(init_system_name): Don't accept localhost.localdomain.
[emacs.git] / lisp / subr.el
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1 ;;; subr.el --- basic lisp subroutines for Emacs
3 ;; Copyright (C) 1985, 1986, 1992, 1994, 1995, 1999, 2000, 2001, 2002, 2003,
4 ;; 2004, 2005, 2006, 2007 Free Software Foundation, Inc.
6 ;; Maintainer: FSF
7 ;; Keywords: internal
9 ;; This file is part of GNU Emacs.
11 ;; GNU Emacs is free software; you can redistribute it and/or modify
12 ;; it under the terms of the GNU General Public License as published by
13 ;; the Free Software Foundation; either version 2, or (at your option)
14 ;; any later version.
16 ;; GNU Emacs is distributed in the hope that it will be useful,
17 ;; but WITHOUT ANY WARRANTY; without even the implied warranty of
18 ;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 ;; GNU General Public License for more details.
21 ;; You should have received a copy of the GNU General Public License
22 ;; along with GNU Emacs; see the file COPYING. If not, write to the
23 ;; Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
24 ;; Boston, MA 02110-1301, USA.
26 ;;; Commentary:
28 ;;; Code:
29 (defvar custom-declare-variable-list nil
30 "Record `defcustom' calls made before `custom.el' is loaded to handle them.
31 Each element of this list holds the arguments to one call to `defcustom'.")
33 ;; Use this, rather than defcustom, in subr.el and other files loaded
34 ;; before custom.el.
35 (defun custom-declare-variable-early (&rest arguments)
36 (setq custom-declare-variable-list
37 (cons arguments custom-declare-variable-list)))
40 ;;;; Basic Lisp macros.
42 (defalias 'not 'null)
44 (defmacro noreturn (form)
45 "Evaluate FORM, expecting it not to return.
46 If FORM does return, signal an error."
47 `(prog1 ,form
48 (error "Form marked with `noreturn' did return")))
50 (defmacro 1value (form)
51 "Evaluate FORM, expecting a constant return value.
52 This is the global do-nothing version. There is also `testcover-1value'
53 that complains if FORM ever does return differing values."
54 form)
56 (defmacro def-edebug-spec (symbol spec)
57 "Set the `edebug-form-spec' property of SYMBOL according to SPEC.
58 Both SYMBOL and SPEC are unevaluated. The SPEC can be 0, t, a symbol
59 \(naming a function), or a list."
60 `(put (quote ,symbol) 'edebug-form-spec (quote ,spec)))
62 (defmacro lambda (&rest cdr)
63 "Return a lambda expression.
64 A call of the form (lambda ARGS DOCSTRING INTERACTIVE BODY) is
65 self-quoting; the result of evaluating the lambda expression is the
66 expression itself. The lambda expression may then be treated as a
67 function, i.e., stored as the function value of a symbol, passed to
68 `funcall' or `mapcar', etc.
70 ARGS should take the same form as an argument list for a `defun'.
71 DOCSTRING is an optional documentation string.
72 If present, it should describe how to call the function.
73 But documentation strings are usually not useful in nameless functions.
74 INTERACTIVE should be a call to the function `interactive', which see.
75 It may also be omitted.
76 BODY should be a list of Lisp expressions.
78 \(fn ARGS [DOCSTRING] [INTERACTIVE] BODY)"
79 ;; Note that this definition should not use backquotes; subr.el should not
80 ;; depend on backquote.el.
81 (list 'function (cons 'lambda cdr)))
83 (defmacro push (newelt listname)
84 "Add NEWELT to the list stored in the symbol LISTNAME.
85 This is equivalent to (setq LISTNAME (cons NEWELT LISTNAME)).
86 LISTNAME must be a symbol."
87 (declare (debug (form sexp)))
88 (list 'setq listname
89 (list 'cons newelt listname)))
91 (defmacro pop (listname)
92 "Return the first element of LISTNAME's value, and remove it from the list.
93 LISTNAME must be a symbol whose value is a list.
94 If the value is nil, `pop' returns nil but does not actually
95 change the list."
96 (declare (debug (sexp)))
97 (list 'car
98 (list 'prog1 listname
99 (list 'setq listname (list 'cdr listname)))))
101 (defmacro when (cond &rest body)
102 "If COND yields non-nil, do BODY, else return nil.
103 When COND yields non-nil, eval BODY forms sequentially and return
104 value of last one, or nil if there are none.
106 \(fn COND BODY ...)"
107 (declare (indent 1) (debug t))
108 (list 'if cond (cons 'progn body)))
110 (defmacro unless (cond &rest body)
111 "If COND yields nil, do BODY, else return nil.
112 When COND yields nil, eval BODY forms sequentially and return
113 value of last one, or nil if there are none.
115 \(fn COND BODY ...)"
116 (declare (indent 1) (debug t))
117 (cons 'if (cons cond (cons nil body))))
119 (defvar --dolist-tail-- nil
120 "Temporary variable used in `dolist' expansion.")
122 (defmacro dolist (spec &rest body)
123 "Loop over a list.
124 Evaluate BODY with VAR bound to each car from LIST, in turn.
125 Then evaluate RESULT to get return value, default nil.
127 \(fn (VAR LIST [RESULT]) BODY...)"
128 (declare (indent 1) (debug ((symbolp form &optional form) body)))
129 ;; It would be cleaner to create an uninterned symbol,
130 ;; but that uses a lot more space when many functions in many files
131 ;; use dolist.
132 (let ((temp '--dolist-tail--))
133 `(let ((,temp ,(nth 1 spec))
134 ,(car spec))
135 (while ,temp
136 (setq ,(car spec) (car ,temp))
137 ,@body
138 (setq ,temp (cdr ,temp)))
139 ,@(if (cdr (cdr spec))
140 `((setq ,(car spec) nil) ,@(cdr (cdr spec)))))))
142 (defvar --dotimes-limit-- nil
143 "Temporary variable used in `dotimes' expansion.")
145 (defmacro dotimes (spec &rest body)
146 "Loop a certain number of times.
147 Evaluate BODY with VAR bound to successive integers running from 0,
148 inclusive, to COUNT, exclusive. Then evaluate RESULT to get
149 the return value (nil if RESULT is omitted).
151 \(fn (VAR COUNT [RESULT]) BODY...)"
152 (declare (indent 1) (debug dolist))
153 ;; It would be cleaner to create an uninterned symbol,
154 ;; but that uses a lot more space when many functions in many files
155 ;; use dotimes.
156 (let ((temp '--dotimes-limit--)
157 (start 0)
158 (end (nth 1 spec)))
159 `(let ((,temp ,end)
160 (,(car spec) ,start))
161 (while (< ,(car spec) ,temp)
162 ,@body
163 (setq ,(car spec) (1+ ,(car spec))))
164 ,@(cdr (cdr spec)))))
166 (defmacro declare (&rest specs)
167 "Do not evaluate any arguments and return nil.
168 Treated as a declaration when used at the right place in a
169 `defmacro' form. \(See Info anchor `(elisp)Definition of declare'.)"
170 nil)
172 ;;;; Basic Lisp functions.
174 (defun ignore (&rest ignore)
175 "Do nothing and return nil.
176 This function accepts any number of arguments, but ignores them."
177 (interactive)
178 nil)
180 (defun error (&rest args)
181 "Signal an error, making error message by passing all args to `format'.
182 In Emacs, the convention is that error messages start with a capital
183 letter but *do not* end with a period. Please follow this convention
184 for the sake of consistency."
185 (while t
186 (signal 'error (list (apply 'format args)))))
188 ;; We put this here instead of in frame.el so that it's defined even on
189 ;; systems where frame.el isn't loaded.
190 (defun frame-configuration-p (object)
191 "Return non-nil if OBJECT seems to be a frame configuration.
192 Any list whose car is `frame-configuration' is assumed to be a frame
193 configuration."
194 (and (consp object)
195 (eq (car object) 'frame-configuration)))
197 (defun functionp (object)
198 "Non-nil if OBJECT is any kind of function or a special form.
199 Also non-nil if OBJECT is a symbol and its function definition is
200 \(recursively) a function or special form. This does not include
201 macros."
202 (or (and (symbolp object) (fboundp object)
203 (condition-case nil
204 (setq object (indirect-function object))
205 (error nil))
206 (eq (car-safe object) 'autoload)
207 (not (car-safe (cdr-safe (cdr-safe (cdr-safe (cdr-safe object)))))))
208 (subrp object) (byte-code-function-p object)
209 (eq (car-safe object) 'lambda)))
211 ;;;; List functions.
213 (defsubst caar (x)
214 "Return the car of the car of X."
215 (car (car x)))
217 (defsubst cadr (x)
218 "Return the car of the cdr of X."
219 (car (cdr x)))
221 (defsubst cdar (x)
222 "Return the cdr of the car of X."
223 (cdr (car x)))
225 (defsubst cddr (x)
226 "Return the cdr of the cdr of X."
227 (cdr (cdr x)))
229 (defun last (list &optional n)
230 "Return the last link of LIST. Its car is the last element.
231 If LIST is nil, return nil.
232 If N is non-nil, return the Nth-to-last link of LIST.
233 If N is bigger than the length of LIST, return LIST."
234 (if n
235 (let ((m 0) (p list))
236 (while (consp p)
237 (setq m (1+ m) p (cdr p)))
238 (if (<= n 0) p
239 (if (< n m) (nthcdr (- m n) list) list)))
240 (while (consp (cdr list))
241 (setq list (cdr list)))
242 list))
244 (defun butlast (list &optional n)
245 "Return a copy of LIST with the last N elements removed."
246 (if (and n (<= n 0)) list
247 (nbutlast (copy-sequence list) n)))
249 (defun nbutlast (list &optional n)
250 "Modifies LIST to remove the last N elements."
251 (let ((m (length list)))
252 (or n (setq n 1))
253 (and (< n m)
254 (progn
255 (if (> n 0) (setcdr (nthcdr (- (1- m) n) list) nil))
256 list))))
258 (defun delete-dups (list)
259 "Destructively remove `equal' duplicates from LIST.
260 Store the result in LIST and return it. LIST must be a proper list.
261 Of several `equal' occurrences of an element in LIST, the first
262 one is kept."
263 (let ((tail list))
264 (while tail
265 (setcdr tail (delete (car tail) (cdr tail)))
266 (setq tail (cdr tail))))
267 list)
269 (defun number-sequence (from &optional to inc)
270 "Return a sequence of numbers from FROM to TO (both inclusive) as a list.
271 INC is the increment used between numbers in the sequence and defaults to 1.
272 So, the Nth element of the list is \(+ FROM \(* N INC)) where N counts from
273 zero. TO is only included if there is an N for which TO = FROM + N * INC.
274 If TO is nil or numerically equal to FROM, return \(FROM).
275 If INC is positive and TO is less than FROM, or INC is negative
276 and TO is larger than FROM, return nil.
277 If INC is zero and TO is neither nil nor numerically equal to
278 FROM, signal an error.
280 This function is primarily designed for integer arguments.
281 Nevertheless, FROM, TO and INC can be integer or float. However,
282 floating point arithmetic is inexact. For instance, depending on
283 the machine, it may quite well happen that
284 \(number-sequence 0.4 0.6 0.2) returns the one element list \(0.4),
285 whereas \(number-sequence 0.4 0.8 0.2) returns a list with three
286 elements. Thus, if some of the arguments are floats and one wants
287 to make sure that TO is included, one may have to explicitly write
288 TO as \(+ FROM \(* N INC)) or use a variable whose value was
289 computed with this exact expression. Alternatively, you can,
290 of course, also replace TO with a slightly larger value
291 \(or a slightly more negative value if INC is negative)."
292 (if (or (not to) (= from to))
293 (list from)
294 (or inc (setq inc 1))
295 (when (zerop inc) (error "The increment can not be zero"))
296 (let (seq (n 0) (next from))
297 (if (> inc 0)
298 (while (<= next to)
299 (setq seq (cons next seq)
300 n (1+ n)
301 next (+ from (* n inc))))
302 (while (>= next to)
303 (setq seq (cons next seq)
304 n (1+ n)
305 next (+ from (* n inc)))))
306 (nreverse seq))))
308 (defun copy-tree (tree &optional vecp)
309 "Make a copy of TREE.
310 If TREE is a cons cell, this recursively copies both its car and its cdr.
311 Contrast to `copy-sequence', which copies only along the cdrs. With second
312 argument VECP, this copies vectors as well as conses."
313 (if (consp tree)
314 (let (result)
315 (while (consp tree)
316 (let ((newcar (car tree)))
317 (if (or (consp (car tree)) (and vecp (vectorp (car tree))))
318 (setq newcar (copy-tree (car tree) vecp)))
319 (push newcar result))
320 (setq tree (cdr tree)))
321 (nconc (nreverse result) tree))
322 (if (and vecp (vectorp tree))
323 (let ((i (length (setq tree (copy-sequence tree)))))
324 (while (>= (setq i (1- i)) 0)
325 (aset tree i (copy-tree (aref tree i) vecp)))
326 tree)
327 tree)))
329 ;;;; Various list-search functions.
331 (defun assoc-default (key alist &optional test default)
332 "Find object KEY in a pseudo-alist ALIST.
333 ALIST is a list of conses or objects. Each element (or the element's car,
334 if it is a cons) is compared with KEY by evaluating (TEST (car elt) KEY).
335 If that is non-nil, the element matches;
336 then `assoc-default' returns the element's cdr, if it is a cons,
337 or DEFAULT if the element is not a cons.
339 If no element matches, the value is nil.
340 If TEST is omitted or nil, `equal' is used."
341 (let (found (tail alist) value)
342 (while (and tail (not found))
343 (let ((elt (car tail)))
344 (when (funcall (or test 'equal) (if (consp elt) (car elt) elt) key)
345 (setq found t value (if (consp elt) (cdr elt) default))))
346 (setq tail (cdr tail)))
347 value))
349 (make-obsolete 'assoc-ignore-case 'assoc-string)
350 (defun assoc-ignore-case (key alist)
351 "Like `assoc', but ignores differences in case and text representation.
352 KEY must be a string. Upper-case and lower-case letters are treated as equal.
353 Unibyte strings are converted to multibyte for comparison."
354 (assoc-string key alist t))
356 (make-obsolete 'assoc-ignore-representation 'assoc-string)
357 (defun assoc-ignore-representation (key alist)
358 "Like `assoc', but ignores differences in text representation.
359 KEY must be a string.
360 Unibyte strings are converted to multibyte for comparison."
361 (assoc-string key alist nil))
363 (defun member-ignore-case (elt list)
364 "Like `member', but ignores differences in case and text representation.
365 ELT must be a string. Upper-case and lower-case letters are treated as equal.
366 Unibyte strings are converted to multibyte for comparison.
367 Non-strings in LIST are ignored."
368 (while (and list
369 (not (and (stringp (car list))
370 (eq t (compare-strings elt 0 nil (car list) 0 nil t)))))
371 (setq list (cdr list)))
372 list)
374 (defun assq-delete-all (key alist)
375 "Delete from ALIST all elements whose car is `eq' to KEY.
376 Return the modified alist.
377 Elements of ALIST that are not conses are ignored."
378 (while (and (consp (car alist))
379 (eq (car (car alist)) key))
380 (setq alist (cdr alist)))
381 (let ((tail alist) tail-cdr)
382 (while (setq tail-cdr (cdr tail))
383 (if (and (consp (car tail-cdr))
384 (eq (car (car tail-cdr)) key))
385 (setcdr tail (cdr tail-cdr))
386 (setq tail tail-cdr))))
387 alist)
389 (defun rassq-delete-all (value alist)
390 "Delete from ALIST all elements whose cdr is `eq' to VALUE.
391 Return the modified alist.
392 Elements of ALIST that are not conses are ignored."
393 (while (and (consp (car alist))
394 (eq (cdr (car alist)) value))
395 (setq alist (cdr alist)))
396 (let ((tail alist) tail-cdr)
397 (while (setq tail-cdr (cdr tail))
398 (if (and (consp (car tail-cdr))
399 (eq (cdr (car tail-cdr)) value))
400 (setcdr tail (cdr tail-cdr))
401 (setq tail tail-cdr))))
402 alist)
404 (defun remove (elt seq)
405 "Return a copy of SEQ with all occurrences of ELT removed.
406 SEQ must be a list, vector, or string. The comparison is done with `equal'."
407 (if (nlistp seq)
408 ;; If SEQ isn't a list, there's no need to copy SEQ because
409 ;; `delete' will return a new object.
410 (delete elt seq)
411 (delete elt (copy-sequence seq))))
413 (defun remq (elt list)
414 "Return LIST with all occurrences of ELT removed.
415 The comparison is done with `eq'. Contrary to `delq', this does not use
416 side-effects, and the argument LIST is not modified."
417 (if (memq elt list)
418 (delq elt (copy-sequence list))
419 list))
421 ;;;; Keymap support.
423 (defmacro kbd (keys)
424 "Convert KEYS to the internal Emacs key representation.
425 KEYS should be a string constant in the format used for
426 saving keyboard macros (see `edmacro-mode')."
427 (read-kbd-macro keys))
429 (defun undefined ()
430 (interactive)
431 (ding))
433 ;; Prevent the \{...} documentation construct
434 ;; from mentioning keys that run this command.
435 (put 'undefined 'suppress-keymap t)
437 (defun suppress-keymap (map &optional nodigits)
438 "Make MAP override all normally self-inserting keys to be undefined.
439 Normally, as an exception, digits and minus-sign are set to make prefix args,
440 but optional second arg NODIGITS non-nil treats them like other chars."
441 (define-key map [remap self-insert-command] 'undefined)
442 (or nodigits
443 (let (loop)
444 (define-key map "-" 'negative-argument)
445 ;; Make plain numbers do numeric args.
446 (setq loop ?0)
447 (while (<= loop ?9)
448 (define-key map (char-to-string loop) 'digit-argument)
449 (setq loop (1+ loop))))))
451 (defun define-key-after (keymap key definition &optional after)
452 "Add binding in KEYMAP for KEY => DEFINITION, right after AFTER's binding.
