2 @c This is part of the GNU Emacs Lisp Reference Manual.
3 @c Copyright (C) 1990, 1991, 1992, 1993, 1994, 1995, 1998, 1999, 2001, 2002,
4 @c 2003, 2004, 2005, 2006, 2007, 2008, 2009 Free Software Foundation, Inc.
5 @c See the file elisp.texi for copying conditions.
6 @setfilename ../../info/minibuf
7 @node Minibuffers, Command Loop, Read and Print, Top
9 @cindex arguments, reading
10 @cindex complex arguments
13 A @dfn{minibuffer} is a special buffer that Emacs commands use to
14 read arguments more complicated than the single numeric prefix
15 argument. These arguments include file names, buffer names, and
16 command names (as in @kbd{M-x}). The minibuffer is displayed on the
17 bottom line of the frame, in the same place as the echo area
18 (@pxref{The Echo Area}), but only while it is in use for reading an
22 * Intro to Minibuffers:: Basic information about minibuffers.
23 * Text from Minibuffer:: How to read a straight text string.
24 * Object from Minibuffer:: How to read a Lisp object or expression.
25 * Minibuffer History:: Recording previous minibuffer inputs
26 so the user can reuse them.
27 * Initial Input:: Specifying initial contents for the minibuffer.
28 * Completion:: How to invoke and customize completion.
29 * Yes-or-No Queries:: Asking a question with a simple answer.
30 * Multiple Queries:: Asking a series of similar questions.
31 * Reading a Password:: Reading a password from the terminal.
32 * Minibuffer Commands:: Commands used as key bindings in minibuffers.
33 * Minibuffer Contents:: How such commands access the minibuffer text.
34 * Minibuffer Windows:: Operating on the special minibuffer windows.
35 * Recursive Mini:: Whether recursive entry to minibuffer is allowed.
36 * Minibuffer Misc:: Various customization hooks and variables.
39 @node Intro to Minibuffers
40 @section Introduction to Minibuffers
42 In most ways, a minibuffer is a normal Emacs buffer. Most operations
43 @emph{within} a buffer, such as editing commands, work normally in a
44 minibuffer. However, many operations for managing buffers do not apply
45 to minibuffers. The name of a minibuffer always has the form @w{@samp{
46 *Minibuf-@var{number}*}}, and it cannot be changed. Minibuffers are
47 displayed only in special windows used only for minibuffers; these
48 windows always appear at the bottom of a frame. (Sometimes frames have
49 no minibuffer window, and sometimes a special kind of frame contains
50 nothing but a minibuffer window; see @ref{Minibuffers and Frames}.)
52 The text in the minibuffer always starts with the @dfn{prompt string},
53 the text that was specified by the program that is using the minibuffer
54 to tell the user what sort of input to type. This text is marked
55 read-only so you won't accidentally delete or change it. It is also
56 marked as a field (@pxref{Fields}), so that certain motion functions,
57 including @code{beginning-of-line}, @code{forward-word},
58 @code{forward-sentence}, and @code{forward-paragraph}, stop at the
59 boundary between the prompt and the actual text.
61 The minibuffer's window is normally a single line; it grows
62 automatically if the contents require more space. You can explicitly
63 resize it temporarily with the window sizing commands; it reverts to
64 its normal size when the minibuffer is exited. You can resize it
65 permanently by using the window sizing commands in the frame's other
66 window, when the minibuffer is not active. If the frame contains just
67 a minibuffer, you can change the minibuffer's size by changing the
70 Use of the minibuffer reads input events, and that alters the values
71 of variables such as @code{this-command} and @code{last-command}
72 (@pxref{Command Loop Info}). Your program should bind them around the
73 code that uses the minibuffer, if you do not want that to change them.
75 Under some circumstances, a command can use a minibuffer even if
76 there is an active minibuffer; such minibuffers are called a
77 @dfn{recursive minibuffer}. The first minibuffer is named
78 @w{@samp{ *Minibuf-0*}}. Recursive minibuffers are named by
79 incrementing the number at the end of the name. (The names begin with
80 a space so that they won't show up in normal buffer lists.) Of
81 several recursive minibuffers, the innermost (or most recently
82 entered) is the active minibuffer. We usually call this ``the''
83 minibuffer. You can permit or forbid recursive minibuffers by setting
84 the variable @code{enable-recursive-minibuffers}, or by putting
85 properties of that name on command symbols (@xref{Recursive Mini}.)
87 Like other buffers, a minibuffer uses a local keymap
88 (@pxref{Keymaps}) to specify special key bindings. The function that
89 invokes the minibuffer also sets up its local map according to the job
90 to be done. @xref{Text from Minibuffer}, for the non-completion
91 minibuffer local maps. @xref{Completion Commands}, for the minibuffer
92 local maps for completion.
94 When Emacs is running in batch mode, any request to read from the
95 minibuffer actually reads a line from the standard input descriptor that
96 was supplied when Emacs was started.
98 @node Text from Minibuffer
99 @section Reading Text Strings with the Minibuffer
101 The most basic primitive for minibuffer input is
102 @code{read-from-minibuffer}, which can be used to read either a string
103 or a Lisp object in textual form. The function @code{read-regexp} is
104 used for reading regular expressions (@pxref{Regular Expressions}),
105 which are a special kind of string. There are also specialized
106 functions for reading commands, variables, file names, etc.@:
107 (@pxref{Completion}).
109 In most cases, you should not call minibuffer input functions in the
110 middle of a Lisp function. Instead, do all minibuffer input as part of
111 reading the arguments for a command, in the @code{interactive}
112 specification. @xref{Defining Commands}.
114 @defun read-from-minibuffer prompt-string &optional initial-contents keymap read hist default inherit-input-method
115 This function is the most general way to get input from the
116 minibuffer. By default, it accepts arbitrary text and returns it as a
117 string; however, if @var{read} is non-@code{nil}, then it uses
118 @code{read} to convert the text into a Lisp object (@pxref{Input
121 The first thing this function does is to activate a minibuffer and
122 display it with @var{prompt-string} as the prompt. This value must be a
123 string. Then the user can edit text in the minibuffer.
125 When the user types a command to exit the minibuffer,
126 @code{read-from-minibuffer} constructs the return value from the text in
127 the minibuffer. Normally it returns a string containing that text.
128 However, if @var{read} is non-@code{nil}, @code{read-from-minibuffer}
129 reads the text and returns the resulting Lisp object, unevaluated.
130 (@xref{Input Functions}, for information about reading.)
132 The argument @var{default} specifies default values to make available
133 through the history commands. It should be a string, a list of
134 strings, or @code{nil}. The string or strings become the minibuffer's
135 ``future history,'' available to the user with @kbd{M-n}.
137 If @var{read} is non-@code{nil}, then @var{default} is also used
138 as the input to @code{read}, if the user enters empty input.
139 If @var{default} is a list of strings, the first string is used as the input.
140 If @var{default} is @code{nil}, empty input results in an @code{end-of-file} error.
141 However, in the usual case (where @var{read} is @code{nil}),
142 @code{read-from-minibuffer} ignores @var{default} when the user enters
143 empty input and returns an empty string, @code{""}. In this respect,
144 it differs from all the other minibuffer input functions in this chapter.
146 If @var{keymap} is non-@code{nil}, that keymap is the local keymap to
147 use in the minibuffer. If @var{keymap} is omitted or @code{nil}, the
148 value of @code{minibuffer-local-map} is used as the keymap. Specifying
149 a keymap is the most important way to customize the minibuffer for
150 various applications such as completion.
152 The argument @var{hist} specifies which history list variable to use
153 for saving the input and for history commands used in the minibuffer.
154 It defaults to @code{minibuffer-history}. @xref{Minibuffer History}.
156 If the variable @code{minibuffer-allow-text-properties} is
157 non-@code{nil}, then the string which is returned includes whatever text
158 properties were present in the minibuffer. Otherwise all the text
159 properties are stripped when the value is returned.
161 If the argument @var{inherit-input-method} is non-@code{nil}, then the
162 minibuffer inherits the current input method (@pxref{Input Methods}) and
163 the setting of @code{enable-multibyte-characters} (@pxref{Text
164 Representations}) from whichever buffer was current before entering the
167 Use of @var{initial-contents} is mostly deprecated; we recommend using
168 a non-@code{nil} value only in conjunction with specifying a cons cell
169 for @var{hist}. @xref{Initial Input}.
172 @defun read-string prompt &optional initial history default inherit-input-method
173 This function reads a string from the minibuffer and returns it. The
174 arguments @var{prompt}, @var{initial}, @var{history} and
175 @var{inherit-input-method} are used as in @code{read-from-minibuffer}.
176 The keymap used is @code{minibuffer-local-map}.
178 The optional argument @var{default} is used as in
179 @code{read-from-minibuffer}, except that, if non-@code{nil}, it also
180 specifies a default value to return if the user enters null input. As
181 in @code{read-from-minibuffer} it should be a string, a list of
182 strings, or @code{nil} which is equivalent to an empty string. When
183 @var{default} is a string, that string is the default value. When it
184 is a list of strings, the first string is the default value. (All
185 these strings are available to the user in the ``future minibuffer
188 This function works by calling the
189 @code{read-from-minibuffer} function:
193 (read-string @var{prompt} @var{initial} @var{history} @var{default} @var{inherit})
196 (read-from-minibuffer @var{prompt} @var{initial} nil nil
197 @var{history} @var{default} @var{inherit})))
198 (if (and (equal value "") @var{default})
199 (if (consp @var{default}) (car @var{default}) @var{default})
205 @defun read-regexp prompt &optional default-value
206 This function reads a regular expression as a string from the
207 minibuffer and returns it. The argument @var{prompt} is used as in
208 @code{read-from-minibuffer}. The keymap used is
209 @code{minibuffer-local-map}, and @code{regexp-history} is used as the
210 history list (@pxref{Minibuffer History, regexp-history}).
