (sizeof (SEARCH_BINDING)); binding->buffer = buffer; binding->start = start; binding->end = end; binding->flags = 0; return (binding); } /* Make a copy of BINDING without duplicating the data. */ SEARCH_BINDING * copy_binding (SEARCH_BINDING *binding) { SEARCH_BINDING *copy; copy = make_binding (binding->buffer, binding->start, binding->end); copy->flags = binding->flags; return (copy); } /* **************************************************************** */ /* */ /* The Actual Searching Functions */ /* */ /* **************************************************************** */ /* Search forwards or backwards for the text delimited by BINDING. The search is forwards if BINDING->start is greater than BINDING->end. */ long search (char *string, SEARCH_BINDING *binding) { long result; /* If the search is backwards, then search backwards, otherwise forwards. */ if (binding->start > binding->end) result = search_backward (string, binding); else result = search_forward (string, binding); return (result); } /* Search forwards for STRING through the text delimited in BINDING. */ long search_forward (char *string, SEARCH_BINDING *binding) { register int c, i, len; register char *buff, *end; char *alternate = (char *)NULL; len = strlen (string); /* We match characters in the search buffer against STRING and ALTERNATE. ALTERNATE is a case reversed version of STRING; this is cheaper than case folding each character before comparison. Alternate is only used if the case folding bit is turned on in the passed BINDING. */ if (binding->flags & S_FoldCase) { alternate = xstrdup (string); for (i = 0; i < len; i++) { if (islower (alternate[i])) alternate[i] = toupper (alternate[i]); else if (isupper (alternate[i])) alternate[i] = tolower (alternate[i]); } } buff = binding->buffer + binding->start; end = binding->buffer + binding->end + 1; while (buff < (end - len)) { for (i = 0; i < len; i++) { c = buff[i]; if ((c != string[i]) && (!alternate || c != alternate[i])) break; } if (!string[i]) { if (alternate) free (alternate); if (binding->flags & S_SkipDest) buff += len; return ((long) (buff - binding->buffer)); } buff++; } if (alternate) free (alternate); return ((long) -1); } /* Search for STRING backwards through the text delimited in BINDING. */ long search_backward (char *input_string, SEARCH_BINDING *binding) { register int c, i, len; register char *buff, *end; char *string; char *alternate = (char *)NULL; len = strlen (input_string); /* Reverse the characters in the search string. */ string = (char *)xmalloc (1 + len); for (c = 0, i = len - 1; input_string[c]; c++, i--) string[i] = input_string[c]; string[c] = '\0'; /* We match characters in the search buffer against STRING and ALTERNATE. ALTERNATE is a case reversed version of STRING; this is cheaper than case folding each character before comparison. ALTERNATE is only used if the case folding bit is turned on in the passed BINDING. */ if (binding->flags & S_FoldCase) { alternate = xstrdup (string); for (i = 0; i < len; i++) { if (islower (alternate[i])) alternate[i] = toupper (alternate[i]); else if (isupper (alternate[i])) alternate[i] = tolower (alternate[i]); } } buff = binding->buffer + binding->start - 1; end = binding->buffer + binding->end; while (buff > (end + len)) { for (i = 0; i < len; i++) { c = *(buff - i); if (c != string[i] && (!alternate || c != alternate[i])) break; } if (!string[i]) { free (string); if (alternate) free (alternate); if (binding->flags & S_SkipDest) buff -= len; return ((long) (1 + (buff - binding->buffer))); } buff--; } free (string); if (alternate) free (alternate); return ((long) -1); } /* Find STRING in LINE, returning the offset of the end of the string. Return an offset of -1 if STRING does not appear in LINE. The search is bound by the end of the line (i.e., either NEWLINE or 0). */ int string_in_line (char *string, char *line) { register int end; SEARCH_BINDING binding; /* Find the end of the line. */ for (end = 0; line[end] && line[end] != '\n'; end++); /* Search for STRING within these confines. */ binding.buffer = line; binding.start = 0; binding.end = end; binding.flags = S_FoldCase | S_SkipDest; return (search_forward (string, &binding)); } /* Return non-zero if STRING is the first text to appear at BINDING. */ int looking_at (char *string, SEARCH_BINDING *binding) { long search_end; search_end = search (string, binding); /* If the string was not found, SEARCH_END is -1. If the string was found, but not right away, SEARCH_END is != binding->start. Otherwise, the string was found at binding->start. */ return (search_end == binding->start); } /* **************************************************************** */ /* */ /* Small String Searches */ /* */ /* **************************************************************** */ /* Function names that start with "skip" are passed a string, and return an offset from the start of that string. Function names that start with "find" are passed a SEARCH_BINDING, and return an absolute position marker of the item being searched for. "Find" functions return a value of -1 if the item being looked for couldn't be found. */ /* Return the index of the first non-whitespace character in STRING. */ int skip_whitespace (char *string) { register int i; for (i = 0; string && whitespace (string[i]); i++); return (i); } /* Return the index of the first non-whitespace or newline character in STRING. */ int skip_whitespace_and_newlines (char *string) { register int i; for (i = 0; string && whitespace_or_newline (string[i]); i++); return (i); } /* Return the index of the first whitespace character in STRING. */ int skip_non_whitespace (char *string) { register int i; for (i = 0; string && string[i] && !whitespace (string[i]); i++); return (i); } /* Return the index of the first non-node character in STRING. Note that this function contains quite a bit of hair to ignore periods in some special cases. This is because we here at GNU ship some info files which contain nodenames that contain periods. No such nodename can start with a period, or continue with whitespace, newline, or ')' immediately following the period. If second argument NEWLINES_OKAY is non-zero, newlines should be skipped while parsing out the nodename specification. */ int skip_node_characters (char *string, int newlines_okay) { register int c, i = 0; int paren_seen = 0; int paren = 0; /* Handle special case. This is when another function has parsed out the filename component of the node name, and we just want to parse out the nodename proper. In that case, a period at the start of the nodename indicates an empty nodename. */ if (string && *string == '.') return (0); if (string && *string == '(') { paren++; paren_seen++; i++; } for (; string && (c = string[i]); i++) { if (paren) { if (c == '(') paren++; else if (c == ')') paren--; continue; } /* If the character following the close paren is a space or period, then this node name has no more characters associated with it. */ if (c == '\t' || c == ',' || c == INFO_TAGSEP || ((!newlines_okay) && (c == '\n')) || ((paren_seen && string[i - 1] == ')') && (c == ' ' || c == '.')) || (c == '.' && ( #if 0 /* This test causes a node name ending in a period, like `This.', not to be found. The trailing . is stripped. This occurs in the jargon file (`I see no X here.' is a node name). */ (!string[i + 1]) || #endif (whitespace_or_newline (string[i + 1])) || (string[i + 1] == ')')))) break; } return (i); } /* **************************************************************** */ /* */ /* Searching FILE_BUFFER's */ /* */ /* **************************************************************** */ /* Return the absolute position of the first occurence of a node separator in BINDING-buffer. The search starts at BINDING->start. Return -1 if no node separator was found. */ long find_node_separator (SEARCH_BINDING *binding) { register long i; char *body; body = binding->buffer; /* A node is started by [^L]^_[^L]\n. That is to say, the C-l's are optional, but the DELETE and NEWLINE are not. This separator holds true for all separated elements in an Info file, including the tags table (if present) and the indirect tags table (if present). */ for (i = binding->start; i < binding->end - 1; i++) if (((body[i] == INFO_FF && body[i + 1] == INFO_COOKIE) && (body[i + 2] == '\n' || (body[i + 2] == INFO_FF && body[i + 3] == '\n'))) || ((body[i] == INFO_COOKIE) && (body[i + 1] == '\n' || (body[i + 1] == INFO_FF && body[i + 2] == '\n')))) return (i); return (-1); } /* Return the length of the node separator characters that BODY is currently pointing at. */ int skip_node_separator (char *body) { register int i; i = 0; if (body[i] == INFO_FF) i++; if (body[i++] != INFO_COOKIE) return (0); if (body[i] == INFO_FF) i++; if (body[i++] != '\n') return (0); return (i); } /* Return the number of characters from STRING to the start of the next line. */ int skip_line (char *string) { register int i; for (i = 0; string && string[i] && string[i] != '\n'; i++); if (string[i] == '\n') i++; return (i); } /* Return the absolute position of the beginning of a tags table in this binding starting the search at binding->start. */ long find_tags_table (SEARCH_BINDING *binding) { SEARCH_BINDING tmp_search; long position; tmp_search.buffer = binding->buffer; tmp_search.start = binding->start; tmp_search.end = binding->end; tmp_search.flags = S_FoldCase; while ((position = find_node_separator (&tmp_search)) != -1 ) { tmp_search.start = position; tmp_search.start += skip_node_separator (tmp_search.buffer + tmp_search.start); if (looking_at (TAGS_TABLE_BEG_LABEL, &tmp_search)) return (position); } return (-1); } /* Return the absolute position of the node named NODENAME in BINDING. This is a brute force search, and we wish to avoid it when possible. This function is called when a tag (indirect or otherwise) doesn't really point to the right node. It returns the absolute position of the separator preceding the node. */ long find_node_in_binding (char *nodename, SEARCH_BINDING *binding) { long position; int offset, namelen; SEARCH_BINDING tmp_search; namelen = strlen (nodename); tmp_search.buffer = binding->buffer; tmp_search.start = binding->start; tmp_search.end = binding->end; tmp_search.flags = 0; while ((position = find_node_separator (&tmp_search)) != -1) { tmp_search.start = position; tmp_search.start += skip_node_separator (tmp_search.buffer + tmp_search.start); offset = string_in_line (INFO_NODE_LABEL, tmp_search.buffer + tmp_search.start); if (offset == -1) continue; tmp_search.start += offset; tmp_search.start += skip_whitespace (tmp_search.buffer + tmp_search.start); offset = skip_node_characters (tmp_search.buffer + tmp_search.start, DONT_SKIP_NEWLINES); /* Notice that this is an exact match. You cannot grovel through the buffer with this function looking for random nodes. */ if ((offset == namelen) && (tmp_search.buffer[tmp_search.start] == nodename[0]) && (strncmp (tmp_search.buffer + tmp_search.start, nodename, offset) == 0)) return (position); } return (-1); }