453 This is like `define-key' except that the binding for KEY is placed
454 just after the binding for the event AFTER, instead of at the beginning
455 of the map. Note that AFTER must be an event type (like KEY), NOT a command
456 \(like DEFINITION).
458 If AFTER is t or omitted, the new binding goes at the end of the keymap.
459 AFTER should be a single event type--a symbol or a character, not a sequence.
461 Bindings are always added before any inherited map.
463 The order of bindings in a keymap matters when it is used as a menu."
464 (unless after (setq after t))
465 (or (keymapp keymap)
466 (signal 'wrong-type-argument (list 'keymapp keymap)))
467 (setq key
468 (if (<= (length key) 1) (aref key 0)
469 (setq keymap (lookup-key keymap
470 (apply 'vector
471 (butlast (mapcar 'identity key)))))
472 (aref key (1- (length key)))))
473 (let ((tail keymap) done inserted)
474 (while (and (not done) tail)
475 ;; Delete any earlier bindings for the same key.
476 (if (eq (car-safe (car (cdr tail))) key)
477 (setcdr tail (cdr (cdr tail))))
478 ;; If we hit an included map, go down that one.
479 (if (keymapp (car tail)) (setq tail (car tail)))
480 ;; When we reach AFTER's binding, insert the new binding after.
481 ;; If we reach an inherited keymap, insert just before that.
482 ;; If we reach the end of this keymap, insert at the end.
483 (if (or (and (eq (car-safe (car tail)) after)
484 (not (eq after t)))
485 (eq (car (cdr tail)) 'keymap)
486 (null (cdr tail)))
487 (progn
488 ;; Stop the scan only if we find a parent keymap.
489 ;; Keep going past the inserted element
490 ;; so we can delete any duplications that come later.
491 (if (eq (car (cdr tail)) 'keymap)
492 (setq done t))
493 ;; Don't insert more than once.
494 (or inserted
495 (setcdr tail (cons (cons key definition) (cdr tail))))
496 (setq inserted t)))
497 (setq tail (cdr tail)))))
499 (defun map-keymap-internal (function keymap &optional sort-first)
500 "Implement `map-keymap' with sorting.
501 Don't call this function; it is for internal use only."
502 (if sort-first
503 (let (list)
504 (map-keymap (lambda (a b) (push (cons a b) list))
505 keymap)
506 (setq list (sort list
507 (lambda (a b)
508 (setq a (car a) b (car b))
509 (if (integerp a)
510 (if (integerp b) (< a b)
512 (if (integerp b) t
513 (string< a b))))))
514 (dolist (p list)
515 (funcall function (car p) (cdr p))))
516 (map-keymap function keymap)))
518 (put 'keyboard-translate-table 'char-table-extra-slots 0)
520 (defun keyboard-translate (from to)
521 "Translate character FROM to TO at a low level.
522 This function creates a `keyboard-translate-table' if necessary
523 and then modifies one entry in it."
524 (or (char-table-p keyboard-translate-table)
525 (setq keyboard-translate-table
526 (make-char-table 'keyboard-translate-table nil)))
527 (aset keyboard-translate-table from to))
529 ;;;; Key binding commands.
531 (defun global-set-key (key command)
532 "Give KEY a global binding as COMMAND.
533 COMMAND is the command definition to use; usually it is
534 a symbol naming an interactively-callable function.
535 KEY is a key sequence; noninteractively, it is a string or vector
536 of characters or event types, and non-ASCII characters with codes
537 above 127 (such as ISO Latin-1) can be included if you use a vector.
539 Note that if KEY has a local binding in the current buffer,
540 that local binding will continue to shadow any global binding
541 that you make with this function."
542 (interactive "KSet key globally: \nCSet key %s to command: ")
543 (or (vectorp key) (stringp key)
544 (signal 'wrong-type-argument (list 'arrayp key)))
545 (define-key (current-global-map) key command))
547 (defun local-set-key (key command)
548 "Give KEY a local binding as COMMAND.
549 COMMAND is the command definition to use; usually it is
550 a symbol naming an interactively-callable function.
551 KEY is a key sequence; noninteractively, it is a string or vector
552 of characters or event types, and non-ASCII characters with codes
553 above 127 (such as ISO Latin-1) can be included if you use a vector.
555 The binding goes in the current buffer's local map,
556 which in most cases is shared with all other buffers in the same major mode."
557 (interactive "KSet key locally: \nCSet key %s locally to command: ")
558 (let ((map (current-local-map)))
559 (or map
560 (use-local-map (setq map (make-sparse-keymap))))
561 (or (vectorp key) (stringp key)
562 (signal 'wrong-type-argument (list 'arrayp key)))
563 (define-key map key command)))
565 (defun global-unset-key (key)
566 "Remove global binding of KEY.
567 KEY is a string or vector representing a sequence of keystrokes."
568 (interactive "kUnset key globally: ")
569 (global-set-key key nil))
571 (defun local-unset-key (key)
572 "Remove local binding of KEY.
573 KEY is a string or vector representing a sequence of keystrokes."
574 (interactive "kUnset key locally: ")
575 (if (current-local-map)
576 (local-set-key key nil))
577 nil)
579 ;;;; substitute-key-definition and its subroutines.
581 (defvar key-substitution-in-progress nil
582 "Used internally by `substitute-key-definition'.")
584 (defun substitute-key-definition (olddef newdef keymap &optional oldmap prefix)
585 "Replace OLDDEF with NEWDEF for any keys in KEYMAP now defined as OLDDEF.
586 In other words, OLDDEF is replaced with NEWDEF where ever it appears.
587 Alternatively, if optional fourth argument OLDMAP is specified, we redefine
588 in KEYMAP as NEWDEF those keys which are defined as OLDDEF in OLDMAP.
590 If you don't specify OLDMAP, you can usually get the same results
591 in a cleaner way with command remapping, like this:
592 \(define-key KEYMAP [remap OLDDEF] NEWDEF)
593 \n(fn OLDDEF NEWDEF KEYMAP &optional OLDMAP)"
594 ;; Don't document PREFIX in the doc string because we don't want to
595 ;; advertise it. It's meant for recursive calls only. Here's its
596 ;; meaning
598 ;; If optional argument PREFIX is specified, it should be a key
599 ;; prefix, a string. Redefined bindings will then be bound to the
600 ;; original key, with PREFIX added at the front.
601 (or prefix (setq prefix ""))
602 (let* ((scan (or oldmap keymap))
603 (prefix1 (vconcat prefix [nil]))
604 (key-substitution-in-progress
605 (cons scan key-substitution-in-progress)))
606 ;; Scan OLDMAP, finding each char or event-symbol that
607 ;; has any definition, and act on it with hack-key.
608 (map-keymap
609 (lambda (char defn)
610 (aset prefix1 (length prefix) char)
611 (substitute-key-definition-key defn olddef newdef prefix1 keymap))
612 scan)))
614 (defun substitute-key-definition-key (defn olddef newdef prefix keymap)
615 (let (inner-def skipped menu-item)
616 ;; Find the actual command name within the binding.
617 (if (eq (car-safe defn) 'menu-item)
618 (setq menu-item defn defn (nth 2 defn))
619 ;; Skip past menu-prompt.
620 (while (stringp (car-safe defn))
621 (push (pop defn) skipped))
622 ;; Skip past cached key-equivalence data for menu items.
623 (if (consp (car-safe defn))
624 (setq defn (cdr defn))))
625 (if (or (eq defn olddef)
626 ;; Compare with equal if definition is a key sequence.
627 ;; That is useful for operating on function-key-map.
628 (and (or (stringp defn) (vectorp defn))
629 (equal defn olddef)))
630 (define-key keymap prefix
631 (if menu-item
632 (let ((copy (copy-sequence menu-item)))
633 (setcar (nthcdr 2 copy) newdef)
634 copy)
635 (nconc (nreverse skipped) newdef)))
636 ;; Look past a symbol that names a keymap.
637 (setq inner-def
638 (or (indirect-function defn t) defn))
639 ;; For nested keymaps, we use `inner-def' rather than `defn' so as to
640 ;; avoid autoloading a keymap. This is mostly done to preserve the
641 ;; original non-autoloading behavior of pre-map-keymap times.
642 (if (and (keymapp inner-def)
643 ;; Avoid recursively scanning
644 ;; where KEYMAP does not have a submap.
645 (let ((elt (lookup-key keymap prefix)))
646 (or (null elt) (natnump elt) (keymapp elt)))
647 ;; Avoid recursively rescanning keymap being scanned.
648 (not (memq inner-def key-substitution-in-progress)))
649 ;; If this one isn't being scanned already, scan it now.
650 (substitute-key-definition olddef newdef keymap inner-def prefix)))))
653 ;;;; The global keymap tree.
655 ;;; global-map, esc-map, and ctl-x-map have their values set up in
656 ;;; keymap.c; we just give them docstrings here.
658 (defvar global-map nil
659 "Default global keymap mapping Emacs keyboard input into commands.
660 The value is a keymap which is usually (but not necessarily) Emacs's
661 global map.")
663 (defvar esc-map nil
664 "Default keymap for ESC (meta) commands.
665 The normal global definition of the character ESC indirects to this keymap.")
667 (defvar ctl-x-map nil
668 "Default keymap for C-x commands.
669 The normal global definition of the character C-x indirects to this keymap.")
671 (defvar ctl-x-4-map (make-sparse-keymap)
672 "Keymap for subcommands of C-x 4.")
673 (defalias 'ctl-x-4-prefix ctl-x-4-map)
674 (define-key ctl-x-map "4" 'ctl-x-4-prefix)
676 (defvar ctl-x-5-map (make-sparse-keymap)
677 "Keymap for frame commands.")
678 (defalias 'ctl-x-5-prefix ctl-x-5-map)
679 (define-key ctl-x-map "5" 'ctl-x-5-prefix)
682 ;;;; Event manipulation functions.
684 ;; The call to `read' is to ensure that the value is computed at load time
685 ;; and not compiled into the .elc file. The value is negative on most
686 ;; machines, but not on all!
687 (defconst listify-key-sequence-1 (logior 128 (read "?\\M-\\^@")))
689 (defun listify-key-sequence (key)
690 "Convert a key sequence to a list of events."
691 (if (vectorp key)
692 (append key nil)
693 (mapcar (function (lambda (c)
694 (if (> c 127)
695 (logxor c listify-key-sequence-1)
696 c)))
697 key)))
699 (defsubst eventp (obj)
700 "True if the argument is an event object."
701 (or (and (integerp obj)
702 ;; Filter out integers too large to be events.
703 ;; M is the biggest modifier.
704 (zerop (logand obj (lognot (1- (lsh ?\M-\^@ 1)))))
705 (char-valid-p (event-basic-type obj)))
706 (and (symbolp obj)
707 (get obj 'event-symbol-elements))
708 (and (consp obj)
709 (symbolp (car obj))
710 (get (car obj) 'event-symbol-elements))))
712 (defun event-modifiers (event)
713 "Return a list of symbols representing the modifier keys in event EVENT.
714 The elements of the list may include `meta', `control',
715 `shift', `hyper', `super', `alt', `click', `double', `triple', `drag',
716 and `down'.
717 EVENT may be an event or an event type. If EVENT is a symbol
718 that has never been used in an event that has been read as input
719 in the current Emacs session, then this function can return nil,
720 even when EVENT actually has modifiers."
721 (let ((type event))
722 (if (listp type)
723 (setq type (car type)))
724 (if (symbolp type)
725 (cdr (get type 'event-symbol-elements))
726 (let ((list nil)
727 (char (logand type (lognot (logior ?\M-\^@ ?\C-\^@ ?\S-\^@
728 ?\H-\^@ ?\s-\^@ ?\A-\^@)))))
729 (if (not (zerop (logand type ?\M-\^@)))
730 (push 'meta list))
731 (if (or (not (zerop (logand type ?\C-\^@)))
732 (< char 32))
733 (push 'control list))
734 (if (or (not (zerop (logand type ?\S-\^@)))
735 (/= char (downcase char)))
736 (push 'shift list))
737 (or (zerop (logand type ?\H-\^@))
738 (push 'hyper list))
739 (or (zerop (logand type ?\s-\^@))
740 (push 'super list))
741 (or (zerop (logand type ?\A-\^@))
742 (push 'alt list))
743 list))))
745 (defun event-basic-type (event)
746 "Return the basic type of the given event (all modifiers removed).
747 The value is a printing character (not upper case) or a symbol.
748 EVENT may be an event or an event type. If EVENT is a symbol
749 that has never been used in an event that has been read as input
750 in the current Emacs session, then this function may return nil."
751 (if (consp event)
752 (setq event (car event)))
753 (if (symbolp event)
754 (car (get event 'event-symbol-elements))
755 (let* ((base (logand event (1- ?\A-\^@)))
756 (uncontrolled (if (< base 32) (logior base 64) base)))
757 ;; There are some numbers that are invalid characters and
758 ;; cause `downcase' to get an error.
759 (condition-case ()
760 (downcase uncontrolled)
761 (error uncontrolled)))))
763 (defsubst mouse-movement-p (object)
764 "Return non-nil if OBJECT is a mouse movement event."
765 (eq (car-safe object) 'mouse-movement))
767 (defsubst event-start (event)
768 "Return the starting position of EVENT.
769 If EVENT is a mouse or key press or a mouse click, this returns the location
770 of the event.
771 If EVENT is a drag, this returns the drag's starting position.
772 The return value is of the form
773 (WINDOW AREA-OR-POS (X . Y) TIMESTAMP OBJECT POS (COL . ROW)
774 IMAGE (DX . DY) (WIDTH . HEIGHT))
775 The `posn-' functions access elements of such lists."
776 (if (consp event) (nth 1 event)
777 (list (selected-window) (point) '(0 . 0) 0)))
779 (defsubst event-end (event)
780 "Return the ending location of EVENT.
781 EVENT should be a click, drag, or key press event.
782 If EVENT is a click event, this function is the same as `event-start'.
783 The return value is of the form
784 (WINDOW AREA-OR-POS (X . Y) TIMESTAMP OBJECT POS (COL . ROW)
785 IMAGE (DX . DY) (WIDTH . HEIGHT))
786 The `posn-' functions access elements of such lists."
787 (if (consp event) (nth (if (consp (nth 2 event)) 2 1) event)
788 (list (selected-window) (point) '(0 . 0) 0)))
790 (defsubst event-click-count (event)
791 "Return the multi-click count of EVENT, a click or drag event.
792 The return value is a positive integer."
793 (if (and (consp event) (integerp (nth 2 event))) (nth 2 event) 1))
795 ;;;; Extracting fields of the positions in an event.
797 (defsubst posn-window (position)
798 "Return the window in POSITION.
799 POSITION should be a list of the form returned by the `event-start'
800 and `event-end' functions."
801 (nth 0 position))
803 (defsubst posn-area (position)
804 "Return the window area recorded in POSITION, or nil for the text area.
805 POSITION should be a list of the form returned by the `event-start'
806 and `event-end' functions."
807 (let ((area (if (consp (nth 1 position))
808 (car (nth 1 position))
809 (nth 1 position))))
810 (and (symbolp area) area)))
812 (defsubst posn-point (position)
813 "Return the buffer location in POSITION.
814 POSITION should be a list of the form returned by the `event-start'
815 and `event-end' functions."
816 (or (nth 5 position)
817 (if (consp (nth 1 position))
818 (car (nth 1 position))
819 (nth 1 position))))
821 (defun posn-set-point (position)
822 "Move point to POSITION.
823 Select the corresponding window as well."
824 (if (not (windowp (posn-window position)))
825 (error "Position not in text area of window"))
826 (select-window (posn-window position))
827 (if (numberp (posn-point position))
828 (goto-char (posn-point position))))
830 (defsubst posn-x-y (position)
831 "Return the x and y coordinates in POSITION.
832 POSITION should be a list of the form returned by the `event-start'
833 and `event-end' functions."
834 (nth 2 position))
836 (defun posn-col-row (position)
837 "Return the nominal column and row in POSITION, measured in characters.
838 The column and row values are approximations calculated from the x
839 and y coordinates in POSITION and the frame's default character width
840 and height.
841 For a scroll-bar event, the result column is 0, and the row
842 corresponds to the vertical position of the click in the scroll bar.
843 POSITION should be a list of the form returned by the `event-start'
844 and `event-end' functions."
845 (let* ((pair (posn-x-y position))
846 (window (posn-window position))
847 (area (posn-area position)))
848 (cond
849 ((null window)
850 '(0 . 0))
851 ((eq area 'vertical-scroll-bar)
852 (cons 0 (scroll-bar-scale pair (1- (window-height window)))))
853 ((eq area 'horizontal-scroll-bar)
854 (cons (scroll-bar-scale pair (window-width window)) 0))
856 (let* ((frame (if (framep window) window (window-frame window)))
857 (x (/ (car pair) (frame-char-width frame)))
858 (y (/ (cdr pair) (+ (frame-char-height frame)
859 (or (frame-parameter frame 'line-spacing)
860 default-line-spacing
861 0)))))
862 (cons x y))))))
864 (defun posn-actual-col-row (position)
865 "Return the actual column and row in POSITION, measured in characters.
866 These are the actual row number in the window and character number in that row.
867 Return nil if POSITION does not contain the actual position; in that case
868 `posn-col-row' can be used to get approximate values.
869 POSITION should be a list of the form returned by the `event-start'
870 and `event-end' functions."
871 (nth 6 position))
873 (defsubst posn-timestamp (position)
874 "Return the timestamp of POSITION.
875 POSITION should be a list of the form returned by the `event-start'
876 and `event-end' functions."
877 (nth 3 position))
879 (defsubst posn-string (position)
880 "Return the string object of POSITION.
881 Value is a cons (STRING . STRING-POS), or nil if not a string.
882 POSITION should be a list of the form returned by the `event-start'
883 and `event-end' functions."
884 (nth 4 position))
886 (defsubst posn-image (position)
887 "Return the image object of POSITION.
888 Value is a list (image ...), or nil if not an image.
889 POSITION should be a list of the form returned by the `event-start'
890 and `event-end' functions."
891 (nth 7 position))
893 (defsubst posn-object (position)
894 "Return the object (image or string) of POSITION.