212 The optional argument @var{default-value} specifies a default value to
213 return if the user enters null input; it should be a string, or
214 @code{nil} which is equivalent to an empty string.
216 In addition, @code{read-regexp} collects a few useful candidates for
217 input and passes them to @code{read-from-minibuffer}, to make them
218 available to the user as the ``future minibuffer history list''
219 (@pxref{Minibuffer History, future list,, emacs, The GNU Emacs
220 Manual}). These candidates are:
224 The word or symbol at point.
226 The last regexp used in an incremental search.
228 The last string used in an incremental search.
230 The last string or pattern used in query-replace commands.
233 This function works by calling the @code{read-from-minibuffer}
234 function, after computing the list of defaults as described above.
237 @defvar minibuffer-allow-text-properties
238 If this variable is @code{nil}, then @code{read-from-minibuffer} strips
239 all text properties from the minibuffer input before returning it.
240 This variable also affects @code{read-string}. However,
241 @code{read-no-blanks-input} (see below), as well as
242 @code{read-minibuffer} and related functions (@pxref{Object from
243 Minibuffer,, Reading Lisp Objects With the Minibuffer}), and all
244 functions that do minibuffer input with completion, discard text
245 properties unconditionally, regardless of the value of this variable.
248 @defvar minibuffer-local-map
250 @anchor{Definition of minibuffer-local-map}
251 @c avoid page break at anchor; work around Texinfo deficiency
252 is the default local keymap for reading from the minibuffer. By
253 default, it makes the following bindings:
257 @code{exit-minibuffer}
260 @code{exit-minibuffer}
263 @code{abort-recursive-edit}
267 @code{next-history-element}
271 @code{previous-history-element}
274 @code{next-matching-history-element}
277 @code{previous-matching-history-element}
281 @c In version 18, initial is required
283 @defun read-no-blanks-input prompt &optional initial inherit-input-method
284 This function reads a string from the minibuffer, but does not allow
285 whitespace characters as part of the input: instead, those characters
286 terminate the input. The arguments @var{prompt}, @var{initial}, and
287 @var{inherit-input-method} are used as in @code{read-from-minibuffer}.
289 This is a simplified interface to the @code{read-from-minibuffer}
290 function, and passes the value of the @code{minibuffer-local-ns-map}
291 keymap as the @var{keymap} argument for that function. Since the keymap
292 @code{minibuffer-local-ns-map} does not rebind @kbd{C-q}, it @emph{is}
293 possible to put a space into the string, by quoting it.
295 This function discards text properties, regardless of the value of
296 @code{minibuffer-allow-text-properties}.
300 (read-no-blanks-input @var{prompt} @var{initial})
302 (let (minibuffer-allow-text-properties)
303 (read-from-minibuffer @var{prompt} @var{initial} minibuffer-local-ns-map))
308 @defvar minibuffer-local-ns-map
309 This built-in variable is the keymap used as the minibuffer local keymap
310 in the function @code{read-no-blanks-input}. By default, it makes the
311 following bindings, in addition to those of @code{minibuffer-local-map}:
315 @cindex @key{SPC} in minibuffer
316 @code{exit-minibuffer}
319 @cindex @key{TAB} in minibuffer
320 @code{exit-minibuffer}
323 @cindex @kbd{?} in minibuffer
324 @code{self-insert-and-exit}
328 @node Object from Minibuffer
329 @section Reading Lisp Objects with the Minibuffer
331 This section describes functions for reading Lisp objects with the
334 @defun read-minibuffer prompt &optional initial
335 This function reads a Lisp object using the minibuffer, and returns it
336 without evaluating it. The arguments @var{prompt} and @var{initial} are
337 used as in @code{read-from-minibuffer}.
339 This is a simplified interface to the
340 @code{read-from-minibuffer} function:
344 (read-minibuffer @var{prompt} @var{initial})
346 (let (minibuffer-allow-text-properties)
347 (read-from-minibuffer @var{prompt} @var{initial} nil t))
351 Here is an example in which we supply the string @code{"(testing)"} as
357 "Enter an expression: " (format "%s" '(testing)))
359 ;; @r{Here is how the minibuffer is displayed:}
363 ---------- Buffer: Minibuffer ----------
364 Enter an expression: (testing)@point{}
365 ---------- Buffer: Minibuffer ----------
370 The user can type @key{RET} immediately to use the initial input as a
371 default, or can edit the input.
374 @defun eval-minibuffer prompt &optional initial
375 This function reads a Lisp expression using the minibuffer, evaluates
376 it, then returns the result. The arguments @var{prompt} and
377 @var{initial} are used as in @code{read-from-minibuffer}.
379 This function simply evaluates the result of a call to
380 @code{read-minibuffer}:
384 (eval-minibuffer @var{prompt} @var{initial})
386 (eval (read-minibuffer @var{prompt} @var{initial}))
391 @defun edit-and-eval-command prompt form
392 This function reads a Lisp expression in the minibuffer, and then
393 evaluates it. The difference between this command and
394 @code{eval-minibuffer} is that here the initial @var{form} is not
395 optional and it is treated as a Lisp object to be converted to printed
396 representation rather than as a string of text. It is printed with
397 @code{prin1}, so if it is a string, double-quote characters (@samp{"})
398 appear in the initial text. @xref{Output Functions}.
400 The first thing @code{edit-and-eval-command} does is to activate the
401 minibuffer with @var{prompt} as the prompt. Then it inserts the printed
402 representation of @var{form} in the minibuffer, and lets the user edit it.
403 When the user exits the minibuffer, the edited text is read with
404 @code{read} and then evaluated. The resulting value becomes the value
405 of @code{edit-and-eval-command}.
407 In the following example, we offer the user an expression with initial
408 text which is a valid form already:
412 (edit-and-eval-command "Please edit: " '(forward-word 1))
414 ;; @r{After evaluation of the preceding expression,}
415 ;; @r{the following appears in the minibuffer:}
419 ---------- Buffer: Minibuffer ----------
420 Please edit: (forward-word 1)@point{}
421 ---------- Buffer: Minibuffer ----------
426 Typing @key{RET} right away would exit the minibuffer and evaluate the
427 expression, thus moving point forward one word.
428 @code{edit-and-eval-command} returns @code{nil} in this example.
431 @node Minibuffer History
432 @section Minibuffer History
433 @cindex minibuffer history
436 A @dfn{minibuffer history list} records previous minibuffer inputs so
437 the user can reuse them conveniently. A history list is actually a
438 symbol, not a list; it is a variable whose value is a list of strings
439 (previous inputs), most recent first.
441 There are many separate history lists, used for different kinds of
442 inputs. It's the Lisp programmer's job to specify the right history
443 list for each use of the minibuffer.
445 You specify the history list with the optional @var{hist} argument
446 to either @code{read-from-minibuffer} or @code{completing-read}. Here
447 are the possible values for it:
451 Use @var{variable} (a symbol) as the history list.
453 @item (@var{variable} . @var{startpos})
454 Use @var{variable} (a symbol) as the history list, and assume that the
455 initial history position is @var{startpos} (a nonnegative integer).
457 Specifying 0 for @var{startpos} is equivalent to just specifying the
458 symbol @var{variable}. @code{previous-history-element} will display
459 the most recent element of the history list in the minibuffer. If you
460 specify a positive @var{startpos}, the minibuffer history functions
461 behave as if @code{(elt @var{variable} (1- @var{STARTPOS}))} were the
462 history element currently shown in the minibuffer.
464 For consistency, you should also specify that element of the history
465 as the initial minibuffer contents, using the @var{initial} argument
466 to the minibuffer input function (@pxref{Initial Input}).
469 If you don't specify @var{hist}, then the default history list
470 @code{minibuffer-history} is used. For other standard history lists,
471 see below. You can also create your own history list variable; just
472 initialize it to @code{nil} before the first use.
474 Both @code{read-from-minibuffer} and @code{completing-read} add new
475 elements to the history list automatically, and provide commands to
476 allow the user to reuse items on the list. The only thing your program
477 needs to do to use a history list is to initialize it and to pass its
478 name to the input functions when you wish. But it is safe to modify the
479 list by hand when the minibuffer input functions are not using it.
481 Emacs functions that add a new element to a history list can also
482 delete old elements if the list gets too long. The variable
483 @code{history-length} specifies the maximum length for most history
484 lists. To specify a different maximum length for a particular history
485 list, put the length in the @code{history-length} property of the
486 history list symbol. The variable @code{history-delete-duplicates}
487 specifies whether to delete duplicates in history.
489 @defun add-to-history history-var newelt &optional maxelt keep-all
490 This function adds a new element @var{newelt}, if it isn't the empty
491 string, to the history list stored in the variable @var{history-var},
492 and returns the updated history list. It limits the list length to
493 the value of @var{maxelt} (if non-@code{nil}) or @code{history-length}
494 (described below). The possible values of @var{maxelt} have the same
495 meaning as the values of @code{history-length}.
497 Normally, @code{add-to-history} removes duplicate members from the
498 history list if @code{history-delete-duplicates} is non-@code{nil}.
499 However, if @var{keep-all} is non-@code{nil}, that says not to remove
500 duplicates, and to add @var{newelt} to the list even if it is empty.
503 @defvar history-add-new-input
504 If the value of this variable is @code{nil}, standard functions that
505 read from the minibuffer don't add new elements to the history list.
506 This lets Lisp programs explicitly manage input history by using
507 @code{add-to-history}. By default, @code{history-add-new-input} is
508 set to a non-@code{nil} value.
