This is ../info/lispref.info, produced by makeinfo version 4.0 from lispref/lispref.texi. INFO-DIR-SECTION XEmacs Editor START-INFO-DIR-ENTRY * Lispref: (lispref). XEmacs Lisp Reference Manual. END-INFO-DIR-ENTRY Edition History: GNU Emacs Lisp Reference Manual Second Edition (v2.01), May 1993 GNU Emacs Lisp Reference Manual Further Revised (v2.02), August 1993 Lucid Emacs Lisp Reference Manual (for 19.10) First Edition, March 1994 XEmacs Lisp Programmer's Manual (for 19.12) Second Edition, April 1995 GNU Emacs Lisp Reference Manual v2.4, June 1995 XEmacs Lisp Programmer's Manual (for 19.13) Third Edition, July 1995 XEmacs Lisp Reference Manual (for 19.14 and 20.0) v3.1, March 1996 XEmacs Lisp Reference Manual (for 19.15 and 20.1, 20.2, 20.3) v3.2, April, May, November 1997 XEmacs Lisp Reference Manual (for 21.0) v3.3, April 1998 Copyright (C) 1990, 1991, 1992, 1993, 1994, 1995 Free Software Foundation, Inc. Copyright (C) 1994, 1995 Sun Microsystems, Inc. Copyright (C) 1995, 1996 Ben Wing. Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice are preserved on all copies. Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that this permission notice may be stated in a translation approved by the Foundation. Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided also that the section entitled "GNU General Public License" is included exactly as in the original, and provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that the section entitled "GNU General Public License" may be included in a translation approved by the Free Software Foundation instead of in the original English.  File: lispref.info, Node: Key Sequences, Next: Prefix Keys, Prev: Inheritance and Keymaps, Up: Keymaps Key Sequences ============= Contrary to popular belief, the world is not ASCII. When running under a window manager, XEmacs can tell the difference between, for example, the keystrokes `control-h', `control-shift-h', and `backspace'. You can, in fact, bind different commands to each of these. A "key sequence" is a set of keystrokes. A "keystroke" is a keysym and some set of modifiers (such as and ). A "keysym" is what is printed on the keys on your keyboard. A keysym may be represented by a symbol, or (if and only if it is equivalent to an ASCII character in the range 32 - 255) by a character or its equivalent ASCII code. The `A' key may be represented by the symbol `A', the character `?A', or by the number 65. The `break' key may be represented only by the symbol `break'. A keystroke may be represented by a list: the last element of the list is the key (a symbol, character, or number, as above) and the preceding elements are the symbolic names of modifier keys (, , , , , and ). Thus, the sequence `control-b' is represented by the forms `(control b)', `(control ?b)', and `(control 98)'. A keystroke may also be represented by an event object, as returned by the `next-command-event' and `read-key-sequence' functions. Note that in this context, the keystroke `control-b' is _not_ represented by the number 2 (the ASCII code for `^B') or the character `?\^B'. See below. The modifier is somewhat of a special case. You should not (and cannot) use `(meta shift a)' to mean `(meta A)', since for characters that have ASCII equivalents, the state of the shift key is implicit in the keysym (`a' vs. `A'). You also cannot say `(shift =)' to mean `+', as that sort of thing varies from keyboard to keyboard. The modifier is for use only with characters that do not have a second keysym on the same key, such as `backspace' and `tab'. A key sequence is a vector of keystrokes. As a degenerate case, elements of this vector may also be keysyms if they have no modifiers. That is, the `A' keystroke is represented by all of these forms: A ?A 65 (A) (?A) (65) [A] [?A] [65] [(A)] [(?A)] [(65)] the `control-a' keystroke is represented by these forms: (control A) (control ?A) (control 65) [(control A)] [(control ?A)] [(control 65)] the key sequence `control-c control-a' is represented by these forms: [(control c) (control a)] [(control ?c) (control ?a)] [(control 99) (control 65)] etc. Mouse button clicks work just like keypresses: `(control button1)' means pressing the left mouse button while holding down the control key. `[(control c) (shift button3)]' means `control-c', hold , click right. Commands may be bound to the mouse-button up-stroke rather than the down-stroke as well. `button1' means the down-stroke, and `button1up' means the up-stroke. Different commands may be bound to the up and down strokes, though that is probably not what you want, so be careful. For backward compatibility, a key sequence may also be represented by a string. In this case, it represents the key sequence(s) that would produce that sequence of ASCII characters in a purely ASCII world. For example, a string containing the ASCII backspace character, `"\^H"', would represent two key sequences: `(control h)' and `backspace'. Binding a command to this will actually bind both of those key sequences. Likewise for the following pairs: control h backspace control i tab control m return control j linefeed control [ escape control @ control space After binding a command to two key sequences with a form like (define-key global-map "\^X\^I" 'command-1) it is possible to redefine only one of those sequences like so: (define-key global-map [(control x) (control i)] 'command-2) (define-key global-map [(control x) tab] 'command-3) Of course, all of this applies only when running under a window system. If you're talking to XEmacs through a TTY connection, you don't get any of these features. - Function: event-matches-key-specifier-p event key-specifier This function returns non-`nil' if EVENT matches KEY-SPECIFIER, which can be any valid form representing a key sequence. This can be useful, e.g., to determine if the user pressed `help-char' or `quit-char'.  