895 Value is a list (image ...) for an image object, a cons cell
896 \(STRING . STRING-POS) for a string object, and nil for a buffer position.
897 POSITION should be a list of the form returned by the `event-start'
898 and `event-end' functions."
899 (or (posn-image position) (posn-string position)))
901 (defsubst posn-object-x-y (position)
902 "Return the x and y coordinates relative to the object of POSITION.
903 POSITION should be a list of the form returned by the `event-start'
904 and `event-end' functions."
905 (nth 8 position))
907 (defsubst posn-object-width-height (position)
908 "Return the pixel width and height of the object of POSITION.
909 POSITION should be a list of the form returned by the `event-start'
910 and `event-end' functions."
911 (nth 9 position))
914 ;;;; Obsolescent names for functions.
916 (define-obsolete-function-alias 'window-dot 'window-point "22.1")
917 (define-obsolete-function-alias 'set-window-dot 'set-window-point "22.1")
918 (define-obsolete-function-alias 'read-input 'read-string "22.1")
919 (define-obsolete-function-alias 'show-buffer 'set-window-buffer "22.1")
920 (define-obsolete-function-alias 'eval-current-buffer 'eval-buffer "22.1")
921 (define-obsolete-function-alias 'string-to-int 'string-to-number "22.1")
923 (make-obsolete 'char-bytes "now always returns 1." "20.4")
925 (defun insert-string (&rest args)
926 "Mocklisp-compatibility insert function.
927 Like the function `insert' except that any argument that is a number
928 is converted into a string by expressing it in decimal."
929 (dolist (el args)
930 (insert (if (integerp el) (number-to-string el) el))))
931 (make-obsolete 'insert-string 'insert "22.1")
933 (defun makehash (&optional test) (make-hash-table :test (or test 'eql)))
934 (make-obsolete 'makehash 'make-hash-table "22.1")
936 ;; Some programs still use this as a function.
937 (defun baud-rate ()
938 "Return the value of the `baud-rate' variable."
939 baud-rate)
940 (make-obsolete 'baud-rate "use the `baud-rate' variable instead." "before 19.15")
942 ;; These are used by VM and some old programs
943 (defalias 'focus-frame 'ignore "")
944 (make-obsolete 'focus-frame "it does nothing." "22.1")
945 (defalias 'unfocus-frame 'ignore "")
946 (make-obsolete 'unfocus-frame "it does nothing." "22.1")
949 ;;;; Obsolescence declarations for variables, and aliases.
951 (make-obsolete-variable 'directory-sep-char "do not use it." "21.1")
952 (make-obsolete-variable
953 'mode-line-inverse-video
954 "use the appropriate faces instead."
955 "21.1")
956 (make-obsolete-variable
957 'unread-command-char
958 "use `unread-command-events' instead. That variable is a list of events
959 to reread, so it now uses nil to mean `no event', instead of -1."
960 "before 19.15")
962 ;; Lisp manual only updated in 22.1.
963 (define-obsolete-variable-alias 'executing-macro 'executing-kbd-macro
964 "before 19.34")
966 (defvaralias 'x-lost-selection-hooks 'x-lost-selection-functions)
967 (make-obsolete-variable 'x-lost-selection-hooks
968 'x-lost-selection-functions "22.1")
969 (defvaralias 'x-sent-selection-hooks 'x-sent-selection-functions)
970 (make-obsolete-variable 'x-sent-selection-hooks
971 'x-sent-selection-functions "22.1")
973 (defvaralias 'messages-buffer-max-lines 'message-log-max)
975 ;;;; Alternate names for functions - these are not being phased out.
977 (defalias 'send-string 'process-send-string)
978 (defalias 'send-region 'process-send-region)
979 (defalias 'string= 'string-equal)
980 (defalias 'string< 'string-lessp)
981 (defalias 'move-marker 'set-marker)
982 (defalias 'rplaca 'setcar)
983 (defalias 'rplacd 'setcdr)
984 (defalias 'beep 'ding) ;preserve lingual purity
985 (defalias 'indent-to-column 'indent-to)
986 (defalias 'backward-delete-char 'delete-backward-char)
987 (defalias 'search-forward-regexp (symbol-function 're-search-forward))
988 (defalias 'search-backward-regexp (symbol-function 're-search-backward))
989 (defalias 'int-to-string 'number-to-string)
990 (defalias 'store-match-data 'set-match-data)
991 (defalias 'make-variable-frame-localizable 'make-variable-frame-local)
992 ;; These are the XEmacs names:
993 (defalias 'point-at-eol 'line-end-position)
994 (defalias 'point-at-bol 'line-beginning-position)
996 (defalias 'user-original-login-name 'user-login-name)
999 ;;;; Hook manipulation functions.
1001 (defun make-local-hook (hook)
1002 "Make the hook HOOK local to the current buffer.
1003 The return value is HOOK.
1005 You never need to call this function now that `add-hook' does it for you
1006 if its LOCAL argument is non-nil.
1008 When a hook is local, its local and global values
1009 work in concert: running the hook actually runs all the hook
1010 functions listed in *either* the local value *or* the global value
1011 of the hook variable.
1013 This function works by making t a member of the buffer-local value,
1014 which acts as a flag to run the hook functions in the default value as
1015 well. This works for all normal hooks, but does not work for most
1016 non-normal hooks yet. We will be changing the callers of non-normal
1017 hooks so that they can handle localness; this has to be done one by
1018 one.
1020 This function does nothing if HOOK is already local in the current
1021 buffer.
1023 Do not use `make-local-variable' to make a hook variable buffer-local."
1024 (if (local-variable-p hook)
1026 (or (boundp hook) (set hook nil))
1027 (make-local-variable hook)
1028 (set hook (list t)))
1029 hook)
1030 (make-obsolete 'make-local-hook "not necessary any more." "21.1")
1032 (defun add-hook (hook function &optional append local)
1033 "Add to the value of HOOK the function FUNCTION.
1034 FUNCTION is not added if already present.
1035 FUNCTION is added (if necessary) at the beginning of the hook list
1036 unless the optional argument APPEND is non-nil, in which case
1037 FUNCTION is added at the end.
1039 The optional fourth argument, LOCAL, if non-nil, says to modify
1040 the hook's buffer-local value rather than its default value.
1041 This makes the hook buffer-local if needed, and it makes t a member
1042 of the buffer-local value. That acts as a flag to run the hook
1043 functions in the default value as well as in the local value.
1045 HOOK should be a symbol, and FUNCTION may be any valid function. If
1046 HOOK is void, it is first set to nil. If HOOK's value is a single
1047 function, it is changed to a list of functions."
1048 (or (boundp hook) (set hook nil))
1049 (or (default-boundp hook) (set-default hook nil))
1050 (if local (unless (local-variable-if-set-p hook)
1051 (set (make-local-variable hook) (list t)))
1052 ;; Detect the case where make-local-variable was used on a hook
1053 ;; and do what we used to do.
1054 (unless (and (consp (symbol-value hook)) (memq t (symbol-value hook)))
1055 (setq local t)))
1056 (let ((hook-value (if local (symbol-value hook) (default-value hook))))
1057 ;; If the hook value is a single function, turn it into a list.
1058 (when (or (not (listp hook-value)) (eq (car hook-value) 'lambda))
1059 (setq hook-value (list hook-value)))
1060 ;; Do the actual addition if necessary
1061 (unless (member function hook-value)
1062 (setq hook-value
1063 (if append
1064 (append hook-value (list function))
1065 (cons function hook-value))))
1066 ;; Set the actual variable
1067 (if local (set hook hook-value) (set-default hook hook-value))))
1069 (defun remove-hook (hook function &optional local)
1070 "Remove from the value of HOOK the function FUNCTION.
1071 HOOK should be a symbol, and FUNCTION may be any valid function. If
1072 FUNCTION isn't the value of HOOK, or, if FUNCTION doesn't appear in the
1073 list of hooks to run in HOOK, then nothing is done. See `add-hook'.
1075 The optional third argument, LOCAL, if non-nil, says to modify
1076 the hook's buffer-local value rather than its default value."
1077 (or (boundp hook) (set hook nil))
1078 (or (default-boundp hook) (set-default hook nil))
1079 ;; Do nothing if LOCAL is t but this hook has no local binding.
1080 (unless (and local (not (local-variable-p hook)))
1081 ;; Detect the case where make-local-variable was used on a hook
1082 ;; and do what we used to do.
1083 (when (and (local-variable-p hook)
1084 (not (and (consp (symbol-value hook))
1085 (memq t (symbol-value hook)))))
1086 (setq local t))
1087 (let ((hook-value (if local (symbol-value hook) (default-value hook))))
1088 ;; Remove the function, for both the list and the non-list cases.
1089 (if (or (not (listp hook-value)) (eq (car hook-value) 'lambda))
1090 (if (equal hook-value function) (setq hook-value nil))
1091 (setq hook-value (delete function (copy-sequence hook-value))))
1092 ;; If the function is on the global hook, we need to shadow it locally
1093 ;;(when (and local (member function (default-value hook))
1094 ;; (not (member (cons 'not function) hook-value)))
1095 ;; (push (cons 'not function) hook-value))
1096 ;; Set the actual variable
1097 (if (not local)
1098 (set-default hook hook-value)
1099 (if (equal hook-value '(t))
1100 (kill-local-variable hook)
1101 (set hook hook-value))))))
1103 (defun add-to-list (list-var element &optional append compare-fn)
1104 "Add ELEMENT to the value of LIST-VAR if it isn't there yet.
1105 The test for presence of ELEMENT is done with `equal',
1106 or with COMPARE-FN if that's non-nil.
1107 If ELEMENT is added, it is added at the beginning of the list,
1108 unless the optional argument APPEND is non-nil, in which case
1109 ELEMENT is added at the end.
1111 The return value is the new value of LIST-VAR.
1113 If you want to use `add-to-list' on a variable that is not defined
1114 until a certain package is loaded, you should put the call to `add-to-list'
1115 into a hook function that will be run only after loading the package.
1116 `eval-after-load' provides one way to do this. In some cases
1117 other hooks, such as major mode hooks, can do the job."
1118 (if (cond
1119 ((null compare-fn)
1120 (member element (symbol-value list-var)))
1121 ((eq compare-fn 'eq)
1122 (memq element (symbol-value list-var)))
1123 ((eq compare-fn 'eql)
1124 (memql element (symbol-value list-var)))
1126 (let ((lst (symbol-value list-var)))
1127 (while (and lst
1128 (not (funcall compare-fn element (car lst))))
1129 (setq lst (cdr lst)))
1130 lst)))
1131 (symbol-value list-var)
1132 (set list-var
1133 (if append
1134 (append (symbol-value list-var) (list element))
1135 (cons element (symbol-value list-var))))))
1138 (defun add-to-ordered-list (list-var element &optional order)
1139 "Add ELEMENT to the value of LIST-VAR if it isn't there yet.
1140 The test for presence of ELEMENT is done with `eq'.
1142 The resulting list is reordered so that the elements are in the
1143 order given by each element's numeric list order. Elements
1144 without a numeric list order are placed at the end of the list.
1146 If the third optional argument ORDER is a number (integer or
1147 float), set the element's list order to the given value. If
1148 ORDER is nil or omitted, do not change the numeric order of
1149 ELEMENT. If ORDER has any other value, remove the numeric order
1150 of ELEMENT if it has one.
1152 The list order for each element is stored in LIST-VAR's
1153 `list-order' property.
1155 The return value is the new value of LIST-VAR."
1156 (let ((ordering (get list-var 'list-order)))
1157 (unless ordering
1158 (put list-var 'list-order
1159 (setq ordering (make-hash-table :weakness 'key :test 'eq))))
1160 (when order
1161 (puthash element (and (numberp order) order) ordering))
1162 (unless (memq element (symbol-value list-var))
1163 (set list-var (cons element (symbol-value list-var))))
1164 (set list-var (sort (symbol-value list-var)
1165 (lambda (a b)
1166 (let ((oa (gethash a ordering))
1167 (ob (gethash b ordering)))
1168 (if (and oa ob)
1169 (< oa ob)
1170 oa)))))))
1172 (defun add-to-history (history-var newelt &optional maxelt keep-all)
1173 "Add NEWELT to the history list stored in the variable HISTORY-VAR.
1174 Return the new history list.
1175 If MAXELT is non-nil, it specifies the maximum length of the history.
1176 Otherwise, the maximum history length is the value of the `history-length'
1177 property on symbol HISTORY-VAR, if set, or the value of the `history-length'
1178 variable.
1179 Remove duplicates of NEWELT if `history-delete-duplicates' is non-nil.
1180 If optional fourth arg KEEP-ALL is non-nil, add NEWELT to history even
1181 if it is empty or a duplicate."
1182 (unless maxelt
1183 (setq maxelt (or (get history-var 'history-length)
1184 history-length)))
1185 (let ((history (symbol-value history-var))
1186 tail)
1187 (when (and (listp history)
1188 (or keep-all
1189 (not (stringp newelt))
1190 (> (length newelt) 0))
1191 (or keep-all
1192 (not (equal (car history) newelt))))
1193 (if history-delete-duplicates
1194 (delete newelt history))
1195 (setq history (cons newelt history))
1196 (when (integerp maxelt)
1197 (if (= 0 maxelt)
1198 (setq history nil)
1199 (setq tail (nthcdr (1- maxelt) history))
1200 (when (consp tail)
1201 (setcdr tail nil)))))
1202 (set history-var history)))
1205 ;;;; Mode hooks.
1207 (defvar delay-mode-hooks nil
1208 "If non-nil, `run-mode-hooks' should delay running the hooks.")
1209 (defvar delayed-mode-hooks nil
1210 "List of delayed mode hooks waiting to be run.")
1211 (make-variable-buffer-local 'delayed-mode-hooks)
1212 (put 'delay-mode-hooks 'permanent-local t)
1214 (defvar after-change-major-mode-hook nil
1215 "Normal hook run at the very end of major mode functions.")
1217 (defun run-mode-hooks (&rest hooks)
1218 "Run mode hooks `delayed-mode-hooks' and HOOKS, or delay HOOKS.
1219 Execution is delayed if `delay-mode-hooks' is non-nil.
1220 If `delay-mode-hooks' is nil, run `after-change-major-mode-hook'
1221 after running the mode hooks.
1222 Major mode functions should use this."
1223 (if delay-mode-hooks
1224 ;; Delaying case.
1225 (dolist (hook hooks)
1226 (push hook delayed-mode-hooks))
1227 ;; Normal case, just run the hook as before plus any delayed hooks.
1228 (setq hooks (nconc (nreverse delayed-mode-hooks) hooks))
1229 (setq delayed-mode-hooks nil)
1230 (apply 'run-hooks hooks)
1231 (run-hooks 'after-change-major-mode-hook)))
1233 (defmacro delay-mode-hooks (&rest body)
1234 "Execute BODY, but delay any `run-mode-hooks'.
1235 These hooks will be executed by the first following call to
1236 `run-mode-hooks' that occurs outside any `delayed-mode-hooks' form.
1237 Only affects hooks run in the current buffer."
1238 (declare (debug t) (indent 0))
1239 `(progn
1240 (make-local-variable 'delay-mode-hooks)
1241 (let ((delay-mode-hooks t))
1242 ,@body)))
1244 ;; PUBLIC: find if the current mode derives from another.
1246 (defun derived-mode-p (&rest modes)
1247 "Non-nil if the current major mode is derived from one of MODES.
1248 Uses the `derived-mode-parent' property of the symbol to trace backwards."
1249 (let ((parent major-mode))
1250 (while (and (not (memq parent modes))
1251 (setq parent (get parent 'derived-mode-parent))))
1252 parent))
1254 ;;;; Minor modes.
1256 ;; If a minor mode is not defined with define-minor-mode,
1257 ;; add it here explicitly.
1258 ;; isearch-mode is deliberately excluded, since you should
1259 ;; not call it yourself.
1260 (defvar minor-mode-list '(auto-save-mode auto-fill-mode abbrev-mode
1261 overwrite-mode view-mode
1262 hs-minor-mode)
1263 "List of all minor mode functions.")
1265 (defun add-minor-mode (toggle name &optional keymap after toggle-fun)
1266 "Register a new minor mode.
1268 This is an XEmacs-compatibility function. Use `define-minor-mode' instead.
1270 TOGGLE is a symbol which is the name of a buffer-local variable that
1271 is toggled on or off to say whether the minor mode is active or not.
1273 NAME specifies what will appear in the mode line when the minor mode
1274 is active. NAME should be either a string starting with a space, or a
1275 symbol whose value is such a string.
1277 Optional KEYMAP is the keymap for the minor mode that will be added
1278 to `minor-mode-map-alist'.
1280 Optional AFTER specifies that TOGGLE should be added after AFTER
1281 in `minor-mode-alist'.
1283 Optional TOGGLE-FUN is an interactive function to toggle the mode.
1284 It defaults to (and should by convention be) TOGGLE.
1286 If TOGGLE has a non-nil `:included' property, an entry for the mode is
1287 included in the mode-line minor mode menu.
1288 If TOGGLE has a `:menu-tag', that is used for the menu item's label."
1289 (unless (memq toggle minor-mode-list)
1290 (push toggle minor-mode-list))
1292 (unless toggle-fun (setq toggle-fun toggle))
1293 (unless (eq toggle-fun toggle)
1294 (put toggle :minor-mode-function toggle-fun))
1295 ;; Add the name to the minor-mode-alist.
1296 (when name
1297 (let ((existing (assq toggle minor-mode-alist)))
1298 (if existing
1299 (setcdr existing (list name))
1300 (let ((tail minor-mode-alist) found)
1301 (while (and tail (not found))
1302 (if (eq after (caar tail))
1303 (setq found tail)
1304 (setq tail (cdr tail))))
1305 (if found
1306 (let ((rest (cdr found)))
1307 (setcdr found nil)
1308 (nconc found (list (list toggle name)) rest))
1309 (setq minor-mode-alist (cons (list toggle name)
1310 minor-mode-alist)))))))
1311 ;; Add the toggle to the minor-modes menu if requested.