511 @defopt history-length
512 The value of this variable specifies the maximum length for all
513 history lists that don't specify their own maximum lengths. If the
514 value is @code{t}, that means there no maximum (don't delete old
515 elements). The value of @code{history-length} property of the history
516 list variable's symbol, if set, overrides this variable for that
517 particular history list.
520 @defopt history-delete-duplicates
521 If the value of this variable is @code{t}, that means when adding a
522 new history element, all previous identical elements are deleted.
525 Here are some of the standard minibuffer history list variables:
527 @defvar minibuffer-history
528 The default history list for minibuffer history input.
531 @defvar query-replace-history
532 A history list for arguments to @code{query-replace} (and similar
533 arguments to other commands).
536 @defvar file-name-history
537 A history list for file-name arguments.
540 @defvar buffer-name-history
541 A history list for buffer-name arguments.
544 @defvar regexp-history
545 A history list for regular expression arguments.
548 @defvar extended-command-history
549 A history list for arguments that are names of extended commands.
552 @defvar shell-command-history
553 A history list for arguments that are shell commands.
556 @defvar read-expression-history
557 A history list for arguments that are Lisp expressions to evaluate.
561 @section Initial Input
563 Several of the functions for minibuffer input have an argument called
564 @var{initial} or @var{initial-contents}. This is a mostly-deprecated
565 feature for specifying that the minibuffer should start out with
566 certain text, instead of empty as usual.
568 If @var{initial} is a string, the minibuffer starts out containing the
569 text of the string, with point at the end, when the user starts to
570 edit the text. If the user simply types @key{RET} to exit the
571 minibuffer, it will use the initial input string to determine the
574 @strong{We discourage use of a non-@code{nil} value for
575 @var{initial}}, because initial input is an intrusive interface.
576 History lists and default values provide a much more convenient method
577 to offer useful default inputs to the user.
579 There is just one situation where you should specify a string for an
580 @var{initial} argument. This is when you specify a cons cell for the
581 @var{hist} or @var{history} argument. @xref{Minibuffer History}.
583 @var{initial} can also be a cons cell of the form @code{(@var{string}
584 . @var{position})}. This means to insert @var{string} in the
585 minibuffer but put point at @var{position} within the string's text.
587 As a historical accident, @var{position} was implemented
588 inconsistently in different functions. In @code{completing-read},
589 @var{position}'s value is interpreted as origin-zero; that is, a value
590 of 0 means the beginning of the string, 1 means after the first
591 character, etc. In @code{read-minibuffer}, and the other
592 non-completion minibuffer input functions that support this argument,
593 1 means the beginning of the string 2 means after the first character,
596 Use of a cons cell as the value for @var{initial} arguments is
597 deprecated in user code.
603 @dfn{Completion} is a feature that fills in the rest of a name
604 starting from an abbreviation for it. Completion works by comparing the
605 user's input against a list of valid names and determining how much of
606 the name is determined uniquely by what the user has typed. For
607 example, when you type @kbd{C-x b} (@code{switch-to-buffer}) and then
608 type the first few letters of the name of the buffer to which you wish
609 to switch, and then type @key{TAB} (@code{minibuffer-complete}), Emacs
610 extends the name as far as it can.
612 Standard Emacs commands offer completion for names of symbols, files,
613 buffers, and processes; with the functions in this section, you can
614 implement completion for other kinds of names.
616 The @code{try-completion} function is the basic primitive for
617 completion: it returns the longest determined completion of a given
618 initial string, with a given set of strings to match against.
620 The function @code{completing-read} provides a higher-level interface
621 for completion. A call to @code{completing-read} specifies how to
622 determine the list of valid names. The function then activates the
623 minibuffer with a local keymap that binds a few keys to commands useful
624 for completion. Other functions provide convenient simple interfaces
625 for reading certain kinds of names with completion.
628 * Basic Completion:: Low-level functions for completing strings.
629 (These are too low level to use the minibuffer.)
630 * Minibuffer Completion:: Invoking the minibuffer with completion.
631 * Completion Commands:: Minibuffer commands that do completion.
632 * High-Level Completion:: Convenient special cases of completion
633 (reading buffer name, file name, etc.)
634 * Reading File Names:: Using completion to read file names and
636 * Completion Styles:: Specifying rules for performing completion.
637 * Programmed Completion:: Writing your own completion-function.
640 @node Basic Completion
641 @subsection Basic Completion Functions
643 The completion functions @code{try-completion},
644 @code{all-completions} and @code{test-completion} have nothing in
645 themselves to do with minibuffers. We describe them in this chapter
646 so as to keep them near the higher-level completion features that do
649 If you store a completion alist in a variable, you should mark the
650 variable as ``risky'' with a non-@code{nil}
651 @code{risky-local-variable} property.
653 @defun try-completion string collection &optional predicate
654 This function returns the longest common substring of all possible
655 completions of @var{string} in @var{collection}. The value of
656 @var{collection} must be a list of strings or symbols, an alist, an
657 obarray, a hash table, or a function that implements a virtual set of
660 Completion compares @var{string} against each of the permissible
661 completions specified by @var{collection}; if the beginning of the
662 permissible completion equals @var{string}, it matches. If no permissible
663 completions match, @code{try-completion} returns @code{nil}. If only
664 one permissible completion matches, and the match is exact, then
665 @code{try-completion} returns @code{t}. Otherwise, the value is the
666 longest initial sequence common to all the permissible completions that
669 If @var{collection} is an alist (@pxref{Association Lists}), the
670 permissible completions are the elements of the alist that are either
671 strings, symbols, or conses whose @sc{car} is a string or symbol.
672 Symbols are converted to strings using @code{symbol-name}. Other
673 elements of the alist are ignored. (Remember that in Emacs Lisp, the
674 elements of alists do not @emph{have} to be conses.) In particular, a
675 list of strings or symbols is allowed, even though we usually do not
676 think of such lists as alists.
678 @cindex obarray in completion
679 If @var{collection} is an obarray (@pxref{Creating Symbols}), the names
680 of all symbols in the obarray form the set of permissible completions. The
681 global variable @code{obarray} holds an obarray containing the names of
682 all interned Lisp symbols.
684 Note that the only valid way to make a new obarray is to create it
685 empty and then add symbols to it one by one using @code{intern}.
686 Also, you cannot intern a given symbol in more than one obarray.
688 If @var{collection} is a hash table, then the keys that are strings
689 are the possible completions. Other keys are ignored.
691 You can also use a symbol that is a function as @var{collection}. Then
692 the function is solely responsible for performing completion;
693 @code{try-completion} returns whatever this function returns. The
694 function is called with three arguments: @var{string}, @var{predicate}
695 and @code{nil}. (The reason for the third argument is so that the same
696 function can be used in @code{all-completions} and do the appropriate
697 thing in either case.) @xref{Programmed Completion}.
699 If the argument @var{predicate} is non-@code{nil}, then it must be a
700 function of one argument, unless @var{collection} is a hash table, in
701 which case it should be a function of two arguments. It is used to
702 test each possible match, and the match is accepted only if
703 @var{predicate} returns non-@code{nil}. The argument given to
704 @var{predicate} is either a string or a cons cell (the @sc{car} of
705 which is a string) from the alist, or a symbol (@emph{not} a symbol
706 name) from the obarray. If @var{collection} is a hash table,
707 @var{predicate} is called with two arguments, the string key and the
710 In addition, to be acceptable, a completion must also match all the
711 regular expressions in @code{completion-regexp-list}. (Unless
712 @var{collection} is a function, in which case that function has to
713 handle @code{completion-regexp-list} itself.)
715 In the first of the following examples, the string @samp{foo} is
716 matched by three of the alist @sc{car}s. All of the matches begin with
717 the characters @samp{fooba}, so that is the result. In the second
718 example, there is only one possible match, and it is exact, so the value
725 '(("foobar1" 1) ("barfoo" 2) ("foobaz" 3) ("foobar2" 4)))
730 (try-completion "foo" '(("barfoo" 2) ("foo" 3)))
735 In the following example, numerous symbols begin with the characters
736 @samp{forw}, and all of them begin with the word @samp{forward}. In
737 most of the symbols, this is followed with a @samp{-}, but not in all,
738 so no more than @samp{forward} can be completed.
742 (try-completion "forw" obarray)
747 Finally, in the following example, only two of the three possible
748 matches pass the predicate @code{test} (the string @samp{foobaz} is
749 too short). Both of those begin with the string @samp{foobar}.
754 (> (length (car s)) 6))
760 '(("foobar1" 1) ("barfoo" 2) ("foobaz" 3) ("foobar2" 4))
767 @defun all-completions string collection &optional predicate nospace
768 This function returns a list of all possible completions of
769 @var{string}. The arguments to this function (aside from
770 @var{nospace}) are the same as those of @code{try-completion}. Also,
771 this function uses @code{completion-regexp-list} in the same way that
772 @code{try-completion} does. The optional argument @var{nospace} only
773 matters if @var{string} is the empty string. In that case, if
774 @var{nospace} is non-@code{nil}, completions that start with a space
777 If @var{collection} is a function, it is called with three arguments:
778 @var{string}, @var{predicate} and @code{t}; then @code{all-completions}
779 returns whatever the function returns. @xref{Programmed Completion}.