File: lispref.info, Node: Prefix Keys, Next: Active Keymaps, Prev: Key Sequences, Up: Keymaps Prefix Keys =========== A "prefix key" has an associated keymap that defines what to do with key sequences that start with the prefix key. For example, `C-x' is a prefix key, and it uses a keymap that is also stored in the variable `ctl-x-map'. Here is a list of the standard prefix keys of XEmacs and their keymaps: * `help-map' is used for events that follow `C-h'. * `mode-specific-map' is for events that follow `C-c'. This map is not actually mode specific; its name was chosen to be informative for the user in `C-h b' (`display-bindings'), where it describes the main use of the `C-c' prefix key. * `ctl-x-map' is the map used for events that follow `C-x'. This map is also the function definition of `Control-X-prefix'. * `ctl-x-4-map' is used for events that follow `C-x 4'. * `ctl-x-5-map' is used for events that follow `C-x 5'. * The prefix keys `C-x n', `C-x r' and `C-x a' use keymaps that have no special name. * `esc-map' is an evil hack that is present for compatibility purposes with Emacs 18. Defining a key in `esc-map' is equivalent to defining the same key in `global-map' but with the prefix added. You should _not_ use this in your code. (This map is also the function definition of `ESC-prefix'.) The binding of a prefix key is the keymap to use for looking up the events that follow the prefix key. (It may instead be a symbol whose function definition is a keymap. The effect is the same, but the symbol serves as a name for the prefix key.) Thus, the binding of `C-x' is the symbol `Control-X-prefix', whose function definition is the keymap for `C-x' commands. (The same keymap is also the value of `ctl-x-map'.) Prefix key definitions can appear in any active keymap. The definitions of `C-c', `C-x', `C-h' and as prefix keys appear in the global map, so these prefix keys are always available. Major and minor modes can redefine a key as a prefix by putting a prefix key definition for it in the local map or the minor mode's map. *Note Active Keymaps::. If a key is defined as a prefix in more than one active map, then its various definitions are in effect merged: the commands defined in the minor mode keymaps come first, followed by those in the local map's prefix definition, and then by those from the global map. In the following example, we make `C-p' a prefix key in the local keymap, in such a way that `C-p' is identical to `C-x'. Then the binding for `C-p C-f' is the function `find-file', just like `C-x C-f'. The key sequence `C-p 6' is not found in any active keymap. (use-local-map (make-sparse-keymap)) => nil (local-set-key "\C-p" ctl-x-map) => nil (key-binding "\C-p\C-f") => find-file (key-binding "\C-p6") => nil - Function: define-prefix-command symbol &optional mapvar This function defines SYMBOL as a prefix command: it creates a keymap and stores it as SYMBOL's function definition. Storing the symbol as the binding of a key makes the key a prefix key that has a name. If optional argument MAPVAR is not specified, it also sets SYMBOL as a variable, to have the keymap as its value. (If MAPVAR is given and is not `t', its value is stored as the value of SYMBOL.) The function returns SYMBOL. In Emacs version 18, only the function definition of SYMBOL was set, not the value as a variable.  File: lispref.info, Node: Active Keymaps, Next: Key Lookup, Prev: Prefix Keys, Up: Keymaps Active Keymaps ============== XEmacs normally contains many keymaps; at any given time, just a few of them are "active" in that they participate in the interpretation of user input. These are the global keymap, the current buffer's local keymap, and the keymaps of any enabled minor modes. The "global keymap" holds the bindings of keys that are defined regardless of the current buffer, such as `C-f'. The variable `global-map' holds this keymap, which is always active. Each buffer may have another keymap, its "local keymap", which may contain new or overriding definitions for keys. The current buffer's local keymap is always active except when `overriding-local-map' or `overriding-terminal-local-map' overrides it. Extents and text properties can specify an alternative local map for certain parts of the buffer; see *Note Extents and Events::. Each minor mode may have a keymap; if it does, the keymap is active when the minor mode is enabled. The variable `overriding-local-map' and `overriding-terminal-local-map', if non-`nil', specify other local keymaps that override the buffer's local map and all the minor mode keymaps. All the active keymaps are used together to determine what command to execute when a key is entered. XEmacs searches these maps one by one, in order of decreasing precedence, until