1312 (when (get toggle :included)
1313 (define-key mode-line-mode-menu
1314 (vector toggle)
1315 (list 'menu-item
1316 (concat
1317 (or (get toggle :menu-tag)
1318 (if (stringp name) name (symbol-name toggle)))
1319 (let ((mode-name (if (symbolp name) (symbol-value name))))
1320 (if (and (stringp mode-name) (string-match "[^ ]+" mode-name))
1321 (concat " (" (match-string 0 mode-name) ")"))))
1322 toggle-fun
1323 :button (cons :toggle toggle))))
1325 ;; Add the map to the minor-mode-map-alist.
1326 (when keymap
1327 (let ((existing (assq toggle minor-mode-map-alist)))
1328 (if existing
1329 (setcdr existing keymap)
1330 (let ((tail minor-mode-map-alist) found)
1331 (while (and tail (not found))
1332 (if (eq after (caar tail))
1333 (setq found tail)
1334 (setq tail (cdr tail))))
1335 (if found
1336 (let ((rest (cdr found)))
1337 (setcdr found nil)
1338 (nconc found (list (cons toggle keymap)) rest))
1339 (setq minor-mode-map-alist (cons (cons toggle keymap)
1340 minor-mode-map-alist))))))))
1342 ;;; Load history
1344 ;; (defvar symbol-file-load-history-loaded nil
1345 ;; "Non-nil means we have loaded the file `fns-VERSION.el' in `exec-directory'.
1346 ;; That file records the part of `load-history' for preloaded files,
1347 ;; which is cleared out before dumping to make Emacs smaller.")
1349 ;; (defun load-symbol-file-load-history ()
1350 ;; "Load the file `fns-VERSION.el' in `exec-directory' if not already done.
1351 ;; That file records the part of `load-history' for preloaded files,
1352 ;; which is cleared out before dumping to make Emacs smaller."
1353 ;; (unless symbol-file-load-history-loaded
1354 ;; (load (expand-file-name
1355 ;; ;; fns-XX.YY.ZZ.el does not work on DOS filesystem.
1356 ;; (if (eq system-type 'ms-dos)
1357 ;; "fns.el"
1358 ;; (format "fns-%s.el" emacs-version))
1359 ;; exec-directory)
1360 ;; ;; The file name fns-%s.el already has a .el extension.
1361 ;; nil nil t)
1362 ;; (setq symbol-file-load-history-loaded t)))
1364 (defun symbol-file (symbol &optional type)
1365 "Return the input source in which SYMBOL was defined.
1366 The value is an absolute file name.
1367 It can also be nil, if the definition is not associated with any file.
1369 If TYPE is nil, then any kind of definition is acceptable.
1370 If TYPE is `defun' or `defvar', that specifies function
1371 definition only or variable definition only.
1372 `defface' specifies a face definition only."
1373 (if (and (or (null type) (eq type 'defun))
1374 (symbolp symbol) (fboundp symbol)
1375 (eq 'autoload (car-safe (symbol-function symbol))))
1376 (nth 1 (symbol-function symbol))
1377 (let ((files load-history)
1378 file)
1379 (while files
1380 (if (if type
1381 (if (eq type 'defvar)
1382 ;; Variables are present just as their names.
1383 (member symbol (cdr (car files)))
1384 ;; Other types are represented as (TYPE . NAME).
1385 (member (cons type symbol) (cdr (car files))))
1386 ;; We accept all types, so look for variable def
1387 ;; and then for any other kind.
1388 (or (member symbol (cdr (car files)))
1389 (rassq symbol (cdr (car files)))))
1390 (setq file (car (car files)) files nil))
1391 (setq files (cdr files)))
1392 file)))
1394 ;;;###autoload
1395 (defun locate-library (library &optional nosuffix path interactive-call)
1396 "Show the precise file name of Emacs library LIBRARY.
1397 This command searches the directories in `load-path' like `\\[load-library]'
1398 to find the file that `\\[load-library] RET LIBRARY RET' would load.
1399 Optional second arg NOSUFFIX non-nil means don't add suffixes `load-suffixes'
1400 to the specified name LIBRARY.
1402 If the optional third arg PATH is specified, that list of directories
1403 is used instead of `load-path'.
1405 When called from a program, the file name is normaly returned as a
1406 string. When run interactively, the argument INTERACTIVE-CALL is t,
1407 and the file name is displayed in the echo area."
1408 (interactive (list (completing-read "Locate library: "
1409 'locate-file-completion
1410 (cons load-path (get-load-suffixes)))
1411 nil nil
1413 (let ((file (locate-file library
1414 (or path load-path)
1415 (append (unless nosuffix (get-load-suffixes))
1416 load-file-rep-suffixes))))
1417 (if interactive-call
1418 (if file
1419 (message "Library is file %s" (abbreviate-file-name file))
1420 (message "No library %s in search path" library)))
1421 file))
1424 ;;;; Specifying things to do later.
1426 (defmacro eval-at-startup (&rest body)
1427 "Make arrangements to evaluate BODY when Emacs starts up.
1428 If this is run after Emacs startup, evaluate BODY immediately.
1429 Always returns nil.
1431 This works by adding a function to `before-init-hook'.
1432 That function's doc string says which file created it."
1433 `(progn
1434 (if command-line-processed
1435 (progn . ,body)
1436 (add-hook 'before-init-hook
1437 '(lambda () ,(concat "From " (or load-file-name "no file"))
1438 . ,body)
1440 nil))
1442 (defun load-history-regexp (file)
1443 "Form a regexp to find FILE in `load-history'.
1444 FILE, a string, is described in the function `eval-after-load'."
1445 (if (file-name-absolute-p file)
1446 (setq file (file-truename file)))
1447 (concat (if (file-name-absolute-p file) "\\`" "\\(\\`\\|/\\)")
1448 (regexp-quote file)
1449 (if (file-name-extension file)
1451 ;; Note: regexp-opt can't be used here, since we need to call
1452 ;; this before Emacs has been fully started. 2006-05-21
1453 (concat "\\(" (mapconcat 'regexp-quote load-suffixes "\\|") "\\)?"))
1454 "\\(" (mapconcat 'regexp-quote jka-compr-load-suffixes "\\|")
1455 "\\)?\\'"))
1457 (defun load-history-filename-element (file-regexp)
1458 "Get the first elt of `load-history' whose car matches FILE-REGEXP.
1459 Return nil if there isn't one."
1460 (let* ((loads load-history)
1461 (load-elt (and loads (car loads))))
1462 (save-match-data
1463 (while (and loads
1464 (or (null (car load-elt))
1465 (not (string-match file-regexp (car load-elt)))))
1466 (setq loads (cdr loads)
1467 load-elt (and loads (car loads)))))
1468 load-elt))
1470 (defun eval-after-load (file form)
1471 "Arrange that, if FILE is ever loaded, FORM will be run at that time.
1472 If FILE is already loaded, evaluate FORM right now.
1474 If a matching file is loaded again, FORM will be evaluated again.
1476 If FILE is a string, it may be either an absolute or a relative file
1477 name, and may have an extension \(e.g. \".el\") or may lack one, and
1478 additionally may or may not have an extension denoting a compressed
1479 format \(e.g. \".gz\").
1481 When FILE is absolute, this first converts it to a true name by chasing
1482 symbolic links. Only a file of this name \(see next paragraph regarding
1483 extensions) will trigger the evaluation of FORM. When FILE is relative,
1484 a file whose absolute true name ends in FILE will trigger evaluation.
1486 When FILE lacks an extension, a file name with any extension will trigger
1487 evaluation. Otherwise, its extension must match FILE's. A further
1488 extension for a compressed format \(e.g. \".gz\") on FILE will not affect
1489 this name matching.
1491 Alternatively, FILE can be a feature (i.e. a symbol), in which case FORM
1492 is evaluated whenever that feature is `provide'd.
1494 Usually FILE is just a library name like \"font-lock\" or a feature name
1495 like 'font-lock.
1497 This function makes or adds to an entry on `after-load-alist'."
1498 ;; Add this FORM into after-load-alist (regardless of whether we'll be
1499 ;; evaluating it now).
1500 (let* ((regexp-or-feature
1501 (if (stringp file) (load-history-regexp file) file))
1502 (elt (assoc regexp-or-feature after-load-alist)))
1503 (unless elt
1504 (setq elt (list regexp-or-feature))
1505 (push elt after-load-alist))
1506 ;; Add FORM to the element unless it's already there.
1507 (unless (member form (cdr elt))
1508 (nconc elt (list form)))
1510 ;; Is there an already loaded file whose name (or `provide' name)
1511 ;; matches FILE?
1512 (if (if (stringp file)
1513 (load-history-filename-element regexp-or-feature)
1514 (featurep file))
1515 (eval form))))
1517 (defun do-after-load-evaluation (abs-file)
1518 "Evaluate all `eval-after-load' forms, if any, for ABS-FILE.
1519 ABS-FILE, a string, should be the absolute true name of a file just loaded."
1520 (let ((after-load-elts after-load-alist)
1521 a-l-element file-elements file-element form)
1522 (while after-load-elts
1523 (setq a-l-element (car after-load-elts)
1524 after-load-elts (cdr after-load-elts))
1525 (when (and (stringp (car a-l-element))
1526 (string-match (car a-l-element) abs-file))
1527 (while (setq a-l-element (cdr a-l-element)) ; discard the file name
1528 (setq form (car a-l-element))
1529 (eval form))))))
1531 (defun eval-next-after-load (file)
1532 "Read the following input sexp, and run it whenever FILE is loaded.
1533 This makes or adds to an entry on `after-load-alist'.
1534 FILE should be the name of a library, with no directory name."
1535 (eval-after-load file (read)))
1537 ;;;; Process stuff.
1539 ;; open-network-stream is a wrapper around make-network-process.
1541 (when (featurep 'make-network-process)
1542 (defun open-network-stream (name buffer host service)
1543 "Open a TCP connection for a service to a host.
1544 Returns a subprocess-object to represent the connection.
1545 Input and output work as for subprocesses; `delete-process' closes it.
1547 Args are NAME BUFFER HOST SERVICE.
1548 NAME is name for process. It is modified if necessary to make it unique.
1549 BUFFER is the buffer (or buffer name) to associate with the process.
1550 Process output goes at end of that buffer, unless you specify
1551 an output stream or filter function to handle the output.
1552 BUFFER may be also nil, meaning that this process is not associated
1553 with any buffer.
1554 HOST is name of the host to connect to, or its IP address.
1555 SERVICE is name of the service desired, or an integer specifying
1556 a port number to connect to."
1557 (make-network-process :name name :buffer buffer
1558 :host host :service service)))
1560 ;; compatibility
1562 (make-obsolete
1563 'process-kill-without-query
1564 "use `process-query-on-exit-flag' or `set-process-query-on-exit-flag'."
1565 "22.1")
1566 (defun process-kill-without-query (process &optional flag)
1567 "Say no query needed if PROCESS is running when Emacs is exited.
1568 Optional second argument if non-nil says to require a query.
1569 Value is t if a query was formerly required."
1570 (let ((old (process-query-on-exit-flag process)))
1571 (set-process-query-on-exit-flag process nil)
1572 old))
1574 ;; process plist management
1576 (defun process-get (process propname)
1577 "Return the value of PROCESS' PROPNAME property.
1578 This is the last value stored with `(process-put PROCESS PROPNAME VALUE)'."
1579 (plist-get (process-plist process) propname))
1581 (defun process-put (process propname value)
1582 "Change PROCESS' PROPNAME property to VALUE.
1583 It can be retrieved with `(process-get PROCESS PROPNAME)'."
1584 (set-process-plist process
1585 (plist-put (process-plist process) propname value)))
1588 ;;;; Input and display facilities.
1590 (defvar read-quoted-char-radix 8
1591 "*Radix for \\[quoted-insert] and other uses of `read-quoted-char'.
1592 Legitimate radix values are 8, 10 and 16.")
1594 (custom-declare-variable-early
1595 'read-quoted-char-radix 8
1596 "*Radix for \\[quoted-insert] and other uses of `read-quoted-char'.
1597 Legitimate radix values are 8, 10 and 16."
1598 :type '(choice (const 8) (const 10) (const 16))
1599 :group 'editing-basics)
1601 (defun read-quoted-char (&optional prompt)
1602 "Like `read-char', but do not allow quitting.
1603 Also, if the first character read is an octal digit,
1604 we read any number of octal digits and return the
1605 specified character code. Any nondigit terminates the sequence.
1606 If the terminator is RET, it is discarded;
1607 any other terminator is used itself as input.
1609 The optional argument PROMPT specifies a string to use to prompt the user.
1610 The variable `read-quoted-char-radix' controls which radix to use
1611 for numeric input."
1612 (let ((message-log-max nil) done (first t) (code 0) char translated)
1613 (while (not done)
1614 (let ((inhibit-quit first)
1615 ;; Don't let C-h get the help message--only help function keys.
1616 (help-char nil)
1617 (help-form
1618 "Type the special character you want to use,
1619 or the octal character code.
1620 RET terminates the character code and is discarded;
1621 any other non-digit terminates the character code and is then used as input."))
1622 (setq char (read-event (and prompt (format "%s-" prompt)) t))
1623 (if inhibit-quit (setq quit-flag nil)))
1624 ;; Translate TAB key into control-I ASCII character, and so on.
1625 ;; Note: `read-char' does it using the `ascii-character' property.
1626 ;; We could try and use read-key-sequence instead, but then C-q ESC
1627 ;; or C-q C-x might not return immediately since ESC or C-x might be
1628 ;; bound to some prefix in function-key-map or key-translation-map.
1629 (setq translated char)
1630 (let ((translation (lookup-key function-key-map (vector char))))
1631 (if (arrayp translation)
1632 (setq translated (aref translation 0))))
1633 (cond ((null translated))
1634 ((not (integerp translated))
1635 (setq unread-command-events (list char)
1636 done t))
1637 ((/= (logand translated ?\M-\^@) 0)
1638 ;; Turn a meta-character into a character with the 0200 bit set.
1639 (setq code (logior (logand translated (lognot ?\M-\^@)) 128)
1640 done t))
1641 ((and (<= ?0 translated) (< translated (+ ?0 (min 10 read-quoted-char-radix))))
1642 (setq code (+ (* code read-quoted-char-radix) (- translated ?0)))
1643 (and prompt (setq prompt (message "%s %c" prompt translated))))
1644 ((and (<= ?a (downcase translated))
1645 (< (downcase translated) (+ ?a -10 (min 36 read-quoted-char-radix))))
1646 (setq code (+ (* code read-quoted-char-radix)
1647 (+ 10 (- (downcase translated) ?a))))
1648 (and prompt (setq prompt (message "%s %c" prompt translated))))
1649 ((and (not first) (eq translated ?\C-m))
1650 (setq done t))
1651 ((not first)
1652 (setq unread-command-events (list char)
1653 done t))
1654 (t (setq code translated
1655 done t)))
1656 (setq first nil))
1657 code))
1659 (defun read-passwd (prompt &optional confirm default)
1660 "Read a password, prompting with PROMPT, and return it.
1661 If optional CONFIRM is non-nil, read the password twice to make sure.
1662 Optional DEFAULT is a default password to use instead of empty input.
1664 This function echoes `.' for each character that the user types.
1665 The user ends with RET, LFD, or ESC. DEL or C-h rubs out. C-u kills line.
1666 C-g quits; if `inhibit-quit' was non-nil around this function,
1667 then it returns nil if the user types C-g, but quit-flag remains set.
1669 Once the caller uses the password, it can erase the password
1670 by doing (clear-string STRING)."
1671 (with-local-quit
1672 (if confirm
1673 (let (success)
1674 (while (not success)
1675 (let ((first (read-passwd prompt nil default))
1676 (second (read-passwd "Confirm password: " nil default)))
1677 (if (equal first second)
1678 (progn
1679 (and (arrayp second) (clear-string second))
1680 (setq success first))
1681 (and (arrayp first) (clear-string first))
1682 (and (arrayp second) (clear-string second))
1683 (message "Password not repeated accurately; please start over")
1684 (sit-for 1))))
1685 success)
1686 (let ((pass nil)
1687 ;; Copy it so that add-text-properties won't modify
1688 ;; the object that was passed in by the caller.
1689 (prompt (copy-sequence prompt))
1690 (c 0)
1691 (echo-keystrokes 0)
1692 (cursor-in-echo-area t)
1693 (message-log-max nil))
1694 (add-text-properties 0 (length prompt)
1695 minibuffer-prompt-properties prompt)
1696 (while (progn (message "%s%s"
1697 prompt
1698 (make-string (length pass) ?.))
1699 (setq c (read-char-exclusive nil t))
1700 (and (/= c ?\r) (/= c ?\n) (/= c ?\e)))
1701 (clear-this-command-keys)
1702 (if (= c ?\C-u)
1703 (progn
1704 (and (arrayp pass) (clear-string pass))
1705 (setq pass ""))
1706 (if (and (/= c ?\b) (/= c ?\177))
1707 (let* ((new-char (char-to-string c))
1708 (new-pass (concat pass new-char)))
1709 (and (arrayp pass) (clear-string pass))
1710 (clear-string new-char)
1711 (setq c ?\0)
1712 (setq pass new-pass))
1713 (if (> (length pass) 0)
1714 (let ((new-pass (substring pass 0 -1)))
1715 (and (arrayp pass) (clear-string pass))
1716 (setq pass new-pass))))))
1717 (message nil)
1718 (or pass default "")))))
1720 ;; This should be used by `call-interactively' for `n' specs.
1721 (defun read-number (prompt &optional default)
1722 (let ((n nil))
1723 (when default
1724 (setq prompt
1725 (if (string-match "\\(\\):[ \t]*\\'" prompt)
1726 (replace-match (format " (default %s)" default) t t prompt 1)
1727 (replace-regexp-in-string "[ \t]*\\'"
1728 (format " (default %s) " default)
1729 prompt t t))))
1730 (while
1731 (progn
1732 (let ((str (read-from-minibuffer prompt nil nil nil nil
1733 (and default
1734 (number-to-string default)))))
1735 (setq n (cond
1736 ((zerop (length str)) default)
1737 ((stringp str) (read str)))))
1738 (unless (numberp n)
1739 (message "Please enter a number.")