781 Here is an example, using the function @code{test} shown in the
782 example for @code{try-completion}:
787 (> (length (car s)) 6))
794 '(("foobar1" 1) ("barfoo" 2) ("foobaz" 3) ("foobar2" 4))
796 @result{} ("foobar1" "foobar2")
801 @defun test-completion string collection &optional predicate
802 @anchor{Definition of test-completion}
803 This function returns non-@code{nil} if @var{string} is a valid
804 completion possibility specified by @var{collection} and
805 @var{predicate}. The arguments are the same as in
806 @code{try-completion}. For instance, if @var{collection} is a list of
807 strings, this is true if @var{string} appears in the list and
808 @var{predicate} is satisfied.
810 This function uses @code{completion-regexp-list} in the same
811 way that @code{try-completion} does.
813 If @var{predicate} is non-@code{nil} and if @var{collection} contains
814 several strings that are equal to each other, as determined by
815 @code{compare-strings} according to @code{completion-ignore-case},
816 then @var{predicate} should accept either all or none of them.
817 Otherwise, the return value of @code{test-completion} is essentially
820 If @var{collection} is a function, it is called with three arguments,
821 the values @var{string}, @var{predicate} and @code{lambda}; whatever
822 it returns, @code{test-completion} returns in turn.
825 @defvar completion-ignore-case
826 If the value of this variable is non-@code{nil}, Emacs does not
827 consider case significant in completion. Note, however, that this
828 variable is overridden by @code{read-file-name-completion-ignore-case}
829 within @code{read-file-name} (@pxref{Reading File Names}), and by
830 @code{read-buffer-completion-ignore-case} within @code{read-buffer}
831 (@pxref{High-Level Completion}).
834 @defvar completion-regexp-list
835 This is a list of regular expressions. The completion functions only
836 consider a completion acceptable if it matches all regular expressions
837 in this list, with @code{case-fold-search} (@pxref{Searching and Case})
838 bound to the value of @code{completion-ignore-case}.
841 @defmac lazy-completion-table var fun
842 This macro provides a way to initialize the variable @var{var} as a
843 collection for completion in a lazy way, not computing its actual
844 contents until they are first needed. You use this macro to produce a
845 value that you store in @var{var}. The actual computation of the
846 proper value is done the first time you do completion using @var{var}.
847 It is done by calling @var{fun} with no arguments. The
848 value @var{fun} returns becomes the permanent value of @var{var}.
850 Here is an example of use:
853 (defvar foo (lazy-completion-table foo make-my-alist))
857 @node Minibuffer Completion
858 @subsection Completion and the Minibuffer
859 @cindex minibuffer completion
860 @cindex reading from minibuffer with completion
862 This section describes the basic interface for reading from the
863 minibuffer with completion.
865 @defun completing-read prompt collection &optional predicate require-match initial hist default inherit-input-method
866 This function reads a string in the minibuffer, assisting the user by
867 providing completion. It activates the minibuffer with prompt
868 @var{prompt}, which must be a string.
870 The actual completion is done by passing @var{collection} and
871 @var{predicate} to the function @code{try-completion}. This happens
872 in certain commands bound in the local keymaps used for completion.
873 Some of these commands also call @code{test-completion}. Thus, if
874 @var{predicate} is non-@code{nil}, it should be compatible with
875 @var{collection} and @code{completion-ignore-case}. @xref{Definition
878 The value of the optional argument @var{require-match} determines how
879 the user may exit the minibuffer:
883 If @code{nil}, the usual minibuffer exit commands work regardless of
884 the input in the minibuffer.
887 If @code{t}, the usual minibuffer exit commands won't exit unless the
888 input completes to an element of @var{collection}.
891 If @code{confirm}, the user can exit with any input, but is asked for
892 confirmation if the input is not an element of @var{collection}.
895 If @code{confirm-after-completion}, the user can exit with any input,
896 but is asked for confirmation if the preceding command was a
897 completion command (i.e., one of the commands in
898 @code{minibuffer-confirm-exit-commands}) and the resulting input is
899 not an element of @var{collection}. @xref{Completion Commands}.
902 Any other value of @var{require-match} behaves like @code{t}, except
903 that the exit commands won't exit if it performs completion.
906 However, empty input is always permitted, regardless of the value of
907 @var{require-match}; in that case, @code{completing-read} returns the
908 first element of @var{default}, if it is a list; @code{""}, if
909 @var{default} is @code{nil}; or @var{default}. The string or strings
910 in @var{default} are also available to the user through the history
913 The function @code{completing-read} uses
914 @code{minibuffer-local-completion-map} as the keymap if
915 @var{require-match} is @code{nil}, and uses
916 @code{minibuffer-local-must-match-map} if @var{require-match} is
917 non-@code{nil}. @xref{Completion Commands}.
919 The argument @var{hist} specifies which history list variable to use for
920 saving the input and for minibuffer history commands. It defaults to
921 @code{minibuffer-history}. @xref{Minibuffer History}.
923 The argument @var{initial} is mostly deprecated; we recommend using a
924 non-@code{nil} value only in conjunction with specifying a cons cell
925 for @var{hist}. @xref{Initial Input}. For default input, use
926 @var{default} instead.
928 If the argument @var{inherit-input-method} is non-@code{nil}, then the
929 minibuffer inherits the current input method (@pxref{Input
930 Methods}) and the setting of @code{enable-multibyte-characters}
931 (@pxref{Text Representations}) from whichever buffer was current before
932 entering the minibuffer.
934 If the built-in variable @code{completion-ignore-case} is
935 non-@code{nil}, completion ignores case when comparing the input
936 against the possible matches. @xref{Basic Completion}. In this mode
937 of operation, @var{predicate} must also ignore case, or you will get
940 Here's an example of using @code{completing-read}:
946 '(("foobar1" 1) ("barfoo" 2) ("foobaz" 3) ("foobar2" 4))
951 ;; @r{After evaluation of the preceding expression,}
952 ;; @r{the following appears in the minibuffer:}
954 ---------- Buffer: Minibuffer ----------
955 Complete a foo: fo@point{}
956 ---------- Buffer: Minibuffer ----------
961 If the user then types @kbd{@key{DEL} @key{DEL} b @key{RET}},
962 @code{completing-read} returns @code{barfoo}.
964 The @code{completing-read} function binds variables to pass
965 information to the commands that actually do completion.
966 They are described in the following section.
969 @node Completion Commands
970 @subsection Minibuffer Commands that Do Completion
972 This section describes the keymaps, commands and user options used
973 in the minibuffer to do completion.
975 @defvar minibuffer-completion-table
976 The value of this variable is the collection used for completion in
977 the minibuffer. This is the global variable that contains what
978 @code{completing-read} passes to @code{try-completion}. It is used by
979 minibuffer completion commands such as @code{minibuffer-complete-word}.
982 @defvar minibuffer-completion-predicate
983 This variable's value is the predicate that @code{completing-read}
984 passes to @code{try-completion}. The variable is also used by the other
985 minibuffer completion functions.
988 @defvar minibuffer-completion-confirm
989 This variable determines whether Emacs asks for confirmation before
990 exiting the minibuffer; @code{completing-read} binds this variable,
991 and the function @code{minibuffer-complete-and-exit} checks the value
992 before exiting. If the value is @code{nil}, confirmation is not
993 required. If the value is @code{confirm}, the user may exit with an
994 input that is not a valid completion alternative, but Emacs asks for
995 confirmation. If the value is @code{confirm-after-completion}, the
996 user may exit with an input that is not a valid completion
997 alternative, but Emacs asks for confirmation if the user submitted the
998 input right after any of the completion commands in
999 @code{minibuffer-confirm-exit-commands}.
1002 @defvar minibuffer-confirm-exit-commands
1003 This variable holds a list of commands that cause Emacs to ask for
1004 confirmation before exiting the minibuffer, if the @var{require-match}
1005 argument to @code{completing-read} is @code{confirm-after-completion}.
1006 The confirmation is requested if the user attempts to exit the
1007 minibuffer immediately after calling any command in this list.
1010 @deffn Command minibuffer-complete-word
1011 This function completes the minibuffer contents by at most a single
1012 word. Even if the minibuffer contents have only one completion,
1013 @code{minibuffer-complete-word} does not add any characters beyond the
1014 first character that is not a word constituent. @xref{Syntax Tables}.
1017 @deffn Command minibuffer-complete
1018 This function completes the minibuffer contents as far as possible.
1021 @deffn Command minibuffer-complete-and-exit
1022 This function completes the minibuffer contents, and exits if
1023 confirmation is not required, i.e., if
1024 @code{minibuffer-completion-confirm} is @code{nil}. If confirmation
1025 @emph{is} required, it is given by repeating this command
1026 immediately---the command is programmed to work without confirmation
1027 when run twice in succession.
1030 @deffn Command minibuffer-completion-help
1031 This function creates a list of the possible completions of the
1032 current minibuffer contents. It works by calling @code{all-completions}
1033 using the value of the variable @code{minibuffer-completion-table} as
1034 the @var{collection} argument, and the value of
1035 @code{minibuffer-completion-predicate} as the @var{predicate} argument.
1036 The list of completions is displayed as text in a buffer named
1037 @samp{*Completions*}.
1040 @defun display-completion-list completions &optional common-substring
1041 This function displays @var{completions} to the stream in
1042 @code{standard-output}, usually a buffer. (@xref{Read and Print}, for more
1043 information about streams.) The argument @var{completions} is normally
1044 a list of completions just returned by @code{all-completions}, but it
1045 does not have to be. Each element may be a symbol or a string, either
1046 of which is simply printed. It can also be a list of two strings,
1047 which is printed as if the strings were concatenated. The first of
1048 the two strings is the actual completion, the second string serves as
1051 The argument @var{common-substring} is the prefix that is common to
1052 all the completions. With normal Emacs completion, it is usually the
1053 same as the string that was completed. @code{display-completion-list}
1054 uses this to highlight text in the completion list for better visual
1055 feedback. This is not needed in the minibuffer; for minibuffer
1056 completion, you can pass @code{nil}.