it finds a binding in one of the maps. More specifically: For key-presses, the order of keymaps searched is: * the `keymap' property of any extent(s) or text properties at point; * any applicable minor-mode maps; * the current local map of the current buffer; * the current global map. For mouse-clicks, the order of keymaps searched is: * the current local map of the `mouse-grabbed-buffer' if any; * the `keymap' property of any extent(s) at the position of the click (this includes modeline extents); * the `modeline-map' of the buffer corresponding to the modeline under the mouse (if the click happened over a modeline); * the value of `toolbar-map' in the current buffer (if the click happened over a toolbar); * the current local map of the buffer under the mouse (does not apply to toolbar clicks); * any applicable minor-mode maps; * the current global map. Note that if `overriding-local-map' or `overriding-terminal-local-map' is non-`nil', _only_ those two maps and the current global map are searched. The procedure for searching a single keymap is called "key lookup"; see *Note Key Lookup::. Since every buffer that uses the same major mode normally uses the same local keymap, you can think of the keymap as local to the mode. A change to the local keymap of a buffer (using `local-set-key', for example) is seen also in the other buffers that share that keymap. The local keymaps that are used for Lisp mode, C mode, and several other major modes exist even if they have not yet been used. These local maps are the values of the variables `lisp-mode-map', `c-mode-map', and so on. For most other modes, which are less frequently used, the local keymap is constructed only when the mode is used for the first time in a session. The minibuffer has local keymaps, too; they contain various completion and exit commands. *Note Intro to Minibuffers::. *Note Standard Keymaps::, for a list of standard keymaps. - Function: current-keymaps &optional event-or-keys This function returns a list of the current keymaps that will be searched for bindings. This lists keymaps such as the current local map and the minor-mode maps, but does not list the parents of those keymaps. EVENT-OR-KEYS controls which keymaps will be listed. If EVENT-OR-KEYS is a mouse event (or a vector whose last element is a mouse event), the keymaps for that mouse event will be listed. Otherwise, the keymaps for key presses will be listed. - Variable: global-map This variable contains the default global keymap that maps XEmacs keyboard input to commands. The global keymap is normally this keymap. The default global keymap is a full keymap that binds `self-insert-command' to all of the printing characters. It is normal practice to change the bindings in the global map, but you should not assign this variable any value other than the keymap it starts out with. - Function: current-global-map This function returns the current global keymap. This is the same as the value of `global-map' unless you change one or the other. (current-global-map) => # - Function: current-local-map &optional buffer This function returns BUFFER's local keymap, or `nil' if it has none. BUFFER defaults to the current buffer. In the following example, the keymap for the `*scratch*' buffer (using Lisp Interaction mode) has a number of entries, including one prefix key, `C-x'. (current-local-map) => # (describe-bindings-internal (current-local-map)) => ; Inserted into the buffer: backspace backward-delete-char-untabify linefeed eval-print-last-sexp delete delete-char C-j eval-print-last-sexp C-x << Prefix Command >> M-tab lisp-complete-symbol M-; lisp-indent-for-comment M-C-i lisp-complete-symbol M-C-q indent-sexp M-C-x eval-defun Alt-backspace backward-kill-sexp Alt-delete kill-sexp C-x x edebug-defun - Function: current-minor-mode-maps This function returns a list of the keymaps of currently enabled minor modes. - Function: use-global-map keymap This function makes KEYMAP the new current global keymap. It returns `nil'. It is very unusual to change the global keymap. - Function: use-local-map keymap &optional buffer This function makes KEYMAP the new local keymap of BUFFER. BUFFER defaults to the current buffer. If KEYMAP is `nil', then the buffer has no local keymap. `use-local-map' returns `nil'. Most major mode commands use this function. - Variable: minor-mode-map-alist This variable is an alist describing keymaps that may or may not be active according to the values of certain variables. Its elements look like this: (VARIABLE . KEYMAP) The keymap KEYMAP is active whenever VARIABLE has a non-`nil' value. Typically VARIABLE is the variable that enables or disables a minor mode. *Note Keymaps and Minor Modes::. Note that elements of `minor-mode-map-alist' do not have the same structure as elements of `minor-mode-alist'. The map must be the CDR of the element; a list with the map as the second element will not do. What's more, the keymap itself must appear in the CDR. It does not work to store a variable in the CDR and make the map the value of that variable. When more than one minor mode keymap is active, their order of priority is the order of `minor-mode-map-alist'. But you should design minor modes so that they don't interfere with each other. If you do this properly, the order will not matter. See