1740 (sit-for 1)
1741 t)))
1744 (defun sit-for (seconds &optional nodisp obsolete)
1745 "Perform redisplay, then wait for SECONDS seconds or until input is available.
1746 SECONDS may be a floating-point value.
1747 \(On operating systems that do not support waiting for fractions of a
1748 second, floating-point values are rounded down to the nearest integer.)
1750 If optional arg NODISP is t, don't redisplay, just wait for input.
1751 Redisplay does not happen if input is available before it starts.
1753 Value is t if waited the full time with no input arriving, and nil otherwise.
1755 An obsolete, but still supported form is
1756 \(sit-for SECONDS &optional MILLISECONDS NODISP)
1757 where the optional arg MILLISECONDS specifies an additional wait period,
1758 in milliseconds; this was useful when Emacs was built without
1759 floating point support.
1761 \(fn SECONDS &optional NODISP)"
1762 (when (or obsolete (numberp nodisp))
1763 (setq seconds (+ seconds (* 1e-3 nodisp)))
1764 (setq nodisp obsolete))
1765 (cond
1766 (noninteractive
1767 (sleep-for seconds)
1769 ((input-pending-p)
1770 nil)
1771 ((<= seconds 0)
1772 (or nodisp (redisplay)))
1774 (or nodisp (redisplay))
1775 (let ((read (read-event nil nil seconds)))
1776 (or (null read)
1777 (progn
1778 ;; If last command was a prefix arg, e.g. C-u, push this event onto
1779 ;; unread-command-events as (t . EVENT) so it will be added to
1780 ;; this-command-keys by read-key-sequence.
1781 (if (eq overriding-terminal-local-map universal-argument-map)
1782 (setq read (cons t read)))
1783 (push read unread-command-events)
1784 nil))))))
1786 ;;; Atomic change groups.
1788 (defmacro atomic-change-group (&rest body)
1789 "Perform BODY as an atomic change group.
1790 This means that if BODY exits abnormally,
1791 all of its changes to the current buffer are undone.
1792 This works regardless of whether undo is enabled in the buffer.
1794 This mechanism is transparent to ordinary use of undo;
1795 if undo is enabled in the buffer and BODY succeeds, the
1796 user can undo the change normally."
1797 (declare (indent 0) (debug t))
1798 (let ((handle (make-symbol "--change-group-handle--"))
1799 (success (make-symbol "--change-group-success--")))
1800 `(let ((,handle (prepare-change-group))
1801 (,success nil))
1802 (unwind-protect
1803 (progn
1804 ;; This is inside the unwind-protect because
1805 ;; it enables undo if that was disabled; we need
1806 ;; to make sure that it gets disabled again.
1807 (activate-change-group ,handle)
1808 ,@body
1809 (setq ,success t))
1810 ;; Either of these functions will disable undo
1811 ;; if it was disabled before.
1812 (if ,success
1813 (accept-change-group ,handle)
1814 (cancel-change-group ,handle))))))
1816 (defun prepare-change-group (&optional buffer)
1817 "Return a handle for the current buffer's state, for a change group.
1818 If you specify BUFFER, make a handle for BUFFER's state instead.
1820 Pass the handle to `activate-change-group' afterward to initiate
1821 the actual changes of the change group.
1823 To finish the change group, call either `accept-change-group' or
1824 `cancel-change-group' passing the same handle as argument. Call
1825 `accept-change-group' to accept the changes in the group as final;
1826 call `cancel-change-group' to undo them all. You should use
1827 `unwind-protect' to make sure the group is always finished. The call
1828 to `activate-change-group' should be inside the `unwind-protect'.
1829 Once you finish the group, don't use the handle again--don't try to
1830 finish the same group twice. For a simple example of correct use, see
1831 the source code of `atomic-change-group'.
1833 The handle records only the specified buffer. To make a multibuffer
1834 change group, call this function once for each buffer you want to
1835 cover, then use `nconc' to combine the returned values, like this:
1837 (nconc (prepare-change-group buffer-1)
1838 (prepare-change-group buffer-2))
1840 You can then activate that multibuffer change group with a single
1841 call to `activate-change-group' and finish it with a single call
1842 to `accept-change-group' or `cancel-change-group'."
1844 (if buffer
1845 (list (cons buffer (with-current-buffer buffer buffer-undo-list)))
1846 (list (cons (current-buffer) buffer-undo-list))))
1848 (defun activate-change-group (handle)
1849 "Activate a change group made with `prepare-change-group' (which see)."
1850 (dolist (elt handle)
1851 (with-current-buffer (car elt)
1852 (if (eq buffer-undo-list t)
1853 (setq buffer-undo-list nil)))))
1855 (defun accept-change-group (handle)
1856 "Finish a change group made with `prepare-change-group' (which see).
1857 This finishes the change group by accepting its changes as final."
1858 (dolist (elt handle)
1859 (with-current-buffer (car elt)
1860 (if (eq elt t)
1861 (setq buffer-undo-list t)))))
1863 (defun cancel-change-group (handle)
1864 "Finish a change group made with `prepare-change-group' (which see).
1865 This finishes the change group by reverting all of its changes."
1866 (dolist (elt handle)
1867 (with-current-buffer (car elt)
1868 (setq elt (cdr elt))
1869 (let ((old-car
1870 (if (consp elt) (car elt)))
1871 (old-cdr
1872 (if (consp elt) (cdr elt))))
1873 ;; Temporarily truncate the undo log at ELT.
1874 (when (consp elt)
1875 (setcar elt nil) (setcdr elt nil))
1876 (unless (eq last-command 'undo) (undo-start))
1877 ;; Make sure there's no confusion.
1878 (when (and (consp elt) (not (eq elt (last pending-undo-list))))
1879 (error "Undoing to some unrelated state"))
1880 ;; Undo it all.
1881 (while (listp pending-undo-list) (undo-more 1))
1882 ;; Reset the modified cons cell ELT to its original content.
1883 (when (consp elt)
1884 (setcar elt old-car)
1885 (setcdr elt old-cdr))
1886 ;; Revert the undo info to what it was when we grabbed the state.
1887 (setq buffer-undo-list elt)))))
1889 ;;;; Display-related functions.
1891 ;; For compatibility.
1892 (defalias 'redraw-modeline 'force-mode-line-update)
1894 (defun force-mode-line-update (&optional all)
1895 "Force redisplay of the current buffer's mode line and header line.
1896 With optional non-nil ALL, force redisplay of all mode lines and
1897 header lines. This function also forces recomputation of the
1898 menu bar menus and the frame title."
1899 (if all (save-excursion (set-buffer (other-buffer))))
1900 (set-buffer-modified-p (buffer-modified-p)))
1902 (defun momentary-string-display (string pos &optional exit-char message)
1903 "Momentarily display STRING in the buffer at POS.
1904 Display remains until next event is input.
1905 If POS is a marker, only its position is used; its buffer is ignored.
1906 Optional third arg EXIT-CHAR can be a character, event or event
1907 description list. EXIT-CHAR defaults to SPC. If the input is
1908 EXIT-CHAR it is swallowed; otherwise it is then available as
1909 input (as a command if nothing else).
1910 Display MESSAGE (optional fourth arg) in the echo area.
1911 If MESSAGE is nil, instructions to type EXIT-CHAR are displayed there."
1912 (or exit-char (setq exit-char ?\s))
1913 (let ((inhibit-read-only t)
1914 ;; Don't modify the undo list at all.
1915 (buffer-undo-list t)
1916 (modified (buffer-modified-p))
1917 (name buffer-file-name)
1918 insert-end)
1919 (unwind-protect
1920 (progn
1921 (save-excursion
1922 (goto-char pos)
1923 ;; To avoid trouble with out-of-bounds position
1924 (setq pos (point))
1925 ;; defeat file locking... don't try this at home, kids!
1926 (setq buffer-file-name nil)
1927 (insert-before-markers string)
1928 (setq insert-end (point))
1929 ;; If the message end is off screen, recenter now.
1930 (if (< (window-end nil t) insert-end)
1931 (recenter (/ (window-height) 2)))
1932 ;; If that pushed message start off the screen,
1933 ;; scroll to start it at the top of the screen.
1934 (move-to-window-line 0)
1935 (if (> (point) pos)
1936 (progn
1937 (goto-char pos)
1938 (recenter 0))))
1939 (message (or message "Type %s to continue editing.")
1940 (single-key-description exit-char))
1941 (let (char)
1942 (if (integerp exit-char)
1943 (condition-case nil
1944 (progn
1945 (setq char (read-char))
1946 (or (eq char exit-char)
1947 (setq unread-command-events (list char))))
1948 (error
1949 ;; `exit-char' is a character, hence it differs
1950 ;; from char, which is an event.
1951 (setq unread-command-events (list char))))
1952 ;; `exit-char' can be an event, or an event description
1953 ;; list.
1954 (setq char (read-event))
1955 (or (eq char exit-char)
1956 (eq char (event-convert-list exit-char))
1957 (setq unread-command-events (list char))))))
1958 (if insert-end
1959 (save-excursion
1960 (delete-region pos insert-end)))
1961 (setq buffer-file-name name)
1962 (set-buffer-modified-p modified))))
1965 ;;;; Overlay operations
1967 (defun copy-overlay (o)
1968 "Return a copy of overlay O."
1969 (let ((o1 (make-overlay (overlay-start o) (overlay-end o)
1970 ;; FIXME: there's no easy way to find the
1971 ;; insertion-type of the two markers.
1972 (overlay-buffer o)))
1973 (props (overlay-properties o)))
1974 (while props
1975 (overlay-put o1 (pop props) (pop props)))
1976 o1))
1978 (defun remove-overlays (&optional beg end name val)
1979 "Clear BEG and END of overlays whose property NAME has value VAL.
1980 Overlays might be moved and/or split.
1981 BEG and END default respectively to the beginning and end of buffer."
1982 ;; This speeds up the loops over overlays.
1983 (unless beg (setq beg (point-min)))
1984 (unless end (setq end (point-max)))
1985 (overlay-recenter end)
1986 (if (< end beg)
1987 (setq beg (prog1 end (setq end beg))))
1988 (save-excursion
1989 (dolist (o (overlays-in beg end))
1990 (when (eq (overlay-get o name) val)
1991 ;; Either push this overlay outside beg...end
1992 ;; or split it to exclude beg...end
1993 ;; or delete it entirely (if it is contained in beg...end).
1994 (if (< (overlay-start o) beg)
1995 (if (> (overlay-end o) end)
1996 (progn
1997 (move-overlay (copy-overlay o)
1998 (overlay-start o) beg)
1999 (move-overlay o end (overlay-end o)))
2000 (move-overlay o (overlay-start o) beg))
2001 (if (> (overlay-end o) end)
2002 (move-overlay o end (overlay-end o))
2003 (delete-overlay o)))))))
2005 ;;;; Miscellanea.
2007 (defvar suspend-hook nil
2008 "Normal hook run by `suspend-emacs', before suspending.")
2010 (defvar suspend-resume-hook nil
2011 "Normal hook run by `suspend-emacs', after Emacs is continued.")
2013 (defvar temp-buffer-show-hook nil
2014 "Normal hook run by `with-output-to-temp-buffer' after displaying the buffer.
2015 When the hook runs, the temporary buffer is current, and the window it
2016 was displayed in is selected. This hook is normally set up with a
2017 function to make the buffer read only, and find function names and
2018 variable names in it, provided the major mode is still Help mode.")
2020 (defvar temp-buffer-setup-hook nil
2021 "Normal hook run by `with-output-to-temp-buffer' at the start.
2022 When the hook runs, the temporary buffer is current.
2023 This hook is normally set up with a function to put the buffer in Help
2024 mode.")
2026 ;; Avoid compiler warnings about this variable,
2027 ;; which has a special meaning on certain system types.
2028 (defvar buffer-file-type nil
2029 "Non-nil if the visited file is a binary file.
2030 This variable is meaningful on MS-DOG and Windows NT.
2031 On those systems, it is automatically local in every buffer.
2032 On other systems, this variable is normally always nil.")
2034 ;; The `assert' macro from the cl package signals
2035 ;; `cl-assertion-failed' at runtime so always define it.
2036 (put 'cl-assertion-failed 'error-conditions '(error))
2037 (put 'cl-assertion-failed 'error-message "Assertion failed")
2040 ;;;; Misc. useful functions.
2042 (defun find-tag-default ()
2043 "Determine default tag to search for, based on text at point.
2044 If there is no plausible default, return nil."
2045 (save-excursion
2046 (while (looking-at "\\sw\\|\\s_")
2047 (forward-char 1))
2048 (if (or (re-search-backward "\\sw\\|\\s_"
2049 (save-excursion (beginning-of-line) (point))
2051 (re-search-forward "\\(\\sw\\|\\s_\\)+"
2052 (save-excursion (end-of-line) (point))
2054 (progn
2055 (goto-char (match-end 0))
2056 (condition-case nil
2057 (buffer-substring-no-properties
2058 (point)
2059 (progn (forward-sexp -1)
2060 (while (looking-at "\\s'")
2061 (forward-char 1))
2062 (point)))
2063 (error nil)))
2064 nil)))
2066 (defun play-sound (sound)
2067 "SOUND is a list of the form `(sound KEYWORD VALUE...)'.
2068 The following keywords are recognized:
2070 :file FILE - read sound data from FILE. If FILE isn't an
2071 absolute file name, it is searched in `data-directory'.
2073 :data DATA - read sound data from string DATA.
2075 Exactly one of :file or :data must be present.
2077 :volume VOL - set volume to VOL. VOL must an integer in the
2078 range 0..100 or a float in the range 0..1.0. If not specified,
2079 don't change the volume setting of the sound device.
2081 :device DEVICE - play sound on DEVICE. If not specified,
2082 a system-dependent default device name is used."
2083 (if (fboundp 'play-sound-internal)
2084 (play-sound-internal sound)
2085 (error "This Emacs binary lacks sound support")))
2087 (defun shell-quote-argument (argument)
2088 "Quote an argument for passing as argument to an inferior shell."
2089 (if (or (eq system-type 'ms-dos)
2090 (and (eq system-type 'windows-nt) (w32-shell-dos-semantics)))
2091 ;; Quote using double quotes, but escape any existing quotes in
2092 ;; the argument with backslashes.
2093 (let ((result "")
2094 (start 0)
2095 end)
2096 (if (or (null (string-match "[^\"]" argument))
2097 (< (match-end 0) (length argument)))
2098 (while (string-match "[\"]" argument start)
2099 (setq end (match-beginning 0)
2100 result (concat result (substring argument start end)
2101 "\\" (substring argument end (1+ end)))
2102 start (1+ end))))
2103 (concat "\"" result (substring argument start) "\""))
2104 (if (equal argument "")
2105 "''"
2106 ;; Quote everything except POSIX filename characters.
2107 ;; This should be safe enough even for really weird shells.
2108 (let ((result "") (start 0) end)
2109 (while (string-match "[^-0-9a-zA-Z_./]" argument start)
2110 (setq end (match-beginning 0)
2111 result (concat result (substring argument start end)
2112 "\\" (substring argument end (1+ end)))
2113 start (1+ end)))
2114 (concat result (substring argument start))))))
2116 (defun string-or-null-p (object)
2117 "Return t if OBJECT is a string or nil.
2118 Otherwise, return nil."
2119 (or (stringp object) (null object)))
2121 (defun booleanp (object)
2122 "Return non-nil if OBJECT is one of the two canonical boolean values: t or nil."
2123 (memq object '(nil t)))
2125 (defun field-at-pos (pos)
2126 "Return the field at position POS, taking stickiness etc into account"
2127 (let ((raw-field (get-char-property (field-beginning pos) 'field)))
2128 (if (eq raw-field 'boundary)
2129 (get-char-property (1- (field-end pos)) 'field)
2130 raw-field)))
2133 ;;;; Support for yanking and text properties.
2135 (defvar yank-excluded-properties)
2137 (defun remove-yank-excluded-properties (start end)
2138 "Remove `yank-excluded-properties' between START and END positions.
2139 Replaces `category' properties with their defined properties."
2140 (let ((inhibit-read-only t))
2141 ;; Replace any `category' property with the properties it stands for.
2142 (unless (memq yank-excluded-properties '(t nil))
2143 (save-excursion
2144 (goto-char start)
2145 (while (< (point) end)
2146 (let ((cat (get-text-property (point) 'category))
2147 run-end)
2148 (setq run-end
2149 (next-single-property-change (point) 'category nil end))
2150 (when cat
2151 (let (run-end2 original)
2152 (remove-list-of-text-properties (point) run-end '(category))
2153 (while (< (point) run-end)
2154 (setq run-end2 (next-property-change (point) nil run-end))
2155 (setq original (text-properties-at (point)))
2156 (set-text-properties (point) run-end2 (symbol-plist cat))
2157 (add-text-properties (point) run-end2 original)
2158 (goto-char run-end2))))
2159 (goto-char run-end)))))
2160 (if (eq yank-excluded-properties t)
2161 (set-text-properties start end nil)
2162 (remove-list-of-text-properties start end yank-excluded-properties))))
2164 (defvar yank-undo-function)
2166 (defun insert-for-yank (string)
2167 "Calls `insert-for-yank-1' repetitively for each `yank-handler' segment.
2169 See `insert-for-yank-1' for more details."
2170 (let (to)
2171 (while (setq to (next-single-property-change 0 'yank-handler string))
2172 (insert-for-yank-1 (substring string 0 to))
2173 (setq string (substring string to))))
2174 (insert-for-yank-1 string))
2176 (defun insert-for-yank-1 (string)
2177 "Insert STRING at point, stripping some text properties.
2179 Strip text properties from the inserted text according to
2180 `yank-excluded-properties'. Otherwise just like (insert STRING).
2182 If STRING has a non-nil `yank-handler' property on the first character,
2183 the normal insert behavior is modified in various ways. The value of
2184 the yank-handler property must be a list with one to four elements
2185 with the following format: (FUNCTION PARAM NOEXCLUDE UNDO).