1058 This function is called by @code{minibuffer-completion-help}. The
1059 most common way to use it is together with
1060 @code{with-output-to-temp-buffer}, like this:
1063 (with-output-to-temp-buffer "*Completions*"
1064 (display-completion-list
1065 (all-completions (buffer-string) my-alist)
1070 @defopt completion-auto-help
1071 If this variable is non-@code{nil}, the completion commands
1072 automatically display a list of possible completions whenever nothing
1073 can be completed because the next character is not uniquely determined.
1076 @defvar minibuffer-local-completion-map
1077 @code{completing-read} uses this value as the local keymap when an
1078 exact match of one of the completions is not required. By default, this
1079 keymap makes the following bindings:
1083 @code{minibuffer-completion-help}
1086 @code{minibuffer-complete-word}
1089 @code{minibuffer-complete}
1093 with other characters bound as in @code{minibuffer-local-map}
1094 (@pxref{Definition of minibuffer-local-map}).
1097 @defvar minibuffer-local-must-match-map
1098 @code{completing-read} uses this value as the local keymap when an
1099 exact match of one of the completions is required. Therefore, no keys
1100 are bound to @code{exit-minibuffer}, the command that exits the
1101 minibuffer unconditionally. By default, this keymap makes the following
1106 @code{minibuffer-completion-help}
1109 @code{minibuffer-complete-word}
1112 @code{minibuffer-complete}
1115 @code{minibuffer-complete-and-exit}
1118 @code{minibuffer-complete-and-exit}
1122 with other characters bound as in @code{minibuffer-local-map}.
1125 @defvar minibuffer-local-filename-completion-map
1126 This is like @code{minibuffer-local-completion-map}
1127 except that it does not bind @key{SPC}. This keymap is used by the
1128 function @code{read-file-name}.
1131 @defvar minibuffer-local-filename-must-match-map
1132 This is like @code{minibuffer-local-must-match-map}
1133 except that it does not bind @key{SPC}. This keymap is used by the
1134 function @code{read-file-name}.
1137 @node High-Level Completion
1138 @subsection High-Level Completion Functions
1140 This section describes the higher-level convenient functions for
1141 reading certain sorts of names with completion.
1143 In most cases, you should not call these functions in the middle of a
1144 Lisp function. When possible, do all minibuffer input as part of
1145 reading the arguments for a command, in the @code{interactive}
1146 specification. @xref{Defining Commands}.
1148 @defun read-buffer prompt &optional default require-match
1149 This function reads the name of a buffer and returns it as a string.
1150 The argument @var{default} is the default name to use, the value to
1151 return if the user exits with an empty minibuffer. If non-@code{nil},
1152 it should be a string, a list of strings, or a buffer. If it is
1153 a list, the default value is the first element of this list. It is
1154 mentioned in the prompt, but is not inserted in the minibuffer as
1157 The argument @var{prompt} should be a string ending with a colon and a
1158 space. If @var{default} is non-@code{nil}, the function inserts it in
1159 @var{prompt} before the colon to follow the convention for reading from
1160 the minibuffer with a default value (@pxref{Programming Tips}).
1162 The optional argument @var{require-match} has the same meaning as in
1163 @code{completing-read}. @xref{Minibuffer Completion}.
1165 In the following example, the user enters @samp{minibuffer.t}, and
1166 then types @key{RET}. The argument @var{require-match} is @code{t},
1167 and the only buffer name starting with the given input is
1168 @samp{minibuffer.texi}, so that name is the value.
1171 (read-buffer "Buffer name: " "foo" t)
1173 ;; @r{After evaluation of the preceding expression,}
1174 ;; @r{the following prompt appears,}
1175 ;; @r{with an empty minibuffer:}
1179 ---------- Buffer: Minibuffer ----------
1180 Buffer name (default foo): @point{}
1181 ---------- Buffer: Minibuffer ----------
1185 ;; @r{The user types @kbd{minibuffer.t @key{RET}}.}
1186 @result{} "minibuffer.texi"
1191 @defopt read-buffer-function
1192 This variable specifies how to read buffer names. For example, if you
1193 set this variable to @code{iswitchb-read-buffer}, all Emacs commands
1194 that call @code{read-buffer} to read a buffer name will actually use the
1195 @code{iswitchb} package to read it.
1198 @defopt read-buffer-completion-ignore-case
1199 If this variable is non-@code{nil}, @code{read-buffer} ignores case
1200 when performing completion.
1203 @defun read-command prompt &optional default
1204 This function reads the name of a command and returns it as a Lisp
1205 symbol. The argument @var{prompt} is used as in
1206 @code{read-from-minibuffer}. Recall that a command is anything for
1207 which @code{commandp} returns @code{t}, and a command name is a symbol
1208 for which @code{commandp} returns @code{t}. @xref{Interactive Call}.
1210 The argument @var{default} specifies what to return if the user enters
1211 null input. It can be a symbol, a string or a list of strings. If it
1212 is a string, @code{read-command} interns it before returning it.
1213 If it is a list, @code{read-command} returns the first element of this list.
1214 If @var{default} is @code{nil}, that means no default has been
1215 specified; then if the user enters null input, the return value is
1216 @code{(intern "")}, that is, a symbol whose name is an empty string.
1219 (read-command "Command name? ")
1222 ;; @r{After evaluation of the preceding expression,}
1223 ;; @r{the following prompt appears with an empty minibuffer:}
1227 ---------- Buffer: Minibuffer ----------
1229 ---------- Buffer: Minibuffer ----------
1234 If the user types @kbd{forward-c @key{RET}}, then this function returns
1235 @code{forward-char}.
1237 The @code{read-command} function is a simplified interface to
1238 @code{completing-read}. It uses the variable @code{obarray} so as to
1239 complete in the set of extant Lisp symbols, and it uses the
1240 @code{commandp} predicate so as to accept only command names:
1242 @cindex @code{commandp} example
1245 (read-command @var{prompt})
1247 (intern (completing-read @var{prompt} obarray
1253 @defun read-variable prompt &optional default
1254 @anchor{Definition of read-variable}
1255 This function reads the name of a user variable and returns it as a
1258 The argument @var{default} specifies the default value to return if
1259 the user enters null input. It can be a symbol, a string, or a list
1260 of strings. If it is a string, @code{read-variable} interns it to
1261 make the default value. If it is a list, @code{read-variable} interns
1262 the first element. If @var{default} is @code{nil}, that means no
1263 default has been specified; then if the user enters null input, the
1264 return value is @code{(intern "")}.
1268 (read-variable "Variable name? ")
1270 ;; @r{After evaluation of the preceding expression,}
1271 ;; @r{the following prompt appears,}
1272 ;; @r{with an empty minibuffer:}
1276 ---------- Buffer: Minibuffer ----------
1277 Variable name? @point{}
1278 ---------- Buffer: Minibuffer ----------
1283 If the user then types @kbd{fill-p @key{RET}}, @code{read-variable}
1284 returns @code{fill-prefix}.
1286 In general, @code{read-variable} is similar to @code{read-command},
1287 but uses the predicate @code{user-variable-p} instead of
1290 @cindex @code{user-variable-p} example
1293 (read-variable @var{prompt})
1296 (completing-read @var{prompt} obarray
1297 'user-variable-p t nil))
1302 @deffn Command read-color &optional prompt convert allow-empty display
1303 This function reads a string that is a color specification, either the
1304 color's name or an RGB hex value such as @code{#RRRGGGBBB}. It
1305 prompts with @var{prompt} (default: @code{"Color (name or #R+G+B+):"})
1306 and provides completion for color names, but not for hex RGB values.
1307 In addition to names of standard colors, completion candidates include
1308 the foreground and background colors at point.
1310 Valid RGB values are described in @ref{Color Names}.
1312 The function's return value is the color name typed by the user in the
1313 minibuffer. However, when called interactively or if the optional
1314 argument @var{convert} is non-@code{nil}, it converts the name into
1315 the color's RGB value and returns that value as a string. If an
1316 invalid color name was specified, this function signals an error,
1317 except that empty color names are allowed when @code{allow-empty} is
1318 non-@code{nil} and the user enters null input.
1320 Interactively, or when @var{display} is non-@code{nil}, the return
1321 value is also displayed in the echo area.
1324 See also the functions @code{read-coding-system} and
1325 @code{read-non-nil-coding-system}, in @ref{User-Chosen Coding Systems},
1326 and @code{read-input-method-name}, in @ref{Input Methods}.
1328 @node Reading File Names
1329 @subsection Reading File Names
1330 @cindex read file names
1331 @cindex prompt for file name
1333 The high-level completion functions @code{read-file-name},
1334 @code{read-directory-name}, and @code{read-shell-command} are designed
1335 to read file names, directory names, and shell commands respectively.
1336 They provide special features, including automatic insertion of the
1339 @defun read-file-name prompt &optional directory default require-match initial predicate
1340 This function reads a file name in the minibuffer, prompting with
1341 @var{prompt} and providing completion.
1343 The optional argument @var{require-match} has the same meaning as in
1344 @code{completing-read}. @xref{Minibuffer Completion}.
1346 @code{read-file-name} uses
1347 @code{minibuffer-local-filename-completion-map} as the keymap if
1348 @var{require-match} is @code{nil}, and uses
1349 @code{minibuffer-local-filename-must-match-map} if @var{require-match}
1350 is non-@code{nil}. @xref{Completion Commands}.
1352 The argument @var{directory} specifies the directory to use for
1353 completion of relative file names. It should be an absolute directory
1354 name. If @code{insert-default-directory} is non-@code{nil},
1355 @var{directory} is also inserted in the minibuffer as initial input.