also `minor-mode-key-binding', above. See *Note Keymaps and Minor Modes::, for more information about minor modes. - Variable: modeline-map This variable holds the keymap consulted for mouse-clicks on the modeline of a window. This variable may be buffer-local; its value will be looked up in the buffer of the window whose modeline was clicked upon. - Variable: toolbar-map This variable holds the keymap consulted for mouse-clicks over a toolbar. - Variable: mouse-grabbed-buffer If non-`nil', a buffer which should be consulted first for all mouse activity. When a mouse-click is processed, it will first be looked up in the local-map of this buffer, and then through the normal mechanism if there is no binding for that click. This buffer's value of `mode-motion-hook' will be consulted instead of the `mode-motion-hook' of the buffer of the window under the mouse. You should _bind_ this, not set it. - Variable: overriding-local-map If non-`nil', this variable holds a keymap to use instead of the buffer's local keymap and instead of all the minor mode keymaps. This keymap, if any, overrides all other maps that would have been active, except for the current global map. - Variable: overriding-terminal-local-map If non-`nil', this variable holds a keymap to use instead of the buffer's local keymap and instead of all the minor mode keymaps, but for the selected console only. (In other words, this variable is always console-local; putting a keymap here only applies to keystrokes coming from the selected console. *Note Consoles and Devices::.) This keymap, if any, overrides all other maps that would have been active, except for the current global map.  File: lispref.info, Node: Key Lookup, Next: Functions for Key Lookup, Prev: Active Keymaps, Up: Keymaps Key Lookup ========== "Key lookup" is the process of finding the binding of a key sequence from a given keymap. Actual execution of the binding is not part of key lookup. Key lookup uses just the event type of each event in the key sequence; the rest of the event is ignored. In fact, a key sequence used for key lookup may designate mouse events with just their types (symbols) instead of with entire mouse events (lists). *Note Events::. Such a pseudo-key-sequence is insufficient for `command-execute', but it is sufficient for looking up or rebinding a key. When the key sequence consists of multiple events, key lookup processes the events sequentially: the binding of the first event is found, and must be a keymap; then the second event's binding is found in that keymap, and so on until all the events in the key sequence are used up. (The binding thus found for the last event may or may not be a keymap.) Thus, the process of key lookup is defined in terms of a simpler process for looking up a single event in a keymap. How that is done depends on the type of object associated with the event in that keymap. Let's use the term "keymap entry" to describe the value found by looking up an event type in a keymap. (This doesn't include the item string and other extra elements in menu key bindings because `lookup-key' and other key lookup functions don't include them in the returned value.) While any Lisp object may be stored in a keymap as a keymap entry, not all make sense for key lookup. Here is a list of the meaningful kinds of keymap entries: `nil' `nil' means that the events used so far in the lookup form an undefined key. When a keymap fails to mention an event type at all, and has no default binding, that is equivalent to a binding of `nil' for that event type. KEYMAP The events used so far in the lookup form a prefix key. The next event of the key sequence is looked up in KEYMAP. COMMAND The events used so far in the lookup form a complete key, and COMMAND is its binding. *Note What Is a Function::. ARRAY The array (either a string or a vector) is a keyboard macro. The events used so far in the lookup form a complete key, and the array is its binding. See *Note Keyboard Macros::, for more information. (Note that you cannot use a shortened form of a key sequence here, such as `(control y)'; you must use the full form `[(control y)]'. *Note Key Sequences::.) LIST The meaning of a list depends on the types of the elements of the list. * If the CAR of LIST is `lambda', then the list is a lambda expression. This is presumed to be a command, and is treated as such (see above). * If the CAR of LIST is a keymap and the CDR is an event type, then this is an "indirect entry": (OTHERMAP . OTHERTYPE) When key lookup encounters an indirect entry, it looks up instead the binding of OTHERTYPE in OTHERMAP and uses that. This feature permits you to define one key as an alias for another key. For example, an entry whose CAR is the keymap called `esc-map' and whose CDR is 32 (the code for ) means, "Use the global binding of `Meta-', whatever that may be." SYMBOL The function definition of SYMBOL is used in place of SYMBOL. If that too is a symbol, then this process is repeated, any number of times. Ultimately this should lead to an object that is a keymap, a command or a keyboard macro. A list is allowed if it is a keymap or a command, but indirect entries are not understood when found via symbols. Note that keymaps and keyboard macros (strings and vectors) are not valid functions, so a symbol with