2186 When FUNCTION is present and non-nil, it is called instead of `insert'
2187 to insert the string. FUNCTION takes one argument--the object to insert.
2188 If PARAM is present and non-nil, it replaces STRING as the object
2189 passed to FUNCTION (or `insert'); for example, if FUNCTION is
2190 `yank-rectangle', PARAM may be a list of strings to insert as a
2191 rectangle.
2192 If NOEXCLUDE is present and non-nil, the normal removal of the
2193 yank-excluded-properties is not performed; instead FUNCTION is
2194 responsible for removing those properties. This may be necessary
2195 if FUNCTION adjusts point before or after inserting the object.
2196 If UNDO is present and non-nil, it is a function that will be called
2197 by `yank-pop' to undo the insertion of the current object. It is
2198 called with two arguments, the start and end of the current region.
2199 FUNCTION may set `yank-undo-function' to override the UNDO value."
2200 (let* ((handler (and (stringp string)
2201 (get-text-property 0 'yank-handler string)))
2202 (param (or (nth 1 handler) string))
2203 (opoint (point))
2204 (inhibit-read-only inhibit-read-only)
2205 end)
2207 (setq yank-undo-function t)
2208 (if (nth 0 handler) ;; FUNCTION
2209 (funcall (car handler) param)
2210 (insert param))
2211 (setq end (point))
2213 ;; Prevent read-only properties from interfering with the
2214 ;; following text property changes.
2215 (setq inhibit-read-only t)
2217 ;; What should we do with `font-lock-face' properties?
2218 (if font-lock-defaults
2219 ;; No, just wipe them.
2220 (remove-list-of-text-properties opoint end '(font-lock-face))
2221 ;; Convert them to `face'.
2222 (save-excursion
2223 (goto-char opoint)
2224 (while (< (point) end)
2225 (let ((face (get-text-property (point) 'font-lock-face))
2226 run-end)
2227 (setq run-end
2228 (next-single-property-change (point) 'font-lock-face nil end))
2229 (when face
2230 (remove-text-properties (point) run-end '(font-lock-face nil))
2231 (put-text-property (point) run-end 'face face))
2232 (goto-char run-end)))))
2234 (unless (nth 2 handler) ;; NOEXCLUDE
2235 (remove-yank-excluded-properties opoint (point)))
2237 ;; If last inserted char has properties, mark them as rear-nonsticky.
2238 (if (and (> end opoint)
2239 (text-properties-at (1- end)))
2240 (put-text-property (1- end) end 'rear-nonsticky t))
2242 (if (eq yank-undo-function t) ;; not set by FUNCTION
2243 (setq yank-undo-function (nth 3 handler))) ;; UNDO
2244 (if (nth 4 handler) ;; COMMAND
2245 (setq this-command (nth 4 handler)))))
2247 (defun insert-buffer-substring-no-properties (buffer &optional start end)
2248 "Insert before point a substring of BUFFER, without text properties.
2249 BUFFER may be a buffer or a buffer name.
2250 Arguments START and END are character positions specifying the substring.
2251 They default to the values of (point-min) and (point-max) in BUFFER."
2252 (let ((opoint (point)))
2253 (insert-buffer-substring buffer start end)
2254 (let ((inhibit-read-only t))
2255 (set-text-properties opoint (point) nil))))
2257 (defun insert-buffer-substring-as-yank (buffer &optional start end)
2258 "Insert before point a part of BUFFER, stripping some text properties.
2259 BUFFER may be a buffer or a buffer name.
2260 Arguments START and END are character positions specifying the substring.
2261 They default to the values of (point-min) and (point-max) in BUFFER.
2262 Strip text properties from the inserted text according to
2263 `yank-excluded-properties'."
2264 ;; Since the buffer text should not normally have yank-handler properties,
2265 ;; there is no need to handle them here.
2266 (let ((opoint (point)))
2267 (insert-buffer-substring buffer start end)
2268 (remove-yank-excluded-properties opoint (point))))
2271 ;;;; Synchronous shell commands.
2273 (defun start-process-shell-command (name buffer &rest args)
2274 "Start a program in a subprocess. Return the process object for it.
2275 NAME is name for process. It is modified if necessary to make it unique.
2276 BUFFER is the buffer (or buffer name) to associate with the process.
2277 Process output goes at end of that buffer, unless you specify
2278 an output stream or filter function to handle the output.
2279 BUFFER may be also nil, meaning that this process is not associated
2280 with any buffer
2281 COMMAND is the name of a shell command.
2282 Remaining arguments are the arguments for the command; they are all
2283 spliced together with blanks separating between each two of them, before
2284 passing the command to the shell.
2285 Wildcards and redirection are handled as usual in the shell.
2287 \(fn NAME BUFFER COMMAND &rest COMMAND-ARGS)"
2288 (cond
2289 ((eq system-type 'vax-vms)
2290 (apply 'start-process name buffer args))
2291 ;; We used to use `exec' to replace the shell with the command,
2292 ;; but that failed to handle (...) and semicolon, etc.
2294 (start-process name buffer shell-file-name shell-command-switch
2295 (mapconcat 'identity args " ")))))
2297 (defun call-process-shell-command (command &optional infile buffer display
2298 &rest args)
2299 "Execute the shell command COMMAND synchronously in separate process.
2300 The remaining arguments are optional.
2301 The program's input comes from file INFILE (nil means `/dev/null').
2302 Insert output in BUFFER before point; t means current buffer;
2303 nil for BUFFER means discard it; 0 means discard and don't wait.
2304 BUFFER can also have the form (REAL-BUFFER STDERR-FILE); in that case,
2305 REAL-BUFFER says what to do with standard output, as above,
2306 while STDERR-FILE says what to do with standard error in the child.
2307 STDERR-FILE may be nil (discard standard error output),
2308 t (mix it with ordinary output), or a file name string.
2310 Fourth arg DISPLAY non-nil means redisplay buffer as output is inserted.
2311 Remaining arguments are strings passed as additional arguments for COMMAND.
2312 Wildcards and redirection are handled as usual in the shell.
2314 If BUFFER is 0, `call-process-shell-command' returns immediately with value nil.
2315 Otherwise it waits for COMMAND to terminate and returns a numeric exit
2316 status or a signal description string.
2317 If you quit, the process is killed with SIGINT, or SIGKILL if you quit again."
2318 (cond
2319 ((eq system-type 'vax-vms)
2320 (apply 'call-process command infile buffer display args))
2321 ;; We used to use `exec' to replace the shell with the command,
2322 ;; but that failed to handle (...) and semicolon, etc.
2324 (call-process shell-file-name
2325 infile buffer display
2326 shell-command-switch
2327 (mapconcat 'identity (cons command args) " ")))))
2329 ;;;; Lisp macros to do various things temporarily.
2331 (defmacro with-current-buffer (buffer &rest body)
2332 "Execute the forms in BODY with BUFFER temporarily current.
2333 BUFFER can be a buffer or a buffer name.
2334 The value returned is the value of the last form in BODY.
2335 See also `with-temp-buffer'."
2336 (declare (indent 1) (debug t))
2337 `(save-current-buffer
2338 (set-buffer ,buffer)
2339 ,@body))
2341 (defmacro with-selected-window (window &rest body)
2342 "Execute the forms in BODY with WINDOW as the selected window.
2343 The value returned is the value of the last form in BODY.
2345 This macro saves and restores the current buffer, since otherwise
2346 its normal operation could potentially make a different
2347 buffer current. It does not alter the buffer list ordering.
2349 This macro saves and restores the selected window, as well as
2350 the selected window in each frame. If the previously selected
2351 window of some frame is no longer live at the end of BODY, that
2352 frame's selected window is left alone. If the selected window is
2353 no longer live, then whatever window is selected at the end of
2354 BODY remains selected.
2355 See also `with-temp-buffer'."
2356 (declare (indent 1) (debug t))
2357 ;; Most of this code is a copy of save-selected-window.
2358 `(let ((save-selected-window-window (selected-window))
2359 ;; It is necessary to save all of these, because calling
2360 ;; select-window changes frame-selected-window for whatever
2361 ;; frame that window is in.
2362 (save-selected-window-alist
2363 (mapcar (lambda (frame) (list frame (frame-selected-window frame)))
2364 (frame-list))))
2365 (save-current-buffer
2366 (unwind-protect
2367 (progn (select-window ,window 'norecord)
2368 ,@body)
2369 (dolist (elt save-selected-window-alist)
2370 (and (frame-live-p (car elt))
2371 (window-live-p (cadr elt))
2372 (set-frame-selected-window (car elt) (cadr elt))))
2373 (if (window-live-p save-selected-window-window)
2374 (select-window save-selected-window-window 'norecord))))))
2376 (defmacro with-temp-file (file &rest body)
2377 "Create a new buffer, evaluate BODY there, and write the buffer to FILE.
2378 The value returned is the value of the last form in BODY.
2379 See also `with-temp-buffer'."
2380 (declare (debug t))
2381 (let ((temp-file (make-symbol "temp-file"))
2382 (temp-buffer (make-symbol "temp-buffer")))
2383 `(let ((,temp-file ,file)
2384 (,temp-buffer
2385 (get-buffer-create (generate-new-buffer-name " *temp file*"))))
2386 (unwind-protect
2387 (prog1
2388 (with-current-buffer ,temp-buffer
2389 ,@body)
2390 (with-current-buffer ,temp-buffer
2391 (widen)
2392 (write-region (point-min) (point-max) ,temp-file nil 0)))
2393 (and (buffer-name ,temp-buffer)
2394 (kill-buffer ,temp-buffer))))))
2396 (defmacro with-temp-message (message &rest body)
2397 "Display MESSAGE temporarily if non-nil while BODY is evaluated.
2398 The original message is restored to the echo area after BODY has finished.
2399 The value returned is the value of the last form in BODY.
2400 MESSAGE is written to the message log buffer if `message-log-max' is non-nil.
2401 If MESSAGE is nil, the echo area and message log buffer are unchanged.
2402 Use a MESSAGE of \"\" to temporarily clear the echo area."
2403 (declare (debug t))
2404 (let ((current-message (make-symbol "current-message"))
2405 (temp-message (make-symbol "with-temp-message")))
2406 `(let ((,temp-message ,message)
2407 (,current-message))
2408 (unwind-protect
2409 (progn
2410 (when ,temp-message
2411 (setq ,current-message (current-message))
2412 (message "%s" ,temp-message))
2413 ,@body)
2414 (and ,temp-message
2415 (if ,current-message
2416 (message "%s" ,current-message)
2417 (message nil)))))))
2419 (defmacro with-temp-buffer (&rest body)
2420 "Create a temporary buffer, and evaluate BODY there like `progn'.
2421 See also `with-temp-file' and `with-output-to-string'."
2422 (declare (indent 0) (debug t))
2423 (let ((temp-buffer (make-symbol "temp-buffer")))
2424 `(let ((,temp-buffer (generate-new-buffer " *temp*")))
2425 (unwind-protect
2426 (with-current-buffer ,temp-buffer
2427 ,@body)
2428 (and (buffer-name ,temp-buffer)
2429 (kill-buffer ,temp-buffer))))))
2431 (defmacro with-output-to-string (&rest body)
2432 "Execute BODY, return the text it sent to `standard-output', as a string."
2433 (declare (indent 0) (debug t))
2434 `(let ((standard-output
2435 (get-buffer-create (generate-new-buffer-name " *string-output*"))))
2436 (let ((standard-output standard-output))
2437 ,@body)
2438 (with-current-buffer standard-output
2439 (prog1
2440 (buffer-string)
2441 (kill-buffer nil)))))
2443 (defmacro with-local-quit (&rest body)
2444 "Execute BODY, allowing quits to terminate BODY but not escape further.
2445 When a quit terminates BODY, `with-local-quit' returns nil but
2446 requests another quit. That quit will be processed as soon as quitting
2447 is allowed once again. (Immediately, if `inhibit-quit' is nil.)"
2448 (declare (debug t) (indent 0))
2449 `(condition-case nil
2450 (let ((inhibit-quit nil))
2451 ,@body)
2452 (quit (setq quit-flag t)
2453 ;; This call is to give a chance to handle quit-flag
2454 ;; in case inhibit-quit is nil.
2455 ;; Without this, it will not be handled until the next function
2456 ;; call, and that might allow it to exit thru a condition-case
2457 ;; that intends to handle the quit signal next time.
2458 (eval '(ignore nil)))))
2460 (defmacro while-no-input (&rest body)
2461 "Execute BODY only as long as there's no pending input.
2462 If input arrives, that ends the execution of BODY,
2463 and `while-no-input' returns t. Quitting makes it return nil.
2464 If BODY finishes, `while-no-input' returns whatever value BODY produced."
2465 (declare (debug t) (indent 0))
2466 (let ((catch-sym (make-symbol "input")))
2467 `(with-local-quit
2468 (catch ',catch-sym
2469 (let ((throw-on-input ',catch-sym))
2470 (or (input-pending-p)
2471 ,@body))))))
2473 (defmacro combine-after-change-calls (&rest body)
2474 "Execute BODY, but don't call the after-change functions till the end.
2475 If BODY makes changes in the buffer, they are recorded
2476 and the functions on `after-change-functions' are called several times
2477 when BODY is finished.
2478 The return value is the value of the last form in BODY.
2480 If `before-change-functions' is non-nil, then calls to the after-change
2481 functions can't be deferred, so in that case this macro has no effect.
2483 Do not alter `after-change-functions' or `before-change-functions'
2484 in BODY."
2485 (declare (indent 0) (debug t))
2486 `(unwind-protect
2487 (let ((combine-after-change-calls t))
2488 . ,body)
2489 (combine-after-change-execute)))
2491 (defmacro with-case-table (table &rest body)
2492 "Execute the forms in BODY with TABLE as the current case table.
2493 The value returned is the value of the last form in BODY."
2494 (declare (indent 1) (debug t))
2495 (let ((old-case-table (make-symbol "table"))
2496 (old-buffer (make-symbol "buffer")))
2497 `(let ((,old-case-table (current-case-table))
2498 (,old-buffer (current-buffer)))
2499 (unwind-protect
2500 (progn (set-case-table ,table)
2501 ,@body)
2502 (with-current-buffer ,old-buffer
2503 (set-case-table ,old-case-table))))))
2505 ;;;; Constructing completion tables.
2507 (defmacro dynamic-completion-table (fun)
2508 "Use function FUN as a dynamic completion table.
2509 FUN is called with one argument, the string for which completion is required,
2510 and it should return an alist containing all the intended possible
2511 completions. This alist may be a full list of possible completions so that FUN
2512 can ignore the value of its argument. If completion is performed in the
2513 minibuffer, FUN will be called in the buffer from which the minibuffer was
2514 entered.
2516 The result of the `dynamic-completion-table' form is a function
2517 that can be used as the ALIST argument to `try-completion' and
2518 `all-completion'. See Info node `(elisp)Programmed Completion'."
2519 (declare (debug (lambda-expr)))
2520 (let ((win (make-symbol "window"))
2521 (string (make-symbol "string"))
2522 (predicate (make-symbol "predicate"))
2523 (mode (make-symbol "mode")))
2524 `(lambda (,string ,predicate ,mode)
2525 (with-current-buffer (let ((,win (minibuffer-selected-window)))
2526 (if (window-live-p ,win) (window-buffer ,win)
2527 (current-buffer)))
2528 (cond
2529 ((eq ,mode t) (all-completions ,string (,fun ,string) ,predicate))
2530 ((not ,mode) (try-completion ,string (,fun ,string) ,predicate))
2531 (t (test-completion ,string (,fun ,string) ,predicate)))))))
2533 (defmacro lazy-completion-table (var fun)
2534 ;; We used to have `&rest args' where `args' were evaluated late (at the
2535 ;; time of the call to `fun'), which was counter intuitive. But to get
2536 ;; them to be evaluated early, we have to either use lexical-let (which is
2537 ;; not available in subr.el) or use `(lambda (,str) ...) which prevents the use
2538 ;; of lexical-let in the callers.
2539 ;; So we just removed the argument. Callers can then simply use either of:
2540 ;; (lazy-completion-table var (lambda () (fun x y)))
2541 ;; or
2542 ;; (lazy-completion-table var `(lambda () (fun ',x ',y)))
2543 ;; or
2544 ;; (lexical-let ((x x)) ((y y))
2545 ;; (lazy-completion-table var (lambda () (fun x y))))
2546 ;; depending on the behavior they want.
2547 "Initialize variable VAR as a lazy completion table.
2548 If the completion table VAR is used for the first time (e.g., by passing VAR
2549 as an argument to `try-completion'), the function FUN is called with no
2550 arguments. FUN must return the completion table that will be stored in VAR.
2551 If completion is requested in the minibuffer, FUN will be called in the buffer
2552 from which the minibuffer was entered. The return value of
2553 `lazy-completion-table' must be used to initialize the value of VAR.
2555 You should give VAR a non-nil `risky-local-variable' property."
2556 (declare (debug (symbol lambda-expr)))
2557 (let ((str (make-symbol "string")))
2558 `(dynamic-completion-table
2559 (lambda (,str)
2560 (when (functionp ,var)
2561 (setq ,var (,fun)))
2562 ,var))))
2564 (defmacro complete-in-turn (a b)
2565 "Create a completion table that first tries completion in A and then in B.
2566 A and B should not be costly (or side-effecting) expressions."
2567 (declare (debug (def-form def-form)))
2568 `(lambda (string predicate mode)
2569 (cond
2570 ((eq mode t)
2571 (or (all-completions string ,a predicate)
2572 (all-completions string ,b predicate)))
2573 ((eq mode nil)
2574 (or (try-completion string ,a predicate)
2575 (try-completion string ,b predicate)))
2577 (or (test-completion string ,a predicate)
2578 (test-completion string ,b predicate))))))
2580 ;;; Matching and match data.
2582 (defvar save-match-data-internal)
2584 ;; We use save-match-data-internal as the local variable because
2585 ;; that works ok in practice (people should not use that variable elsewhere).
2586 ;; We used to use an uninterned symbol; the compiler handles that properly
2587 ;; now, but it generates slower code.
2588 (defmacro save-match-data (&rest body)
2589 "Execute the BODY forms, restoring the global value of the match data.