1356 It defaults to the current buffer's value of @code{default-directory}.
1359 If you specify @var{initial}, that is an initial file name to insert
1360 in the buffer (after @var{directory}, if that is inserted). In this
1361 case, point goes at the beginning of @var{initial}. The default for
1362 @var{initial} is @code{nil}---don't insert any file name. To see what
1363 @var{initial} does, try the command @kbd{C-x C-v}. @strong{Please
1364 note:} we recommend using @var{default} rather than @var{initial} in
1367 If @var{default} is non-@code{nil}, then the function returns
1368 @var{default} if the user exits the minibuffer with the same non-empty
1369 contents that @code{read-file-name} inserted initially. The initial
1370 minibuffer contents are always non-empty if
1371 @code{insert-default-directory} is non-@code{nil}, as it is by
1372 default. @var{default} is not checked for validity, regardless of the
1373 value of @var{require-match}. However, if @var{require-match} is
1374 non-@code{nil}, the initial minibuffer contents should be a valid file
1375 (or directory) name. Otherwise @code{read-file-name} attempts
1376 completion if the user exits without any editing, and does not return
1377 @var{default}. @var{default} is also available through the history
1380 If @var{default} is @code{nil}, @code{read-file-name} tries to find a
1381 substitute default to use in its place, which it treats in exactly the
1382 same way as if it had been specified explicitly. If @var{default} is
1383 @code{nil}, but @var{initial} is non-@code{nil}, then the default is
1384 the absolute file name obtained from @var{directory} and
1385 @var{initial}. If both @var{default} and @var{initial} are @code{nil}
1386 and the buffer is visiting a file, @code{read-file-name} uses the
1387 absolute file name of that file as default. If the buffer is not
1388 visiting a file, then there is no default. In that case, if the user
1389 types @key{RET} without any editing, @code{read-file-name} simply
1390 returns the pre-inserted contents of the minibuffer.
1392 If the user types @key{RET} in an empty minibuffer, this function
1393 returns an empty string, regardless of the value of
1394 @var{require-match}. This is, for instance, how the user can make the
1395 current buffer visit no file using @code{M-x set-visited-file-name}.
1397 If @var{predicate} is non-@code{nil}, it specifies a function of one
1398 argument that decides which file names are acceptable completion
1399 possibilities. A file name is an acceptable value if @var{predicate}
1400 returns non-@code{nil} for it.
1402 @code{read-file-name} does not automatically expand file names. You
1403 must call @code{expand-file-name} yourself if an absolute file name is
1410 (read-file-name "The file is ")
1412 ;; @r{After evaluation of the preceding expression,}
1413 ;; @r{the following appears in the minibuffer:}
1417 ---------- Buffer: Minibuffer ----------
1418 The file is /gp/gnu/elisp/@point{}
1419 ---------- Buffer: Minibuffer ----------
1424 Typing @kbd{manual @key{TAB}} results in the following:
1428 ---------- Buffer: Minibuffer ----------
1429 The file is /gp/gnu/elisp/manual.texi@point{}
1430 ---------- Buffer: Minibuffer ----------
1434 @c Wordy to avoid overfull hbox in smallbook mode.
1436 If the user types @key{RET}, @code{read-file-name} returns the file name
1437 as the string @code{"/gp/gnu/elisp/manual.texi"}.
1440 @defvar read-file-name-function
1441 If non-@code{nil}, this should be a function that accepts the same
1442 arguments as @code{read-file-name}. When @code{read-file-name} is
1443 called, it calls this function with the supplied arguments instead of
1444 doing its usual work.
1447 @defopt read-file-name-completion-ignore-case
1448 If this variable is non-@code{nil}, @code{read-file-name} ignores case
1449 when performing completion.
1452 @defun read-directory-name prompt &optional directory default require-match initial
1453 This function is like @code{read-file-name} but allows only directory
1454 names as completion possibilities.
1456 If @var{default} is @code{nil} and @var{initial} is non-@code{nil},
1457 @code{read-directory-name} constructs a substitute default by
1458 combining @var{directory} (or the current buffer's default directory
1459 if @var{directory} is @code{nil}) and @var{initial}. If both
1460 @var{default} and @var{initial} are @code{nil}, this function uses
1461 @var{directory} as substitute default, or the current buffer's default
1462 directory if @var{directory} is @code{nil}.
1465 @defopt insert-default-directory
1466 This variable is used by @code{read-file-name}, and thus, indirectly,
1467 by most commands reading file names. (This includes all commands that
1468 use the code letters @samp{f} or @samp{F} in their interactive form.
1469 @xref{Interactive Codes,, Code Characters for interactive}.) Its
1470 value controls whether @code{read-file-name} starts by placing the
1471 name of the default directory in the minibuffer, plus the initial file
1472 name if any. If the value of this variable is @code{nil}, then
1473 @code{read-file-name} does not place any initial input in the
1474 minibuffer (unless you specify initial input with the @var{initial}
1475 argument). In that case, the default directory is still used for
1476 completion of relative file names, but is not displayed.
1478 If this variable is @code{nil} and the initial minibuffer contents are
1479 empty, the user may have to explicitly fetch the next history element
1480 to access a default value. If the variable is non-@code{nil}, the
1481 initial minibuffer contents are always non-empty and the user can
1482 always request a default value by immediately typing @key{RET} in an
1483 unedited minibuffer. (See above.)
1489 ;; @r{Here the minibuffer starts out with the default directory.}
1490 (let ((insert-default-directory t))
1491 (read-file-name "The file is "))
1495 ---------- Buffer: Minibuffer ----------
1496 The file is ~lewis/manual/@point{}
1497 ---------- Buffer: Minibuffer ----------
1501 ;; @r{Here the minibuffer is empty and only the prompt}
1502 ;; @r{appears on its line.}
1503 (let ((insert-default-directory nil))
1504 (read-file-name "The file is "))
1508 ---------- Buffer: Minibuffer ----------
1509 The file is @point{}
1510 ---------- Buffer: Minibuffer ----------
1515 @defun read-shell-command prompt &optional initial-contents hist &rest args
1516 This function reads a shell command from the minibuffer, prompting
1517 with @var{prompt} and providing intelligent completion. It completes
1518 the first word of the command using candidates that are appropriate
1519 for command names, and the rest of the command words as file names.
1521 This function uses @code{minibuffer-local-shell-command-map} as the
1522 keymap for minibuffer input. The @var{hist} argument specifies the
1523 history list to use; if is omitted or @code{nil}, it defaults to
1524 @code{shell-command-history} (@pxref{Minibuffer History,
1525 shell-command-history}). The optional argument @var{initial-contents}
1526 specifies the initial content of the minibuffer (@pxref{Initial
1527 Input}). The rest of @var{args}, if present, are used as the
1528 @var{default} and @var{inherit-input-method} arguments in
1529 @code{read-from-minibuffer} (@pxref{Text from Minibuffer}).
1532 @defvar minibuffer-local-shell-command-map
1533 This keymap is used by @code{read-shell-command} for completing
1534 command and file names that are part of a shell command.
1537 @node Completion Styles
1538 @subsection Completion Styles
1539 @cindex completion styles
1541 A @dfn{completion style} is a set of rules for generating
1542 completions. The user option @code{completion-styles} stores a list
1543 of completion styles, which are represented by symbols.
1545 @defopt completion-styles
1546 This is a list of completion style symbols to use for performing
1547 completion. Each completion style in this list must be defined in
1548 @code{completion-styles-alist}.
1551 @defvar completion-styles-alist
1552 This variable stores a list of available completion styles. Each
1553 element in the list must have the form @samp{(@var{name}
1554 @var{try-completion} @var{all-completions})}. Here, @var{name} is the
1555 name of the completion style (a symbol), which may be used in
1556 @code{completion-styles-alist} to refer to this style.
1558 @var{try-completion} is the function that does the completion, and
1559 @var{all-completions} is the function that lists the completions.
1560 These functions should accept four arguments: @var{string},
1561 @var{collection}, @var{predicate}, and @var{point}. The @var{string},
1562 @var{collection}, and @var{predicate} arguments have the same meanings
1563 as in @code{try-completion} (@pxref{Basic Completion}), and the
1564 @var{point} argument is the position of point within @var{string}.
1565 Each function should return a non-@code{nil} value if it performed its
1566 job, and @code{nil} if it did not (e.g., if there is no way to
1567 complete @var{string} according to the completion style).
1569 When the user calls a completion command, such as
1570 @code{minibuffer-complete} (@pxref{Completion Commands}), Emacs looks
1571 for the first style listed in @code{completion-styles} and calls its
1572 @var{try-completion} function. If this function returns @code{nil},
1573 Emacs moves to the next completion style listed in
1574 @code{completion-styles} and calls its @var{try-completion} function,
1575 and so on until one of the @var{try-completion} functions successfully
1576 performs completion and returns a non-@code{nil} value. A similar
1577 procedure is used for listing completions, via the
1578 @var{all-completions} functions.
1581 By default, @code{completion-styles-alist} contains four pre-defined
1582 completion styles: @code{basic}, a basic completion style;
1583 @code{partial-completion}, which does partial completion (completing
1584 each word in the input separately); @code{emacs22}, which performs
1585 completion according to the rules used in Emacs 22; and
1586 @code{emacs21}, which performs completion according to the rules used
1589 @node Programmed Completion
1590 @subsection Programmed Completion
1591 @cindex programmed completion
1593 Sometimes it is not possible to create an alist or an obarray
1594 containing all the intended possible completions. In such a case, you
1595 can supply your own function to compute the completion of a given string.