a keymap, string, or vector as its function definition is invalid as a function. It is, however, valid as a key binding. If the definition is a keyboard macro, then the symbol is also valid as an argument to `command-execute' (*note Interactive Call::). The symbol `undefined' is worth special mention: it means to treat the key as undefined. Strictly speaking, the key is defined, and its binding is the command `undefined'; but that command does the same thing that is done automatically for an undefined key: it rings the bell (by calling `ding') but does not signal an error. `undefined' is used in local keymaps to override a global key binding and make the key "undefined" locally. A local binding of `nil' would fail to do this because it would not override the global binding. ANYTHING ELSE If any other type of object is found, the events used so far in the lookup form a complete key, and the object is its binding, but the binding is not executable as a command. In short, a keymap entry may be a keymap, a command, a keyboard macro, a symbol that leads to one of them, or an indirection or `nil'.  File: lispref.info, Node: Functions for Key Lookup, Next: Changing Key Bindings, Prev: Key Lookup, Up: Keymaps Functions for Key Lookup ======================== Here are the functions and variables pertaining to key lookup. - Function: lookup-key keymap key &optional accept-defaults This function returns the definition of KEY in KEYMAP. If the string or vector KEY is not a valid key sequence according to the prefix keys specified in KEYMAP (which means it is "too long" and has extra events at the end), then the value is a number, the number of events at the front of KEY that compose a complete key. If ACCEPT-DEFAULTS is non-`nil', then `lookup-key' considers default bindings as well as bindings for the specific events in KEY. Otherwise, `lookup-key' reports only bindings for the specific sequence KEY, ignoring default bindings except when you explicitly ask about them. All the other functions described in this chapter that look up keys use `lookup-key'. (lookup-key (current-global-map) "\C-x\C-f") => find-file (lookup-key (current-global-map) "\C-x\C-f12345") => 2 If KEY begins with the character whose value is contained in `meta-prefix-char', that character is implicitly removed and the modifier added to the key. Thus, the first example below is handled by conversion into the second example. (lookup-key (current-global-map) "\ef") => forward-word (lookup-key (current-global-map) "\M-f") => forward-word Unlike `read-key-sequence', this function does not modify the specified events in ways that discard information (*note Key Sequence Input::). In particular, it does not convert letters to lower case. - Command: undefined Used in keymaps to undefine keys. If a key sequence is defined to this, invoking this key sequence causes a "key undefined" error, just as if the key sequence had no binding. - Function: key-binding key &optional accept-defaults This function returns the binding for KEY in the current keymaps, trying all the active keymaps. The result is `nil' if KEY is undefined in the keymaps. The argument ACCEPT-DEFAULTS controls checking for default bindings, as in `lookup-key' (above). (key-binding "\C-x\C-f") => find-file (key-binding '(control home)) => beginning-of-buffer (key-binding [escape escape escape]) => keyboard-escape-quit - Function: local-key-binding keys &optional accept-defaults This function returns the binding for KEYS in the current local keymap, or `nil' if it is undefined there. The argument ACCEPT-DEFAULTS controls checking for default bindings, as in `lookup-key' (above). - Function: global-key-binding keys &optional accept-defaults This function returns the binding for command KEYS in the current global keymap, or `nil' if it is undefined there. The argument ACCEPT-DEFAULTS controls checking for default bindings, as in `lookup-key' (above). - Function: minor-mode-key-binding key &optional accept-defaults This function returns a list of all the active minor mode bindings of KEY. More precisely, it returns an alist of pairs `(MODENAME . BINDING)', where MODENAME is the variable that enables the minor mode, and BINDING is KEY's binding in that mode. If KEY has no minor-mode bindings, the value is `nil'. If the first binding is not a prefix command, all subsequent bindings from other minor modes are omitted, since they would be completely shadowed. Similarly, the list omits non-prefix bindings that follow prefix bindings. The argument ACCEPT-DEFAULTS controls checking for default bindings, as in `lookup-key' (above). - Variable: meta-prefix-char This variable is the meta-prefix character code. It is used when translating a two-character sequence to a meta character so it can be looked up in a keymap. For useful results, the value should be a prefix event (*note Prefix Keys::). The default value is `?\^[' (integer 27), which is the ASCII character usually produced by the key. As long as the value of `meta-prefix-char' remains `?\^[', key lookup translates ` b' into `M-b', which is normally defined as the `backward-word' command. However, if you set `meta-prefix-char' to `?\^X' (i.e. the keystroke `C-x') or its equivalent ASCII code `24', then XEmacs will translate `C-x b' (whose standard binding is the `switch-to-buffer' command) into `M-b'. meta-prefix-char ; The default value. => ?