2590 The value returned is the value of the last form in BODY."
2591 ;; It is better not to use backquote here,
2592 ;; because that makes a bootstrapping problem
2593 ;; if you need to recompile all the Lisp files using interpreted code.
2594 (declare (indent 0) (debug t))
2595 (list 'let
2596 '((save-match-data-internal (match-data)))
2597 (list 'unwind-protect
2598 (cons 'progn body)
2599 ;; It is safe to free (evaporate) markers immediately here,
2600 ;; as Lisp programs should not copy from save-match-data-internal.
2601 '(set-match-data save-match-data-internal 'evaporate))))
2603 (defun match-string (num &optional string)
2604 "Return string of text matched by last search.
2605 NUM specifies which parenthesized expression in the last regexp.
2606 Value is nil if NUMth pair didn't match, or there were less than NUM pairs.
2607 Zero means the entire text matched by the whole regexp or whole string.
2608 STRING should be given if the last search was by `string-match' on STRING."
2609 (if (match-beginning num)
2610 (if string
2611 (substring string (match-beginning num) (match-end num))
2612 (buffer-substring (match-beginning num) (match-end num)))))
2614 (defun match-string-no-properties (num &optional string)
2615 "Return string of text matched by last search, without text properties.
2616 NUM specifies which parenthesized expression in the last regexp.
2617 Value is nil if NUMth pair didn't match, or there were less than NUM pairs.
2618 Zero means the entire text matched by the whole regexp or whole string.
2619 STRING should be given if the last search was by `string-match' on STRING."
2620 (if (match-beginning num)
2621 (if string
2622 (substring-no-properties string (match-beginning num)
2623 (match-end num))
2624 (buffer-substring-no-properties (match-beginning num)
2625 (match-end num)))))
2627 (defun looking-back (regexp &optional limit greedy)
2628 "Return non-nil if text before point matches regular expression REGEXP.
2629 Like `looking-at' except matches before point, and is slower.
2630 LIMIT if non-nil speeds up the search by specifying a minimum
2631 starting position, to avoid checking matches that would start
2632 before LIMIT.
2634 If GREEDY is non-nil, extend the match backwards as far as possible,
2635 stopping when a single additional previous character cannot be part
2636 of a match for REGEXP."
2637 (let ((start (point))
2638 (pos
2639 (save-excursion
2640 (and (re-search-backward (concat "\\(?:" regexp "\\)\\=") limit t)
2641 (point)))))
2642 (if (and greedy pos)
2643 (save-restriction
2644 (narrow-to-region (point-min) start)
2645 (while (and (> pos (point-min))
2646 (save-excursion
2647 (goto-char pos)
2648 (backward-char 1)
2649 (looking-at (concat "\\(?:" regexp "\\)\\'"))))
2650 (setq pos (1- pos)))
2651 (save-excursion
2652 (goto-char pos)
2653 (looking-at (concat "\\(?:" regexp "\\)\\'")))))
2654 (not (null pos))))
2656 (defun subregexp-context-p (regexp pos &optional start)
2657 "Return non-nil if POS is in a normal subregexp context in REGEXP.
2658 A subregexp context is one where a sub-regexp can appear.
2659 A non-subregexp context is for example within brackets, or within a
2660 repetition bounds operator `\\=\\{...\\}', or right after a `\\'.
2661 If START is non-nil, it should be a position in REGEXP, smaller
2662 than POS, and known to be in a subregexp context."
2663 ;; Here's one possible implementation, with the great benefit that it
2664 ;; reuses the regexp-matcher's own parser, so it understands all the
2665 ;; details of the syntax. A disadvantage is that it needs to match the
2666 ;; error string.
2667 (condition-case err
2668 (progn
2669 (string-match (substring regexp (or start 0) pos) "")
2671 (invalid-regexp
2672 (not (member (cadr err) '("Unmatched [ or [^"
2673 "Unmatched \\{"
2674 "Trailing backslash")))))
2675 ;; An alternative implementation:
2676 ;; (defconst re-context-re
2677 ;; (let* ((harmless-ch "[^\\[]")
2678 ;; (harmless-esc "\\\\[^{]")
2679 ;; (class-harmless-ch "[^][]")
2680 ;; (class-lb-harmless "[^]:]")
2681 ;; (class-lb-colon-maybe-charclass ":\\([a-z]+:]\\)?")
2682 ;; (class-lb (concat "\\[\\(" class-lb-harmless
2683 ;; "\\|" class-lb-colon-maybe-charclass "\\)"))
2684 ;; (class
2685 ;; (concat "\\[^?]?"
2686 ;; "\\(" class-harmless-ch
2687 ;; "\\|" class-lb "\\)*"
2688 ;; "\\[?]")) ; special handling for bare [ at end of re
2689 ;; (braces "\\\\{[0-9,]+\\\\}"))
2690 ;; (concat "\\`\\(" harmless-ch "\\|" harmless-esc
2691 ;; "\\|" class "\\|" braces "\\)*\\'"))
2692 ;; "Matches any prefix that corresponds to a normal subregexp context.")
2693 ;; (string-match re-context-re (substring regexp (or start 0) pos))
2696 ;;;; split-string
2698 (defconst split-string-default-separators "[ \f\t\n\r\v]+"
2699 "The default value of separators for `split-string'.
2701 A regexp matching strings of whitespace. May be locale-dependent
2702 \(as yet unimplemented). Should not match non-breaking spaces.
2704 Warning: binding this to a different value and using it as default is
2705 likely to have undesired semantics.")
2707 ;; The specification says that if both SEPARATORS and OMIT-NULLS are
2708 ;; defaulted, OMIT-NULLS should be treated as t. Simplifying the logical
2709 ;; expression leads to the equivalent implementation that if SEPARATORS
2710 ;; is defaulted, OMIT-NULLS is treated as t.
2711 (defun split-string (string &optional separators omit-nulls)
2712 "Split STRING into substrings bounded by matches for SEPARATORS.
2714 The beginning and end of STRING, and each match for SEPARATORS, are
2715 splitting points. The substrings matching SEPARATORS are removed, and
2716 the substrings between the splitting points are collected as a list,
2717 which is returned.
2719 If SEPARATORS is non-nil, it should be a regular expression matching text
2720 which separates, but is not part of, the substrings. If nil it defaults to
2721 `split-string-default-separators', normally \"[ \\f\\t\\n\\r\\v]+\", and
2722 OMIT-NULLS is forced to t.
2724 If OMIT-NULLS is t, zero-length substrings are omitted from the list \(so
2725 that for the default value of SEPARATORS leading and trailing whitespace
2726 are effectively trimmed). If nil, all zero-length substrings are retained,
2727 which correctly parses CSV format, for example.
2729 Note that the effect of `(split-string STRING)' is the same as
2730 `(split-string STRING split-string-default-separators t)'. In the rare
2731 case that you wish to retain zero-length substrings when splitting on
2732 whitespace, use `(split-string STRING split-string-default-separators)'.
2734 Modifies the match data; use `save-match-data' if necessary."
2735 (let ((keep-nulls (not (if separators omit-nulls t)))
2736 (rexp (or separators split-string-default-separators))
2737 (start 0)
2738 notfirst
2739 (list nil))
2740 (while (and (string-match rexp string
2741 (if (and notfirst
2742 (= start (match-beginning 0))
2743 (< start (length string)))
2744 (1+ start) start))
2745 (< start (length string)))
2746 (setq notfirst t)
2747 (if (or keep-nulls (< start (match-beginning 0)))
2748 (setq list
2749 (cons (substring string start (match-beginning 0))
2750 list)))
2751 (setq start (match-end 0)))
2752 (if (or keep-nulls (< start (length string)))
2753 (setq list
2754 (cons (substring string start)
2755 list)))
2756 (nreverse list)))
2758 ;;;; Replacement in strings.
2760 (defun subst-char-in-string (fromchar tochar string &optional inplace)
2761 "Replace FROMCHAR with TOCHAR in STRING each time it occurs.
2762 Unless optional argument INPLACE is non-nil, return a new string."
2763 (let ((i (length string))
2764 (newstr (if inplace string (copy-sequence string))))
2765 (while (> i 0)
2766 (setq i (1- i))
2767 (if (eq (aref newstr i) fromchar)
2768 (aset newstr i tochar)))
2769 newstr))
2771 (defun replace-regexp-in-string (regexp rep string &optional
2772 fixedcase literal subexp start)
2773 "Replace all matches for REGEXP with REP in STRING.
2775 Return a new string containing the replacements.
2777 Optional arguments FIXEDCASE, LITERAL and SUBEXP are like the
2778 arguments with the same names of function `replace-match'. If START
2779 is non-nil, start replacements at that index in STRING.
2781 REP is either a string used as the NEWTEXT arg of `replace-match' or a
2782 function. If it is a function, it is called with the actual text of each
2783 match, and its value is used as the replacement text. When REP is called,
2784 the match-data are the result of matching REGEXP against a substring
2785 of STRING.
2787 To replace only the first match (if any), make REGEXP match up to \\'
2788 and replace a sub-expression, e.g.
2789 (replace-regexp-in-string \"\\\\(foo\\\\).*\\\\'\" \"bar\" \" foo foo\" nil nil 1)
2790 => \" bar foo\"
2793 ;; To avoid excessive consing from multiple matches in long strings,
2794 ;; don't just call `replace-match' continually. Walk down the
2795 ;; string looking for matches of REGEXP and building up a (reversed)
2796 ;; list MATCHES. This comprises segments of STRING which weren't
2797 ;; matched interspersed with replacements for segments that were.
2798 ;; [For a `large' number of replacements it's more efficient to
2799 ;; operate in a temporary buffer; we can't tell from the function's
2800 ;; args whether to choose the buffer-based implementation, though it
2801 ;; might be reasonable to do so for long enough STRING.]
2802 (let ((l (length string))
2803 (start (or start 0))
2804 matches str mb me)
2805 (save-match-data
2806 (while (and (< start l) (string-match regexp string start))
2807 (setq mb (match-beginning 0)
2808 me (match-end 0))
2809 ;; If we matched the empty string, make sure we advance by one char
2810 (when (= me mb) (setq me (min l (1+ mb))))
2811 ;; Generate a replacement for the matched substring.
2812 ;; Operate only on the substring to minimize string consing.
2813 ;; Set up match data for the substring for replacement;
2814 ;; presumably this is likely to be faster than munging the
2815 ;; match data directly in Lisp.
2816 (string-match regexp (setq str (substring string mb me)))
2817 (setq matches
2818 (cons (replace-match (if (stringp rep)
2820 (funcall rep (match-string 0 str)))
2821 fixedcase literal str subexp)
2822 (cons (substring string start mb) ; unmatched prefix
2823 matches)))
2824 (setq start me))
2825 ;; Reconstruct a string from the pieces.
2826 (setq matches (cons (substring string start l) matches)) ; leftover
2827 (apply #'concat (nreverse matches)))))
2829 ;;;; invisibility specs
2831 (defun add-to-invisibility-spec (element)
2832 "Add ELEMENT to `buffer-invisibility-spec'.
2833 See documentation for `buffer-invisibility-spec' for the kind of elements
2834 that can be added."
2835 (if (eq buffer-invisibility-spec t)
2836 (setq buffer-invisibility-spec (list t)))
2837 (setq buffer-invisibility-spec
2838 (cons element buffer-invisibility-spec)))
2840 (defun remove-from-invisibility-spec (element)
2841 "Remove ELEMENT from `buffer-invisibility-spec'."
2842 (if (consp buffer-invisibility-spec)
2843 (setq buffer-invisibility-spec
2844 (delete element buffer-invisibility-spec))))
2846 ;;;; Syntax tables.
2848 (defmacro with-syntax-table (table &rest body)
2849 "Evaluate BODY with syntax table of current buffer set to TABLE.
2850 The syntax table of the current buffer is saved, BODY is evaluated, and the
2851 saved table is restored, even in case of an abnormal exit.
2852 Value is what BODY returns."
2853 (declare (debug t))
2854 (let ((old-table (make-symbol "table"))
2855 (old-buffer (make-symbol "buffer")))
2856 `(let ((,old-table (syntax-table))
2857 (,old-buffer (current-buffer)))
2858 (unwind-protect
2859 (progn
2860 (set-syntax-table ,table)
2861 ,@body)
2862 (save-current-buffer
2863 (set-buffer ,old-buffer)
2864 (set-syntax-table ,old-table))))))
2866 (defun make-syntax-table (&optional oldtable)
2867 "Return a new syntax table.
2868 Create a syntax table which inherits from OLDTABLE (if non-nil) or
2869 from `standard-syntax-table' otherwise."
2870 (let ((table (make-char-table 'syntax-table nil)))
2871 (set-char-table-parent table (or oldtable (standard-syntax-table)))
2872 table))
2874 (defun syntax-after (pos)
2875 "Return the raw syntax of the char after POS.
2876 If POS is outside the buffer's accessible portion, return nil."
2877 (unless (or (< pos (point-min)) (>= pos (point-max)))
2878 (let ((st (if parse-sexp-lookup-properties
2879 (get-char-property pos 'syntax-table))))
2880 (if (consp st) st
2881 (aref (or st (syntax-table)) (char-after pos))))))
2883 (defun syntax-class (syntax)
2884 "Return the syntax class part of the syntax descriptor SYNTAX.
2885 If SYNTAX is nil, return nil."
2886 (and syntax (logand (car syntax) 65535)))
2888 ;;;; Text clones
2890 (defun text-clone-maintain (ol1 after beg end &optional len)
2891 "Propagate the changes made under the overlay OL1 to the other clones.
2892 This is used on the `modification-hooks' property of text clones."
2893 (when (and after (not undo-in-progress) (overlay-start ol1))
2894 (let ((margin (if (overlay-get ol1 'text-clone-spreadp) 1 0)))
2895 (setq beg (max beg (+ (overlay-start ol1) margin)))
2896 (setq end (min end (- (overlay-end ol1) margin)))
2897 (when (<= beg end)
2898 (save-excursion
2899 (when (overlay-get ol1 'text-clone-syntax)
2900 ;; Check content of the clone's text.
2901 (let ((cbeg (+ (overlay-start ol1) margin))
2902 (cend (- (overlay-end ol1) margin)))
2903 (goto-char cbeg)
2904 (save-match-data
2905 (if (not (re-search-forward
2906 (overlay-get ol1 'text-clone-syntax) cend t))
2907 ;; Mark the overlay for deletion.
2908 (overlay-put ol1 'text-clones nil)
2909 (when (< (match-end 0) cend)
2910 ;; Shrink the clone at its end.
2911 (setq end (min end (match-end 0)))
2912 (move-overlay ol1 (overlay-start ol1)
2913 (+ (match-end 0) margin)))
2914 (when (> (match-beginning 0) cbeg)
2915 ;; Shrink the clone at its beginning.
2916 (setq beg (max (match-beginning 0) beg))
2917 (move-overlay ol1 (- (match-beginning 0) margin)
2918 (overlay-end ol1)))))))
2919 ;; Now go ahead and update the clones.
2920 (let ((head (- beg (overlay-start ol1)))
2921 (tail (- (overlay-end ol1) end))
2922 (str (buffer-substring beg end))
2923 (nothing-left t)
2924 (inhibit-modification-hooks t))
2925 (dolist (ol2 (overlay-get ol1 'text-clones))
2926 (let ((oe (overlay-end ol2)))
2927 (unless (or (eq ol1 ol2) (null oe))
2928 (setq nothing-left nil)
2929 (let ((mod-beg (+ (overlay-start ol2) head)))
2930 ;;(overlay-put ol2 'modification-hooks nil)
2931 (goto-char (- (overlay-end ol2) tail))
2932 (unless (> mod-beg (point))
2933 (save-excursion (insert str))
2934 (delete-region mod-beg (point)))
2935 ;;(overlay-put ol2 'modification-hooks '(text-clone-maintain))
2936 ))))
2937 (if nothing-left (delete-overlay ol1))))))))
2939 (defun text-clone-create (start end &optional spreadp syntax)
2940 "Create a text clone of START...END at point.
2941 Text clones are chunks of text that are automatically kept identical:
2942 changes done to one of the clones will be immediately propagated to the other.
2944 The buffer's content at point is assumed to be already identical to
2945 the one between START and END.
2946 If SYNTAX is provided it's a regexp that describes the possible text of
2947 the clones; the clone will be shrunk or killed if necessary to ensure that
2948 its text matches the regexp.
2949 If SPREADP is non-nil it indicates that text inserted before/after the
2950 clone should be incorporated in the clone."
2951 ;; To deal with SPREADP we can either use an overlay with `nil t' along
2952 ;; with insert-(behind|in-front-of)-hooks or use a slightly larger overlay
2953 ;; (with a one-char margin at each end) with `t nil'.
2954 ;; We opted for a larger overlay because it behaves better in the case
2955 ;; where the clone is reduced to the empty string (we want the overlay to
2956 ;; stay when the clone's content is the empty string and we want to use
2957 ;; `evaporate' to make sure those overlays get deleted when needed).
2959 (let* ((pt-end (+ (point) (- end start)))
2960 (start-margin (if (or (not spreadp) (bobp) (<= start (point-min)))
2961 0 1))
2962 (end-margin (if (or (not spreadp)
2963 (>= pt-end (point-max))
2964 (>= start (point-max)))
2965 0 1))
2966 (ol1 (make-overlay (- start start-margin) (+ end end-margin) nil t))
2967 (ol2 (make-overlay (- (point) start-margin) (+ pt-end end-margin) nil t))
2968 (dups (list ol1 ol2)))
2969 (overlay-put ol1 'modification-hooks '(text-clone-maintain))
2970 (when spreadp (overlay-put ol1 'text-clone-spreadp t))
2971 (when syntax (overlay-put ol1 'text-clone-syntax syntax))
2972 ;;(overlay-put ol1 'face 'underline)
2973 (overlay-put ol1 'evaporate t)
2974 (overlay-put ol1 'text-clones dups)
2976 (overlay-put ol2 'modification-hooks '(text-clone-maintain))
2977 (when spreadp (overlay-put ol2 'text-clone-spreadp t))
2978 (when syntax (overlay-put ol2 'text-clone-syntax syntax))
2979 ;;(overlay-put ol2 'face 'underline)
2980 (overlay-put ol2 'evaporate t)
2981 (overlay-put ol2 'text-clones dups)))
2983 ;;;; Mail user agents.