1596 This is called @dfn{programmed completion}.
1598 To use this feature, pass a symbol with a function definition as the
1599 @var{collection} argument to @code{completing-read}. The function
1600 @code{completing-read} arranges to pass your completion function along
1601 to @code{try-completion} and @code{all-completions}, which will then let
1602 your function do all the work.
1604 The completion function should accept three arguments:
1608 The string to be completed.
1611 The predicate function to filter possible matches, or @code{nil} if
1612 none. Your function should call the predicate for each possible match,
1613 and ignore the possible match if the predicate returns @code{nil}.
1616 A flag specifying the type of operation.
1619 There are three flag values for three operations:
1623 @code{nil} specifies @code{try-completion}. The completion function
1624 should return the completion of the specified string, or @code{t} if the
1625 string is a unique and exact match already, or @code{nil} if the string
1626 matches no possibility.
1628 If the string is an exact match for one possibility, but also matches
1629 other longer possibilities, the function should return the string, not
1633 @code{t} specifies @code{all-completions}. The completion function
1634 should return a list of all possible completions of the specified
1638 @code{lambda} specifies @code{test-completion}. The completion
1639 function should return @code{t} if the specified string is an exact
1640 match for some possibility; @code{nil} otherwise.
1643 It would be consistent and clean for completion functions to allow
1644 lambda expressions (lists that are functions) as well as function
1645 symbols as @var{collection}, but this is impossible. Lists as
1646 completion tables already have other meanings, and it would be
1647 unreliable to treat one differently just because it is also a possible
1648 function. So you must arrange for any function you wish to use for
1649 completion to be encapsulated in a symbol.
1651 Emacs uses programmed completion when completing file names.
1652 @xref{File Name Completion}.
1654 @defun completion-table-dynamic function
1655 This function is a convenient way to write a function that can act as
1656 programmed completion function. The argument @var{function} should be
1657 a function that takes one argument, a string, and returns an alist of
1658 possible completions of it. You can think of
1659 @code{completion-table-dynamic} as a transducer between that interface
1660 and the interface for programmed completion functions.
1663 @node Yes-or-No Queries
1664 @section Yes-or-No Queries
1665 @cindex asking the user questions
1666 @cindex querying the user
1667 @cindex yes-or-no questions
1669 This section describes functions used to ask the user a yes-or-no
1670 question. The function @code{y-or-n-p} can be answered with a single
1671 character; it is useful for questions where an inadvertent wrong answer
1672 will not have serious consequences. @code{yes-or-no-p} is suitable for
1673 more momentous questions, since it requires three or four characters to
1676 If either of these functions is called in a command that was invoked
1677 using the mouse---more precisely, if @code{last-nonmenu-event}
1678 (@pxref{Command Loop Info}) is either @code{nil} or a list---then it
1679 uses a dialog box or pop-up menu to ask the question. Otherwise, it
1680 uses keyboard input. You can force use of the mouse or use of keyboard
1681 input by binding @code{last-nonmenu-event} to a suitable value around
1684 Strictly speaking, @code{yes-or-no-p} uses the minibuffer and
1685 @code{y-or-n-p} does not; but it seems best to describe them together.
1687 @defun y-or-n-p prompt
1688 This function asks the user a question, expecting input in the echo
1689 area. It returns @code{t} if the user types @kbd{y}, @code{nil} if the
1690 user types @kbd{n}. This function also accepts @key{SPC} to mean yes
1691 and @key{DEL} to mean no. It accepts @kbd{C-]} to mean ``quit,'' like
1692 @kbd{C-g}, because the question might look like a minibuffer and for
1693 that reason the user might try to use @kbd{C-]} to get out. The answer
1694 is a single character, with no @key{RET} needed to terminate it. Upper
1695 and lower case are equivalent.
1697 ``Asking the question'' means printing @var{prompt} in the echo area,
1698 followed by the string @w{@samp{(y or n) }}. If the input is not one of
1699 the expected answers (@kbd{y}, @kbd{n}, @kbd{@key{SPC}},
1700 @kbd{@key{DEL}}, or something that quits), the function responds
1701 @samp{Please answer y or n.}, and repeats the request.
1703 This function does not actually use the minibuffer, since it does not
1704 allow editing of the answer. It actually uses the echo area (@pxref{The
1705 Echo Area}), which uses the same screen space as the minibuffer. The
1706 cursor moves to the echo area while the question is being asked.
1708 The answers and their meanings, even @samp{y} and @samp{n}, are not
1709 hardwired. The keymap @code{query-replace-map} specifies them.
1710 @xref{Search and Replace}.
1712 In the following example, the user first types @kbd{q}, which is
1713 invalid. At the next prompt the user types @kbd{y}.
1717 (y-or-n-p "Do you need a lift? ")
1719 ;; @r{After evaluation of the preceding expression,}
1720 ;; @r{the following prompt appears in the echo area:}
1724 ---------- Echo area ----------
1725 Do you need a lift? (y or n)
1726 ---------- Echo area ----------
1729 ;; @r{If the user then types @kbd{q}, the following appears:}
1732 ---------- Echo area ----------
1733 Please answer y or n. Do you need a lift? (y or n)
1734 ---------- Echo area ----------
1737 ;; @r{When the user types a valid answer,}
1738 ;; @r{it is displayed after the question:}
1741 ---------- Echo area ----------
1742 Do you need a lift? (y or n) y
1743 ---------- Echo area ----------
1748 We show successive lines of echo area messages, but only one actually
1749 appears on the screen at a time.
1752 @defun y-or-n-p-with-timeout prompt seconds default-value
1753 Like @code{y-or-n-p}, except that if the user fails to answer within
1754 @var{seconds} seconds, this function stops waiting and returns
1755 @var{default-value}. It works by setting up a timer; see @ref{Timers}.
1756 The argument @var{seconds} may be an integer or a floating point number.
1759 @defun yes-or-no-p prompt
1760 This function asks the user a question, expecting input in the
1761 minibuffer. It returns @code{t} if the user enters @samp{yes},
1762 @code{nil} if the user types @samp{no}. The user must type @key{RET} to
1763 finalize the response. Upper and lower case are equivalent.
1765 @code{yes-or-no-p} starts by displaying @var{prompt} in the echo area,
1766 followed by @w{@samp{(yes or no) }}. The user must type one of the
1767 expected responses; otherwise, the function responds @samp{Please answer
1768 yes or no.}, waits about two seconds and repeats the request.
1770 @code{yes-or-no-p} requires more work from the user than
1771 @code{y-or-n-p} and is appropriate for more crucial decisions.
1777 (yes-or-no-p "Do you really want to remove everything? ")
1779 ;; @r{After evaluation of the preceding expression,}
1780 ;; @r{the following prompt appears,}
1781 ;; @r{with an empty minibuffer:}
1785 ---------- Buffer: minibuffer ----------
1786 Do you really want to remove everything? (yes or no)
1787 ---------- Buffer: minibuffer ----------
1792 If the user first types @kbd{y @key{RET}}, which is invalid because this
1793 function demands the entire word @samp{yes}, it responds by displaying
1794 these prompts, with a brief pause between them:
1798 ---------- Buffer: minibuffer ----------
1799 Please answer yes or no.
1800 Do you really want to remove everything? (yes or no)
1801 ---------- Buffer: minibuffer ----------
1806 @node Multiple Queries
1807 @section Asking Multiple Y-or-N Questions
1809 When you have a series of similar questions to ask, such as ``Do you
1810 want to save this buffer'' for each buffer in turn, you should use
1811 @code{map-y-or-n-p} to ask the collection of questions, rather than
1812 asking each question individually. This gives the user certain
1813 convenient facilities such as the ability to answer the whole series at
1816 @defun map-y-or-n-p prompter actor list &optional help action-alist no-cursor-in-echo-area
1817 This function asks the user a series of questions, reading a
1818 single-character answer in the echo area for each one.
1820 The value of @var{list} specifies the objects to ask questions about.
1821 It should be either a list of objects or a generator function. If it is
1822 a function, it should expect no arguments, and should return either the
1823 next object to ask about, or @code{nil} meaning stop asking questions.
1825 The argument @var{prompter} specifies how to ask each question. If
1826 @var{prompter} is a string, the question text is computed like this:
1829 (format @var{prompter} @var{object})
1833 where @var{object} is the next object to ask about (as obtained from
1836 If not a string, @var{prompter} should be a function of one argument
1837 (the next object to ask about) and should return the question text. If
1838 the value is a string, that is the question to ask the user. The
1839 function can also return @code{t} meaning do act on this object (and
1840 don't ask the user), or @code{nil} meaning ignore this object (and don't
1843 The argument @var{actor} says how to act on the answers that the user
1844 gives. It should be a function of one argument, and it is called with
1845 each object that the user says yes for. Its argument is always an
1846 object obtained from @var{list}.
1848 If the argument @var{help} is given, it should be a list of this form:
1851 (@var{singular} @var{plural} @var{action})
1855 where @var{singular} is a string containing a singular noun that
1856 describes the objects conceptually being acted on, @var{plural} is the
1857 corresponding plural noun, and @var{action} is a transitive verb
1858 describing what @var{actor} does.
1860 If you don't specify @var{help}, the default is @code{("object"
1861 "objects" "act on")}.
1863 Each time a question is asked, the user may enter @kbd{y}, @kbd{Y}, or
1864 @key{SPC} to act on that object; @kbd{n}, @kbd{N}, or @key{DEL} to skip
1865 that object; @kbd{!} to act on all following objects; @key{ESC} or
1866 @kbd{q} to exit (skip all following objects); @kbd{.} (period) to act on
1867 the current object and then exit; or @kbd{C-h} to get help. These are
1868 the same answers that @code{query-replace} accepts. The keymap
1869 @code{query-replace-map} defines their meaning for @code{map-y-or-n-p}
1870 as well as for @code{query-replace}; see @ref{Search and Replace}.