\^[ ; Under XEmacs 20. => 27 ; Under XEmacs 19. (key-binding "\eb") => backward-word ?\C-x ; The print representation ; of a character. => ?\^X ; Under XEmacs 20. => 24 ; Under XEmacs 19. (setq meta-prefix-char 24) => 24 (key-binding "\C-xb") => backward-word ; Now, typing `C-x b' is ; like typing `M-b'. (setq meta-prefix-char ?\e) ; Avoid confusion! ; Restore the default value! => ?\^[ ; Under XEmacs 20. => 27 ; Under XEmacs 19.  File: lispref.info, Node: Changing Key Bindings, Next: Key Binding Commands, Prev: Functions for Key Lookup, Up: Keymaps Changing Key Bindings ===================== The way to rebind a key is to change its entry in a keymap. If you change a binding in the global keymap, the change is effective in all buffers (though it has no direct effect in buffers that shadow the global binding with a local one). If you change the current buffer's local map, that usually affects all buffers using the same major mode. The `global-set-key' and `local-set-key' functions are convenient interfaces for these operations (*note Key Binding Commands::). You can also use `define-key', a more general function; then you must specify explicitly the map to change. The way to specify the key sequence that you want to rebind is described above (*note Key Sequences::). For the functions below, an error is signaled if KEYMAP is not a keymap or if KEY is not a string or vector representing a key sequence. You can use event types (symbols) as shorthand for events that are lists. - Function: define-key keymap key binding This function sets the binding for KEY in KEYMAP. (If KEY is more than one event long, the change is actually made in another keymap reached from KEYMAP.) The argument BINDING can be any Lisp object, but only certain types are meaningful. (For a list of meaningful types, see *Note Key Lookup::.) The value returned by `define-key' is BINDING. Every prefix of KEY must be a prefix key (i.e., bound to a keymap) or undefined; otherwise an error is signaled. If some prefix of KEY is undefined, then `define-key' defines it as a prefix key so that the rest of KEY may be defined as specified. Here is an example that creates a sparse keymap and makes a number of bindings in it: (setq map (make-sparse-keymap)) => # (define-key map "\C-f" 'forward-char) => forward-char map => # (describe-bindings-internal map) => ; (Inserted in buffer) C-f forward-char ;; Build sparse submap for `C-x' and bind `f' in that. (define-key map "\C-xf" 'forward-word) => forward-word map => # (describe-bindings-internal map) => ; (Inserted in buffer) C-f forward-char C-x << Prefix Command >> C-x f forward-word ;; Bind `C-p' to the `ctl-x-map'. (define-key map "\C-p" ctl-x-map) ;; `ctl-x-map' => # ;; Bind `C-f' to `foo' in the `ctl-x-map'. (define-key map "\C-p\C-f" 'foo) => foo map => # (describe-bindings-internal map) => ; (Inserted in buffer) C-f forward-char C-p << Prefix command Control-X-prefix >> C-x << Prefix Command >> C-p tab indent-rigidly C-p $ set-selective-display C-p ' expand-abbrev C-p ( start-kbd-macro C-p ) end-kbd-macro ... C-p C-x exchange-point-and-mark C-p C-z suspend-or-iconify-emacs C-p M-escape repeat-complex-command C-p M-C-[ repeat-complex-command C-x f forward-word C-p 4 . find-tag-other-window ... C-p 4 C-o display-buffer C-p 5 0 delete-frame ... C-p 5 C-f find-file-other-frame ... C-p a i g inverse-add-global-abbrev C-p a i l inverse-add-mode-abbrev Note that storing a new binding for `C-p C-f' actually works by changing an entry in `ctl-x-map', and this has the effect of changing the bindings of both `C-p C-f' and `C-x C-f' in the default global map. - Function: substitute-key-definition olddef newdef keymap &optional oldmap prefix This function replaces OLDDEF with NEWDEF for any keys in KEYMAP that were bound to OLDDEF. In other words, OLDDEF is replaced with NEWDEF wherever it appears. Prefix keymaps are checked recursively. The function returns `nil'. For example, this redefines `C-x C-f', if you do it in an XEmacs with standard bindings: (substitute-key-definition 'find-file 'find-file-read-only (current-global-map)) If OLDMAP is non-`nil', then its bindings determine which keys to rebind. The rebindings still happen in KEYMAP, not in OLDMAP. Thus, you can change one map under the control of the bindings in another. For example, (substitute-key-definition 'delete-backward-char 'my-funny-delete my-map global-map) puts the special deletion command in `my-map' for whichever keys are globally bound to the standard deletion command. If argument PREFIX is non-`nil', then only those occurrences of OLDDEF found in keymaps accessible through the keymap bound to PREFIX in KEYMAP are redefined. See also `accessible-keymaps'. - Function: suppress-keymap keymap &optional nodigits This function changes the contents of the full keymap KEYMAP by making all the printing characters undefined. More precisely, it binds them to the command `undefined'. This makes ordinary insertion of text impossible. `suppress-keymap' returns `nil'. If NODIGITS is `nil', then `suppress-keymap' defines digits to run `digit-argument', and `-' to run `negative-argument'. Otherwise it makes them undefined like the rest of the printing characters. The `suppress-keymap' function