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296 lines
11 KiB
EmacsLisp
296 lines
11 KiB
EmacsLisp
;;; regexp-opt.el --- generate efficient regexps to match strings
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;; Copyright (C) 1994-2012 Free Software Foundation, Inc.
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;; Author: Simon Marshall <simon@gnu.org>
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;; Maintainer: FSF
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;; Keywords: strings, regexps, extensions
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;; This file is part of GNU Emacs.
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;; GNU Emacs is free software: you can redistribute it and/or modify
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;; it under the terms of the GNU General Public License as published by
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;; the Free Software Foundation, either version 3 of the License, or
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;; (at your option) any later version.
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;; GNU Emacs is distributed in the hope that it will be useful,
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;; but WITHOUT ANY WARRANTY; without even the implied warranty of
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;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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;; GNU General Public License for more details.
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;; You should have received a copy of the GNU General Public License
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;; along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>.
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;;; Commentary:
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;; The "opt" in "regexp-opt" stands for "optim\\(al\\|i[sz]e\\)".
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;;
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;; This package generates a regexp from a given list of strings (which matches
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;; one of those strings) so that the regexp generated by:
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;;
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;; (regexp-opt strings)
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;;
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;; is equivalent to, but more efficient than, the regexp generated by:
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;;
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;; (mapconcat 'regexp-quote strings "\\|")
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;;
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;; For example:
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;;
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;; (let ((strings '("cond" "if" "when" "unless" "while"
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;; "let" "let*" "progn" "prog1" "prog2"
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;; "save-restriction" "save-excursion" "save-window-excursion"
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;; "save-current-buffer" "save-match-data"
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;; "catch" "throw" "unwind-protect" "condition-case")))
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;; (concat "(" (regexp-opt strings t) "\\>"))
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;; => "(\\(c\\(atch\\|ond\\(ition-case\\)?\\)\\|if\\|let\\*?\\|prog[12n]\\|save-\\(current-buffer\\|excursion\\|match-data\\|restriction\\|window-excursion\\)\\|throw\\|un\\(less\\|wind-protect\\)\\|wh\\(en\\|ile\\)\\)\\>"
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;;
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;; Searching using the above example `regexp-opt' regexp takes approximately
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;; two-thirds of the time taken using the equivalent `mapconcat' regexp.
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;; Since this package was written to produce efficient regexps, not regexps
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;; efficiently, it is probably not a good idea to in-line too many calls in
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;; your code, unless you use the following trick with `eval-when-compile':
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;;
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;; (defvar definition-regexp
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;; (eval-when-compile
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;; (concat "^("
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;; (regexp-opt '("defun" "defsubst" "defmacro" "defalias"
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;; "defvar" "defconst") t)
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;; "\\>")))
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;;
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;; The `byte-compile' code will be as if you had defined the variable thus:
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;;
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;; (defvar definition-regexp
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;; "^(\\(def\\(alias\\|const\\|macro\\|subst\\|un\\|var\\)\\)\\>")
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;;
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;; Note that if you use this trick for all instances of `regexp-opt' and
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;; `regexp-opt-depth' in your code, regexp-opt.el would only have to be loaded
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;; at compile time. But note also that using this trick means that should
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;; regexp-opt.el be changed, perhaps to fix a bug or to add a feature to
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;; improve the efficiency of `regexp-opt' regexps, you would have to recompile
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;; your code for such changes to have effect in your code.
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;; Originally written for font-lock.el, from an idea from Stig's hl319.el, with
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;; thanks for ideas also to Michael Ernst, Bob Glickstein, Dan Nicolaescu and
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;; Stefan Monnier.
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;; No doubt `regexp-opt' doesn't always produce optimal regexps, so code, ideas
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;; or any other information to improve things are welcome.
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;;
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;; One possible improvement would be to compile '("aa" "ab" "ba" "bb")
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;; into "[ab][ab]" rather than "a[ab]\\|b[ab]". I'm not sure it's worth
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;; it but if someone knows how to do it without going through too many
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;; contortions, I'm all ears.