1872 You can use @var{action-alist} to specify additional possible answers
1873 and what they mean. It is an alist of elements of the form
1874 @code{(@var{char} @var{function} @var{help})}, each of which defines one
1875 additional answer. In this element, @var{char} is a character (the
1876 answer); @var{function} is a function of one argument (an object from
1877 @var{list}); @var{help} is a string.
1879 When the user responds with @var{char}, @code{map-y-or-n-p} calls
1880 @var{function}. If it returns non-@code{nil}, the object is considered
1881 ``acted upon,'' and @code{map-y-or-n-p} advances to the next object in
1882 @var{list}. If it returns @code{nil}, the prompt is repeated for the
1885 Normally, @code{map-y-or-n-p} binds @code{cursor-in-echo-area} while
1886 prompting. But if @var{no-cursor-in-echo-area} is non-@code{nil}, it
1889 If @code{map-y-or-n-p} is called in a command that was invoked using the
1890 mouse---more precisely, if @code{last-nonmenu-event} (@pxref{Command
1891 Loop Info}) is either @code{nil} or a list---then it uses a dialog box
1892 or pop-up menu to ask the question. In this case, it does not use
1893 keyboard input or the echo area. You can force use of the mouse or use
1894 of keyboard input by binding @code{last-nonmenu-event} to a suitable
1895 value around the call.
1897 The return value of @code{map-y-or-n-p} is the number of objects acted on.
1900 @node Reading a Password
1901 @section Reading a Password
1902 @cindex passwords, reading
1904 To read a password to pass to another program, you can use the
1905 function @code{read-passwd}.
1907 @defun read-passwd prompt &optional confirm default
1908 This function reads a password, prompting with @var{prompt}. It does
1909 not echo the password as the user types it; instead, it echoes @samp{.}
1910 for each character in the password.
1912 The optional argument @var{confirm}, if non-@code{nil}, says to read the
1913 password twice and insist it must be the same both times. If it isn't
1914 the same, the user has to type it over and over until the last two
1917 The optional argument @var{default} specifies the default password to
1918 return if the user enters empty input. If @var{default} is @code{nil},
1919 then @code{read-passwd} returns the null string in that case.
1922 @node Minibuffer Commands
1923 @section Minibuffer Commands
1925 This section describes some commands meant for use in the
1928 @deffn Command exit-minibuffer
1929 This command exits the active minibuffer. It is normally bound to
1930 keys in minibuffer local keymaps.
1933 @deffn Command self-insert-and-exit
1934 This command exits the active minibuffer after inserting the last
1935 character typed on the keyboard (found in @code{last-command-event};
1936 @pxref{Command Loop Info}).
1939 @deffn Command previous-history-element n
1940 This command replaces the minibuffer contents with the value of the
1941 @var{n}th previous (older) history element.
1944 @deffn Command next-history-element n
1945 This command replaces the minibuffer contents with the value of the
1946 @var{n}th more recent history element.
1949 @deffn Command previous-matching-history-element pattern n
1950 This command replaces the minibuffer contents with the value of the
1951 @var{n}th previous (older) history element that matches @var{pattern} (a
1952 regular expression).
1955 @deffn Command next-matching-history-element pattern n
1956 This command replaces the minibuffer contents with the value of the
1957 @var{n}th next (newer) history element that matches @var{pattern} (a
1958 regular expression).
1961 @node Minibuffer Windows
1962 @section Minibuffer Windows
1963 @cindex minibuffer windows
1965 These functions access and select minibuffer windows
1966 and test whether they are active.
1968 @defun active-minibuffer-window
1969 This function returns the currently active minibuffer window, or
1970 @code{nil} if none is currently active.
1973 @defun minibuffer-window &optional frame
1974 @anchor{Definition of minibuffer-window}
1975 This function returns the minibuffer window used for frame @var{frame}.
1976 If @var{frame} is @code{nil}, that stands for the current frame. Note
1977 that the minibuffer window used by a frame need not be part of that
1978 frame---a frame that has no minibuffer of its own necessarily uses some
1979 other frame's minibuffer window.
1982 @defun set-minibuffer-window window
1983 This function specifies @var{window} as the minibuffer window to use.
1984 This affects where the minibuffer is displayed if you put text in it
1985 without invoking the usual minibuffer commands. It has no effect on
1986 the usual minibuffer input functions because they all start by
1987 choosing the minibuffer window according to the current frame.
1991 @defun window-minibuffer-p &optional window
1992 This function returns non-@code{nil} if @var{window} is a minibuffer
1994 @var{window} defaults to the selected window.
1997 It is not correct to determine whether a given window is a minibuffer by
1998 comparing it with the result of @code{(minibuffer-window)}, because
1999 there can be more than one minibuffer window if there is more than one
2002 @defun minibuffer-window-active-p window
2003 This function returns non-@code{nil} if @var{window}, assumed to be
2004 a minibuffer window, is currently active.
2007 @node Minibuffer Contents
2008 @section Minibuffer Contents
2010 These functions access the minibuffer prompt and contents.
2012 @defun minibuffer-prompt
2013 This function returns the prompt string of the currently active
2014 minibuffer. If no minibuffer is active, it returns @code{nil}.
2017 @defun minibuffer-prompt-end
2018 This function returns the current
2019 position of the end of the minibuffer prompt, if a minibuffer is
2020 current. Otherwise, it returns the minimum valid buffer position.
2023 @defun minibuffer-prompt-width
2024 This function returns the current display-width of the minibuffer
2025 prompt, if a minibuffer is current. Otherwise, it returns zero.
2028 @defun minibuffer-contents
2029 This function returns the editable
2030 contents of the minibuffer (that is, everything except the prompt) as
2031 a string, if a minibuffer is current. Otherwise, it returns the
2032 entire contents of the current buffer.
2035 @defun minibuffer-contents-no-properties
2036 This is like @code{minibuffer-contents}, except that it does not copy text
2037 properties, just the characters themselves. @xref{Text Properties}.
2040 @defun minibuffer-completion-contents
2041 This is like @code{minibuffer-contents}, except that it returns only
2042 the contents before point. That is the part that completion commands
2043 operate on. @xref{Minibuffer Completion}.
2046 @defun delete-minibuffer-contents
2047 This function erases the editable contents of the minibuffer (that is,
2048 everything except the prompt), if a minibuffer is current. Otherwise,
2049 it erases the entire current buffer.
2052 @node Recursive Mini
2053 @section Recursive Minibuffers
2054 @cindex recursive minibuffers
2056 These functions and variables deal with recursive minibuffers
2057 (@pxref{Recursive Editing}):
2059 @defun minibuffer-depth
2060 This function returns the current depth of activations of the
2061 minibuffer, a nonnegative integer. If no minibuffers are active, it
2065 @defopt enable-recursive-minibuffers
2066 If this variable is non-@code{nil}, you can invoke commands (such as
2067 @code{find-file}) that use minibuffers even while the minibuffer window
2068 is active. Such invocation produces a recursive editing level for a new
2069 minibuffer. The outer-level minibuffer is invisible while you are
2070 editing the inner one.
2072 If this variable is @code{nil}, you cannot invoke minibuffer
2073 commands when the minibuffer window is active, not even if you switch to
2074 another window to do it.
2078 If a command name has a property @code{enable-recursive-minibuffers}
2079 that is non-@code{nil}, then the command can use the minibuffer to read
2080 arguments even if it is invoked from the minibuffer. A command can
2081 also achieve this by binding @code{enable-recursive-minibuffers}
2082 to @code{t} in the interactive declaration (@pxref{Using Interactive}).
2083 The minibuffer command @code{next-matching-history-element} (normally
2084 @kbd{M-s} in the minibuffer) does the latter.
2086 @node Minibuffer Misc
2087 @section Minibuffer Miscellany
2089 @defun minibufferp &optional buffer-or-name
2090 This function returns non-@code{nil} if @var{buffer-or-name} is a
2091 minibuffer. If @var{buffer-or-name} is omitted, it tests the current
2095 @defvar minibuffer-setup-hook
2096 This is a normal hook that is run whenever the minibuffer is entered.
2100 @defvar minibuffer-exit-hook
2101 This is a normal hook that is run whenever the minibuffer is exited.
2105 @defvar minibuffer-help-form
2106 @anchor{Definition of minibuffer-help-form}
2107 The current value of this variable is used to rebind @code{help-form}
2108 locally inside the minibuffer (@pxref{Help Functions}).
2111 @defvar minibuffer-scroll-window
2112 @anchor{Definition of minibuffer-scroll-window}
2113 If the value of this variable is non-@code{nil}, it should be a window
2114 object. When the function @code{scroll-other-window} is called in the
2115 minibuffer, it scrolls this window.
2118 @defun minibuffer-selected-window
2119 This function returns the window which was selected when the
2120 minibuffer was entered. If selected window is not a minibuffer
2121 window, it returns @code{nil}.
2124 @defopt max-mini-window-height
2125 This variable specifies the maximum height for resizing minibuffer
2126 windows. If a float, it specifies a fraction of the height of the
2127 frame. If an integer, it specifies a number of lines.
2130 @defun minibuffer-message string &rest args
2131 This function displays @var{string} temporarily at the end of the
2132 minibuffer text, for two seconds, or until the next input event
2133 arrives, whichever comes first. If @var{args} is non-@code{nil}, the
2134 actual message is obtained by passing @var{string} and @var{args}
2135 through @code{format}. @xref{Formatting Strings}.
2139 arch-tag: bba7f945-9078-477f-a2ce-18818a6e1218