does not make it impossible to modify a buffer, as it does not suppress commands such as `yank' and `quoted-insert'. To prevent any modification of a buffer, make it read-only (*note Read Only Buffers::). Since this function modifies KEYMAP, you would normally use it on a newly created keymap. Operating on an existing keymap that is used for some other purpose is likely to cause trouble; for example, suppressing `global-map' would make it impossible to use most of XEmacs. Most often, `suppress-keymap' is used to initialize local keymaps of modes such as Rmail and Dired where insertion of text is not desirable and the buffer is read-only. Here is an example taken from the file `emacs/lisp/dired.el', showing how the local keymap for Dired mode is set up: ... (setq dired-mode-map (make-keymap)) (suppress-keymap dired-mode-map) (define-key dired-mode-map "r" 'dired-rename-file) (define-key dired-mode-map "\C-d" 'dired-flag-file-deleted) (define-key dired-mode-map "d" 'dired-flag-file-deleted) (define-key dired-mode-map "v" 'dired-view-file) (define-key dired-mode-map "e" 'dired-find-file) (define-key dired-mode-map "f" 'dired-find-file) ...  File: lispref.info, Node: Key Binding Commands, Next: Scanning Keymaps, Prev: Changing Key Bindings, Up: Keymaps Commands for Binding Keys ========================= This section describes some convenient interactive interfaces for changing key bindings. They work by calling `define-key'. People often use `global-set-key' in their `.emacs' file for simple customization. For example, (global-set-key "\C-x\C-\\" 'next-line) or (global-set-key [(control ?x) (control ?\\)] 'next-line) or (global-set-key [?\C-x ?\C-\\] 'next-line) redefines `C-x C-\' to move down a line. (global-set-key [(meta button1)] 'mouse-set-point) redefines the first (leftmost) mouse button, typed with the Meta key, to set point where you click. - Command: global-set-key key definition This function sets the binding of KEY in the current global map to DEFINITION. (global-set-key KEY DEFINITION) == (define-key (current-global-map) KEY DEFINITION) - Command: global-unset-key key This function removes the binding of KEY from the current global map. One use of this function is in preparation for defining a longer key that uses KEY as a prefix--which would not be allowed if KEY has a non-prefix binding. For example: (global-unset-key "\C-l") => nil (global-set-key "\C-l\C-l" 'redraw-display) => nil This function is implemented simply using `define-key': (global-unset-key KEY) == (define-key (current-global-map) KEY nil) - Command: local-set-key key definition This function sets the binding of KEY in the current local keymap to DEFINITION. (local-set-key KEY DEFINITION) == (define-key (current-local-map) KEY DEFINITION) - Command: local-unset-key key This function removes the binding of KEY from the current local map. (local-unset-key KEY) == (define-key (current-local-map) KEY nil)  File: lispref.info, Node: Scanning Keymaps, Next: Other Keymap Functions, Prev: Key Binding Commands, Up: Keymaps Scanning Keymaps ================ This section describes functions used to scan all the current keymaps, or all keys within a keymap, for the sake of printing help information. - Function: accessible-keymaps keymap &optional prefix This function returns a list of all the keymaps that can be accessed (via prefix keys) from KEYMAP. The value is an association list with elements of the form `(KEY . MAP)', where KEY is a prefix key whose definition in KEYMAP is MAP. The elements of the alist are ordered so that the KEY increases in length. The first element is always `([] . KEYMAP)', because the specified keymap is accessible from itself with a prefix of no events. If PREFIX is given, it should be a prefix key sequence; then `accessible-keymaps' includes only the submaps whose prefixes start with PREFIX. These elements look just as they do in the value of `(accessible-keymaps)'; the only difference is that some elements are omitted. In the example below, the returned alist indicates that the key `C-x', which is displayed as `[(control x)]', is a prefix key whose definition is the keymap `#) 1 entry 0x8a2>'. (The strange notation for the keymap's name indicates that this is an internal submap of `emacs-lisp-mode-map'. This is because `lisp-interaction-mode-map' has set up `emacs-lisp-mode-map' as its parent, and `lisp-interaction-mode-map' defines no key sequences beginning with `C-x'.) (current-local-map) => # (accessible-keymaps (current-local-map)) =>(([] . #) ([(control x)] . #) 1 entry 0x8a2>)) The following example shows the results of calling `accessible-keymaps' on a large, complex keymap. Notice how some keymaps were given explicit names using `set-keymap-name'; those submaps without explicit names are given descriptive names indicating their relationship to their enclosing keymap. (accessible-keymaps (current-global-map)) => (([] . #) ([(control c)] . #) ([(control h)] . #) ([(control x)] . #) ([(meta escape)] . #) 3 entries 0x3e0>) ([(meta control \[)] . #) 3 entries 0x3e0>) ([f1] . #) ([(control x) \4] . #) ([(control x) \5] . #) ([(control x) \6] . #) ([(control x) a] . #) 8 entries 0x3ef>) ([(control x) n] . #) ([(control x) r] . #) ([(control x) v] . #) ([(control x) a i] . #) 8 entries 0x3ef>) 2 entries 0x3f5>)) - Function: map-keymap function keymap &optional sort-first This function applies FUNCTION to each element of KEYMAP. FUNCTION will be called with two arguments: a key-description list, and the binding. The order in which the elements of the keymap are passed to the function is unspecified. If the function inserts new elements into the keymap, it may or may not be called with them later. No element of the keymap will ever be passed to the function more than once. The function will not be called on elements of this keymap's parents (*note Inheritance and Keymaps::) or upon keymaps which are contained within this keymap (multi-character definitions). It will be called on characters since they are not really two-character sequences. If the optional third argument SORT-FIRST is non-`nil', then the elements of the keymap will be passed to the mapper function in a canonical order. Otherwise, they will be passed in hash (that is, random) order, which is faster. - Function: keymap-fullness keymap This function returns the number of bindings in the keymap. - Function: where-is-internal definition &optional keymaps firstonly noindirect event-or-keys This function returns a list of key sequences (of any length) that are bound to DEFINITION in a set of keymaps. The argument DEFINITION can be any object; it is compared with all keymap entries using `eq'. KEYMAPS can be either a keymap (meaning search in that keymap and the current global keymap) or a list of keymaps (meaning search in exactly those keymaps and no others). If KEYMAPS is nil, search in the currently applicable maps for EVENT-OR-KEYS. If KEYMAPS is a keymap, then the maps searched are KEYMAPS and the global keymap. If KEYMAPS is a list of keymaps, then the maps searched are exactly those keymaps, and no others. If KEYMAPS is `nil', then the maps used are the current active keymaps for EVENT-OR-KEYS (this is equivalent to specifying `(current-keymaps EVENT-OR-KEYS)' as the argument to KEYMAPS). If FIRSTONLY is non-`nil', then the value is a single vector representing the first key sequence found, rather than a list of all possible key sequences. If NOINDIRECT is non-`nil', `where-is-internal' doesn't follow indirect keymap bindings. This makes it possible to search for an indirect definition itself. This function is used by `where-is' (*note Help: (xemacs)Help.). (where-is-internal 'describe-function) => ([(control h) d] [(control h) f] [f1 d] [f1 f]) - Function: describe-bindings-internal map &optional all shadow prefix mouse-only-p This function inserts (into the current buffer) a list of all defined keys and their definitions in MAP. Optional second argument ALL says whether to include even "uninteresting" definitions, i.e. symbols with a non-`nil' `suppress-keymap' property. Third argument SHADOW is a list of keymaps whose bindings shadow those of map; if a binding is present in any shadowing map, it is not printed. Fourth argument PREFIX, if non-`nil', should be a key sequence; only bindings which start with that key sequence will be printed. Fifth argument MOUSE-ONLY-P says to only print bindings for mouse clicks. `describe-bindings-internal' is used to implement the help command `describe-bindings'. - Command: describe-bindings &optional prefix mouse-only-p This function creates a listing of all defined keys and their definitions. It writes the listing in a buffer named `*Help*' and displays it in a window. If optional argument PREFIX is non-`nil', it should be a prefix key; then the listing includes only keys that start with PREFIX. When several characters with consecutive ASCII codes have the same definition, they are shown together, as `FIRSTCHAR..LASTCHAR'. In this instance, you need to know the ASCII codes to understand which characters this means. For example, in the default global map, the characters ` .. ~' are described by a single line. is ASCII 32, `~' is ASCII 126, and the characters between them include all the normal printing characters, (e.g., letters, digits, punctuation, etc.); all these characters are bound to `self-insert-command'. If the second optional argument MOUSE-ONLY-P (prefix arg, interactively) is non-`nil' then only the mouse bindings are displayed.  File: lispref.info, Node: Other Keymap Functions, Prev: Scanning Keymaps, Up: Keymaps Other Keymap Functions ====================== - Function: set-keymap-prompt keymap new-prompt This function sets the "prompt" of KEYMAP to string NEW-PROMPT, or `nil' if no prompt is desired. The prompt is shown in the echo-area when reading a key-sequence to be looked-up in this keymap. - Function: keymap-prompt keymap &optional use-inherited This function returns the "prompt" of the given keymap. If USE-INHERITED is non-`nil', any parent keymaps will also be searched for a prompt.  File: lispref.info, Node: Menus, Next: Dialog Boxes, Prev: Keymaps, Up: Top Menus ***** * Menu: * Menu Format:: Format of a menu description. * Menubar Format:: How to specify a menubar. * Menubar:: Functions for controlling the menubar. * Modifying Menus:: Modifying a menu description. * Pop-Up Menus:: Functions for specifying pop-up menus. * Menu Filters:: Filter functions for the default menubar. * Menu Accelerators:: Using and controlling menu accelerator keys * Buffers Menu:: The menu that displays the list of buffers.