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;;; Code:
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;;;###autoload
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(defun regexp-opt (strings &optional paren)
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"Return a regexp to match a string in the list STRINGS.
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Each string should be unique in STRINGS and should not contain any regexps,
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quoted or not. If optional PAREN is non-nil, ensure that the returned regexp
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is enclosed by at least one regexp grouping construct.
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The returned regexp is typically more efficient than the equivalent regexp:
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(let ((open (if PAREN \"\\\\(\" \"\")) (close (if PAREN \"\\\\)\" \"\")))
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(concat open (mapconcat 'regexp-quote STRINGS \"\\\\|\") close))
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If PAREN is `words', then the resulting regexp is additionally surrounded
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by \\=\\< and \\>.
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If PAREN is `symbols', then the resulting regexp is additionally surrounded
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by \\=\\_< and \\_>."
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(save-match-data
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;; Recurse on the sorted list.
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(let* ((max-lisp-eval-depth 10000)
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(max-specpdl-size 10000)
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(completion-ignore-case nil)
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(completion-regexp-list nil)
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(open (cond ((stringp paren) paren) (paren "\\(")))
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(sorted-strings (delete-dups
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(sort (copy-sequence strings) 'string-lessp)))
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(re (regexp-opt-group sorted-strings (or open t) (not open))))
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(cond ((eq paren 'words)
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(concat "\\<" re "\\>"))
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((eq paren 'symbols)
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(concat "\\_<" re "\\_>"))
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(t re)))))
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;;;###autoload
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(defun regexp-opt-depth (regexp)
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"Return the depth of REGEXP.
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This means the number of non-shy regexp grouping constructs
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\(parenthesized expressions) in REGEXP."
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(save-match-data
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;; Hack to signal an error if REGEXP does not have balanced parentheses.
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(string-match regexp "")
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;; Count the number of open parentheses in REGEXP.
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(let ((count 0) start last)
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(while (string-match "\\\\(\\(\\?[0-9]*:\\)?" regexp start)
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(setq start (match-end 0)) ; Start of next search.
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(when (and (not (match-beginning 1))
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(subregexp-context-p regexp (match-beginning 0) last))
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;; It's not a shy group and it's not inside brackets or after
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;; a backslash: it's really a group-open marker.
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(setq last start) ; Speed up next regexp-opt-re-context-p.
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(setq count (1+ count))))
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count)))
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;;; Workhorse functions.
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(eval-when-compile
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(require 'cl))
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(defun regexp-opt-group (strings &optional paren lax)
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"Return a regexp to match a string in the sorted list STRINGS.
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If PAREN non-nil, output regexp parentheses around returned regexp.
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If LAX non-nil, don't output parentheses if it doesn't require them.
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Merges keywords to avoid backtracking in Emacs' regexp matcher."
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;; The basic idea is to find the shortest common prefix or suffix, remove it
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;; and recurse. If there is no prefix, we divide the list into two so that
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;; \(at least) one half will have at least a one-character common prefix.
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;; Also we delay the addition of grouping parenthesis as long as possible
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;; until we're sure we need them, and try to remove one-character sequences
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;; so we can use character sets rather than grouping parenthesis.
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(let* ((open-group (cond ((stringp paren) paren) (paren "\\(?:") (t "")))
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(close-group (if paren "\\)" ""))
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(open-charset (if lax "" open-group))
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(close-charset (if lax "" close-group)))
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(cond
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;;
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;; If there are no strings, just return the empty string.
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((= (length strings) 0)
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"")
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;;
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;; If there is only one string, just return it.
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((= (length strings) 1)
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(if (= (length (car strings)) 1)
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(concat open-charset (regexp-quote (car strings)) close-charset)
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(concat open-group (regexp-quote (car strings)) close-group)))
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;;
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;; If there is an empty string, remove it and recurse on the rest.
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((= (length (car strings)) 0)
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(concat open-charset
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(regexp-opt-group (cdr strings) t t) "?"