2985 ;; Here we include just enough for other packages to be able
2986 ;; to define them.
2988 (defun define-mail-user-agent (symbol composefunc sendfunc
2989 &optional abortfunc hookvar)
2990 "Define a symbol to identify a mail-sending package for `mail-user-agent'.
2992 SYMBOL can be any Lisp symbol. Its function definition and/or
2993 value as a variable do not matter for this usage; we use only certain
2994 properties on its property list, to encode the rest of the arguments.
2996 COMPOSEFUNC is program callable function that composes an outgoing
2997 mail message buffer. This function should set up the basics of the
2998 buffer without requiring user interaction. It should populate the
2999 standard mail headers, leaving the `to:' and `subject:' headers blank
3000 by default.
3002 COMPOSEFUNC should accept several optional arguments--the same
3003 arguments that `compose-mail' takes. See that function's documentation.
3005 SENDFUNC is the command a user would run to send the message.
3007 Optional ABORTFUNC is the command a user would run to abort the
3008 message. For mail packages that don't have a separate abort function,
3009 this can be `kill-buffer' (the equivalent of omitting this argument).
3011 Optional HOOKVAR is a hook variable that gets run before the message
3012 is actually sent. Callers that use the `mail-user-agent' may
3013 install a hook function temporarily on this hook variable.
3014 If HOOKVAR is nil, `mail-send-hook' is used.
3016 The properties used on SYMBOL are `composefunc', `sendfunc',
3017 `abortfunc', and `hookvar'."
3018 (put symbol 'composefunc composefunc)
3019 (put symbol 'sendfunc sendfunc)
3020 (put symbol 'abortfunc (or abortfunc 'kill-buffer))
3021 (put symbol 'hookvar (or hookvar 'mail-send-hook)))
3023 ;;;; Progress reporters.
3025 ;; Progress reporter has the following structure:
3027 ;; (NEXT-UPDATE-VALUE . [NEXT-UPDATE-TIME
3028 ;; MIN-VALUE
3029 ;; MAX-VALUE
3030 ;; MESSAGE
3031 ;; MIN-CHANGE
3032 ;; MIN-TIME])
3034 ;; This weirdeness is for optimization reasons: we want
3035 ;; `progress-reporter-update' to be as fast as possible, so
3036 ;; `(car reporter)' is better than `(aref reporter 0)'.
3038 ;; NEXT-UPDATE-TIME is a float. While `float-time' loses a couple
3039 ;; digits of precision, it doesn't really matter here. On the other
3040 ;; hand, it greatly simplifies the code.
3042 (defsubst progress-reporter-update (reporter value)
3043 "Report progress of an operation in the echo area.
3044 However, if the change since last echo area update is too small
3045 or not enough time has passed, then do nothing (see
3046 `make-progress-reporter' for details).
3048 First parameter, REPORTER, should be the result of a call to
3049 `make-progress-reporter'. Second, VALUE, determines the actual
3050 progress of operation; it must be between MIN-VALUE and MAX-VALUE
3051 as passed to `make-progress-reporter'.
3053 This function is very inexpensive, you may not bother how often
3054 you call it."
3055 (when (>= value (car reporter))
3056 (progress-reporter-do-update reporter value)))
3058 (defun make-progress-reporter (message min-value max-value
3059 &optional current-value
3060 min-change min-time)
3061 "Return progress reporter object to be used with `progress-reporter-update'.
3063 MESSAGE is shown in the echo area. When at least 1% of operation
3064 is complete, the exact percentage will be appended to the
3065 MESSAGE. When you call `progress-reporter-done', word \"done\"
3066 is printed after the MESSAGE. You can change MESSAGE of an
3067 existing progress reporter with `progress-reporter-force-update'.
3069 MIN-VALUE and MAX-VALUE designate starting (0% complete) and
3070 final (100% complete) states of operation. The latter should be
3071 larger; if this is not the case, then simply negate all values.
3072 Optional CURRENT-VALUE specifies the progress by the moment you
3073 call this function. You should omit it or set it to nil in most
3074 cases since it defaults to MIN-VALUE.
3076 Optional MIN-CHANGE determines the minimal change in percents to
3077 report (default is 1%.) Optional MIN-TIME specifies the minimal
3078 time before echo area updates (default is 0.2 seconds.) If
3079 `float-time' function is not present, then time is not tracked
3080 at all. If OS is not capable of measuring fractions of seconds,
3081 then this parameter is effectively rounded up."
3083 (unless min-time
3084 (setq min-time 0.2))
3085 (let ((reporter
3086 (cons min-value ;; Force a call to `message' now
3087 (vector (if (and (fboundp 'float-time)
3088 (>= min-time 0.02))
3089 (float-time) nil)
3090 min-value
3091 max-value
3092 message
3093 (if min-change (max (min min-change 50) 1) 1)
3094 min-time))))
3095 (progress-reporter-update reporter (or current-value min-value))
3096 reporter))
3098 (defun progress-reporter-force-update (reporter value &optional new-message)
3099 "Report progress of an operation in the echo area unconditionally.
3101 First two parameters are the same as for
3102 `progress-reporter-update'. Optional NEW-MESSAGE allows you to
3103 change the displayed message."
3104 (let ((parameters (cdr reporter)))
3105 (when new-message
3106 (aset parameters 3 new-message))
3107 (when (aref parameters 0)
3108 (aset parameters 0 (float-time)))
3109 (progress-reporter-do-update reporter value)))
3111 (defun progress-reporter-do-update (reporter value)
3112 (let* ((parameters (cdr reporter))
3113 (min-value (aref parameters 1))
3114 (max-value (aref parameters 2))
3115 (one-percent (/ (- max-value min-value) 100.0))
3116 (percentage (if (= max-value min-value)
3118 (truncate (/ (- value min-value) one-percent))))
3119 (update-time (aref parameters 0))
3120 (current-time (float-time))
3121 (enough-time-passed
3122 ;; See if enough time has passed since the last update.
3123 (or (not update-time)
3124 (when (>= current-time update-time)
3125 ;; Calculate time for the next update
3126 (aset parameters 0 (+ update-time (aref parameters 5)))))))
3128 ;; Calculate NEXT-UPDATE-VALUE. If we are not going to print
3129 ;; message this time because not enough time has passed, then use
3130 ;; 1 instead of MIN-CHANGE. This makes delays between echo area
3131 ;; updates closer to MIN-TIME.
3132 (setcar reporter
3133 (min (+ min-value (* (+ percentage
3134 (if enough-time-passed
3135 (aref parameters 4) ;; MIN-CHANGE
3137 one-percent))
3138 max-value))
3139 (when (integerp value)
3140 (setcar reporter (ceiling (car reporter))))
3142 ;; Only print message if enough time has passed
3143 (when enough-time-passed
3144 (if (> percentage 0)
3145 (message "%s%d%%" (aref parameters 3) percentage)
3146 (message "%s" (aref parameters 3))))))
3148 (defun progress-reporter-done (reporter)
3149 "Print reporter's message followed by word \"done\" in echo area."
3150 (message "%sdone" (aref (cdr reporter) 3)))
3152 (defmacro dotimes-with-progress-reporter (spec message &rest body)
3153 "Loop a certain number of times and report progress in the echo area.
3154 Evaluate BODY with VAR bound to successive integers running from
3155 0, inclusive, to COUNT, exclusive. Then evaluate RESULT to get
3156 the return value (nil if RESULT is omitted).
3158 At each iteration MESSAGE followed by progress percentage is
3159 printed in the echo area. After the loop is finished, MESSAGE
3160 followed by word \"done\" is printed. This macro is a
3161 convenience wrapper around `make-progress-reporter' and friends.
3163 \(fn (VAR COUNT [RESULT]) MESSAGE BODY...)"
3164 (declare (indent 2) (debug ((symbolp form &optional form) form body)))
3165 (let ((temp (make-symbol "--dotimes-temp--"))
3166 (temp2 (make-symbol "--dotimes-temp2--"))
3167 (start 0)
3168 (end (nth 1 spec)))
3169 `(let ((,temp ,end)
3170 (,(car spec) ,start)
3171 (,temp2 (make-progress-reporter ,message ,start ,end)))
3172 (while (< ,(car spec) ,temp)
3173 ,@body
3174 (progress-reporter-update ,temp2
3175 (setq ,(car spec) (1+ ,(car spec)))))
3176 (progress-reporter-done ,temp2)
3177 nil ,@(cdr (cdr spec)))))
3180 ;;;; Comparing version strings.
3182 (defvar version-separator "."
3183 "*Specify the string used to separate the version elements.
3185 Usually the separator is \".\", but it can be any other string.")
3188 (defvar version-regexp-alist
3189 '(("^[-_+ ]?a\\(lpha\\)?$" . -3)
3190 ("^[-_+]$" . -3) ; treat "1.2.3-20050920" and "1.2-3" as alpha releases
3191 ("^[-_+ ]cvs$" . -3) ; treat "1.2.3-CVS" as alpha release
3192 ("^[-_+ ]?b\\(eta\\)?$" . -2)
3193 ("^[-_+ ]?\\(pre\\|rc\\)$" . -1))
3194 "*Specify association between non-numeric version part and a priority.
3196 This association is used to handle version string like \"1.0pre2\",
3197 \"0.9alpha1\", etc. It's used by `version-to-list' (which see) to convert the
3198 non-numeric part to an integer. For example:
3200 String Version Integer List Version
3201 \"1.0pre2\" (1 0 -1 2)
3202 \"1.0PRE2\" (1 0 -1 2)
3203 \"22.8beta3\" (22 8 -2 3)
3204 \"22.8 Beta3\" (22 8 -2 3)
3205 \"0.9alpha1\" (0 9 -3 1)
3206 \"0.9AlphA1\" (0 9 -3 1)
3207 \"0.9 alpha\" (0 9 -3)
3209 Each element has the following form:
3211 (REGEXP . PRIORITY)
3213 Where:
3215 REGEXP regexp used to match non-numeric part of a version string.
3216 It should begin with a `^' anchor and end with a `$' to
3217 prevent false hits. Letter-case is ignored while matching
3218 REGEXP.
3220 PRIORITY negative integer which indicate the non-numeric priority.")
3223 (defun version-to-list (ver)
3224 "Convert version string VER into an integer list.
3226 The version syntax is given by the following EBNF:
3228 VERSION ::= NUMBER ( SEPARATOR NUMBER )*.
3230 NUMBER ::= (0|1|2|3|4|5|6|7|8|9)+.
3232 SEPARATOR ::= `version-separator' (which see)
3233 | `version-regexp-alist' (which see).
3235 The NUMBER part is optional if SEPARATOR is a match for an element
3236 in `version-regexp-alist'.
3238 As an example of valid version syntax:
3240 1.0pre2 1.0.7.5 22.8beta3 0.9alpha1 6.9.30Beta
3242 As an example of invalid version syntax:
3244 1.0prepre2 1.0..7.5 22.8X3 alpha3.2 .5
3246 As an example of version convertion:
3248 String Version Integer List Version
3249 \"1.0.7.5\" (1 0 7 5)
3250 \"1.0pre2\" (1 0 -1 2)
3251 \"1.0PRE2\" (1 0 -1 2)
3252 \"22.8beta3\" (22 8 -2 3)
3253 \"22.8Beta3\" (22 8 -2 3)
3254 \"0.9alpha1\" (0 9 -3 1)
3255 \"0.9AlphA1\" (0 9 -3 1)
3256 \"0.9alpha\" (0 9 -3)
3258 See documentation for `version-separator' and `version-regexp-alist'."
3259 (or (and (stringp ver) (> (length ver) 0))
3260 (error "Invalid version string: '%s'" ver))
3261 ;; Change .x.y to 0.x.y
3262 (if (and (>= (length ver) (length version-separator))
3263 (string-equal (substring ver 0 (length version-separator))
3264 version-separator))
3265 (setq ver (concat "0" ver)))
3266 (save-match-data
3267 (let ((i 0)
3268 (case-fold-search t) ; ignore case in matching
3269 lst s al)
3270 (while (and (setq s (string-match "[0-9]+" ver i))
3271 (= s i))
3272 ;; handle numeric part
3273 (setq lst (cons (string-to-number (substring ver i (match-end 0)))
3274 lst)
3275 i (match-end 0))
3276 ;; handle non-numeric part
3277 (when (and (setq s (string-match "[^0-9]+" ver i))
3278 (= s i))
3279 (setq s (substring ver i (match-end 0))
3280 i (match-end 0))
3281 ;; handle alpha, beta, pre, etc. separator
3282 (unless (string= s version-separator)
3283 (setq al version-regexp-alist)
3284 (while (and al (not (string-match (caar al) s)))
3285 (setq al (cdr al)))
3286 (or al (error "Invalid version syntax: '%s'" ver))
3287 (setq lst (cons (cdar al) lst)))))
3288 (if (null lst)
3289 (error "Invalid version syntax: '%s'" ver)
3290 (nreverse lst)))))
3293 (defun version-list-< (l1 l2)
3294 "Return t if integer list L1 is lesser than L2.
3296 Note that integer list (1) is equal to (1 0), (1 0 0), (1 0 0 0),
3297 etc. That is, the trailing zeroes are irrelevant. Also, integer
3298 list (1) is greater than (1 -1) which is greater than (1 -2)
3299 which is greater than (1 -3)."
3300 (while (and l1 l2 (= (car l1) (car l2)))
3301 (setq l1 (cdr l1)
3302 l2 (cdr l2)))
3303 (cond
3304 ;; l1 not null and l2 not null
3305 ((and l1 l2) (< (car l1) (car l2)))
3306 ;; l1 null and l2 null ==> l1 length = l2 length
3307 ((and (null l1) (null l2)) nil)
3308 ;; l1 not null and l2 null ==> l1 length > l2 length
3309 (l1 (< (version-list-not-zero l1) 0))
3310 ;; l1 null and l2 not null ==> l2 length > l1 length
3311 (t (< 0 (version-list-not-zero l2)))))
3314 (defun version-list-= (l1 l2)
3315 "Return t if integer list L1 is equal to L2.
3317 Note that integer list (1) is equal to (1 0), (1 0 0), (1 0 0 0),
3318 etc. That is, the trailing zeroes are irrelevant. Also, integer
3319 list (1) is greater than (1 -1) which is greater than (1 -2)
3320 which is greater than (1 -3)."
3321 (while (and l1 l2 (= (car l1) (car l2)))
3322 (setq l1 (cdr l1)
3323 l2 (cdr l2)))
3324 (cond
3325 ;; l1 not null and l2 not null
3326 ((and l1 l2) nil)
3327 ;; l1 null and l2 null ==> l1 length = l2 length
3328 ((and (null l1) (null l2)))
3329 ;; l1 not null and l2 null ==> l1 length > l2 length
3330 (l1 (zerop (version-list-not-zero l1)))
3331 ;; l1 null and l2 not null ==> l2 length > l1 length
3332 (t (zerop (version-list-not-zero l2)))))
3335 (defun version-list-<= (l1 l2)
3336 "Return t if integer list L1 is lesser than or equal to L2.
3338 Note that integer list (1) is equal to (1 0), (1 0 0), (1 0 0 0),
3339 etc. That is, the trailing zeroes are irrelevant. Also, integer
3340 list (1) is greater than (1 -1) which is greater than (1 -2)
3341 which is greater than (1 -3)."
3342 (while (and l1 l2 (= (car l1) (car l2)))
3343 (setq l1 (cdr l1)
3344 l2 (cdr l2)))
3345 (cond
3346 ;; l1 not null and l2 not null
3347 ((and l1 l2) (< (car l1) (car l2)))
3348 ;; l1 null and l2 null ==> l1 length = l2 length
3349 ((and (null l1) (null l2)))
3350 ;; l1 not null and l2 null ==> l1 length > l2 length
3351 (l1 (<= (version-list-not-zero l1) 0))
3352 ;; l1 null and l2 not null ==> l2 length > l1 length
3353 (t (<= 0 (version-list-not-zero l2)))))
3355 (defun version-list-not-zero (lst)
3356 "Return the first non-zero element of integer list LST.
3358 If all LST elements are zeroes or LST is nil, return zero."
3359 (while (and lst (zerop (car lst)))
3360 (setq lst (cdr lst)))
3361 (if lst
3362 (car lst)
3363 ;; there is no element different of zero
3367 (defun version< (v1 v2)
3368 "Return t if version V1 is lesser than V2.
3370 Note that version string \"1\" is equal to \"1.0\", \"1.0.0\", \"1.0.0.0\",
3371 etc. That is, the trailing \".0\"s are irrelevant. Also, version string \"1\"
3372 is greater than \"1pre\" which is greater than \"1beta\" which is greater than
3373 \"1alpha\"."
3374 (version-list-< (version-to-list v1) (version-to-list v2)))
3377 (defun version<= (v1 v2)
3378 "Return t if version V1 is lesser than or equal to V2.
3380 Note that version string \"1\" is equal to \"1.0\", \"1.0.0\", \"1.0.0.0\",
3381 etc. That is, the trailing \".0\"s are irrelevant. Also, version string \"1\"
3382 is greater than \"1pre\" which is greater than \"1beta\" which is greater than
3383 \"1alpha\"."
3384 (version-list-<= (version-to-list v1) (version-to-list v2)))
3386 (defun version= (v1 v2)
3387 "Return t if version V1 is equal to V2.
3389 Note that version string \"1\" is equal to \"1.0\", \"1.0.0\", \"1.0.0.0\",
3390 etc. That is, the trailing \".0\"s are irrelevant. Also, version string \"1\"
3391 is greater than \"1pre\" which is greater than \"1beta\" which is greater than
3392 \"1alpha\"."
3393 (version-list-= (version-to-list v1) (version-to-list v2)))
3397 ;; arch-tag: f7e0e6e5-70aa-4897-ae72-7a3511ec40bc
3398 ;;; subr.el ends here