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close-charset))
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;;
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;; If there are several one-char strings, use charsets
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((and (= (length (car strings)) 1)
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(let ((strs (cdr strings)))
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(while (and strs (/= (length (car strs)) 1))
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(pop strs))
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strs))
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(let (letters rest)
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;; Collect one-char strings
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(dolist (s strings)
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(if (= (length s) 1) (push (string-to-char s) letters) (push s rest)))
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(if rest
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;; several one-char strings: take them and recurse
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;; on the rest (first so as to match the longest).
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(concat open-group
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(regexp-opt-group (nreverse rest))
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"\\|" (regexp-opt-charset letters)
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close-group)
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;; all are one-char strings: just return a character set.
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(concat open-charset
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(regexp-opt-charset letters)
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close-charset))))
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;;
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;; We have a list of different length strings.
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(t
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(let ((prefix (try-completion "" strings)))
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(if (> (length prefix) 0)
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;; common prefix: take it and recurse on the suffixes.
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(let* ((n (length prefix))
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(suffixes (mapcar (lambda (s) (substring s n)) strings)))
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(concat open-group
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(regexp-quote prefix)
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(regexp-opt-group suffixes t t)
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close-group))
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(let* ((sgnirts (mapcar (lambda (s)
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(concat (nreverse (string-to-list s))))
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strings))
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(xiffus (try-completion "" sgnirts)))
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(if (> (length xiffus) 0)
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;; common suffix: take it and recurse on the prefixes.
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(let* ((n (- (length xiffus)))
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(prefixes
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;; Sorting is necessary in cases such as ("ad" "d").
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(sort (mapcar (lambda (s) (substring s 0 n)) strings)
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'string-lessp)))
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(concat open-group
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(regexp-opt-group prefixes t t)
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(regexp-quote
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(concat (nreverse (string-to-list xiffus))))
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close-group))
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;; Otherwise, divide the list into those that start with a
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;; particular letter and those that do not, and recurse on them.
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(let* ((char (substring-no-properties (car strings) 0 1))
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(half1 (all-completions char strings))
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(half2 (nthcdr (length half1) strings)))
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(concat open-group
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(regexp-opt-group half1)
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"\\|" (regexp-opt-group half2)
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close-group))))))))))
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(defun regexp-opt-charset (chars)
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"Return a regexp to match a character in CHARS."
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;; The basic idea is to find character ranges. Also we take care in the
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;; position of character set meta characters in the character set regexp.
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;;
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(let* ((charmap (make-char-table 'case-table))
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(start -1) (end -2)
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(charset "")
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(bracket "") (dash "") (caret ""))
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;;
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;; Make a character map but extract character set meta characters.
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(dolist (char chars)
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(case char
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(?\]
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(setq bracket "]"))
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(?^
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(setq caret "^"))
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(?-
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(setq dash "-"))
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(otherwise
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(aset charmap char t))))
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;;
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;; Make a character set from the map using ranges where applicable.
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(map-char-table
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(lambda (c v)
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(when v
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(if (consp c)
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(if (= (1- (car c)) end) (setq end (cdr c))
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(if (> end (+ start 2))
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(setq charset (format "%s%c-%c" charset start end))
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(while (>= end start)
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(setq charset (format "%s%c" charset start))
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(incf start)))
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(setq start (car c) end (cdr c)))
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(if (= (1- c) end) (setq end c)
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(if (> end (+ start 2))
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(setq charset (format "%s%c-%c" charset start end))
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(while (>= end start)
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(setq charset (format "%s%c" charset start))
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(incf start)))
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(setq start c end c)))))
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charmap)
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(when (>= end start)
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(if (> end (+ start 2))
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(setq charset (format "%s%c-%c" charset start end))
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(while (>= end start)
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(setq charset (format "%s%c" charset start))
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(incf start))))
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;;
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;; Make sure a caret is not first and a dash is first or last.
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(if (and (string-equal charset "") (string-equal bracket ""))
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(concat "[" dash caret "]")
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(concat "[" bracket charset caret dash "]"))))
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(provide 'regexp-opt)
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;;; regexp-opt.el ends here
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