| blob | e1e45b18d4e702b29d901f02c5520d5246009e52 |
1 /* Manipulation of keymaps
2 Copyright (C) 1985, 1986, 1987, 1988, 1993, 1994, 1995,
3 1998, 1999, 2000, 2001, 2002, 2003, 2004,
4 2005, 2006, 2007 Free Software Foundation, Inc.
6 This file is part of GNU Emacs.
8 GNU Emacs is free software; you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 3, or (at your option)
11 any later version.
13 GNU Emacs is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
18 You should have received a copy of the GNU General Public License
19 along with GNU Emacs; see the file COPYING. If not, write to
20 the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
21 Boston, MA 02110-1301, USA. */
24 #include <config.h>
25 #include <stdio.h>
26 #if HAVE_ALLOCA_H
27 # include <alloca.h>
28 #endif
41 /* The number of elements in keymap vectors. */
42 #define DENSE_TABLE_SIZE (0200)
44 /* Actually allocate storage for these variables */
51 ESC-prefixed default commands */
54 C-x-prefixed default commands */
56 /* was MinibufLocalMap */
57 Lisp_Object Vminibuffer_local_map;
58 /* The keymap used by the minibuf for local
59 bindings when spaces are allowed in the
60 minibuf */
62 /* was MinibufLocalNSMap */
63 Lisp_Object Vminibuffer_local_ns_map;
64 /* The keymap used by the minibuf for local
65 bindings when spaces are not encouraged
66 in the minibuf */
68 /* keymap used for minibuffers when doing completion */
69 /* was MinibufLocalCompletionMap */
70 Lisp_Object Vminibuffer_local_completion_map;
72 /* keymap used for minibuffers when doing completion in filenames */
73 Lisp_Object Vminibuffer_local_filename_completion_map;
75 /* keymap used for minibuffers when doing completion in filenames
76 with require-match*/
77 Lisp_Object Vminibuffer_local_must_match_filename_map;
79 /* keymap used for minibuffers when doing completion and require a match */
80 /* was MinibufLocalMustMatchMap */
81 Lisp_Object Vminibuffer_local_must_match_map;
83 /* Alist of minor mode variables and keymaps. */
84 Lisp_Object Vminor_mode_map_alist;
86 /* Alist of major-mode-specific overrides for
87 minor mode variables and keymaps. */
88 Lisp_Object Vminor_mode_overriding_map_alist;
90 /* List of emulation mode keymap alists. */
91 Lisp_Object Vemulation_mode_map_alists;
93 /* Keymap mapping ASCII function key sequences onto their preferred forms.
94 Initialized by the terminal-specific lisp files. See DEFVAR for more
95 documentation. */
96 Lisp_Object Vfunction_key_map;
98 /* Keymap mapping ASCII function key sequences onto their preferred forms. */
99 Lisp_Object Vkey_translation_map;
101 /* A list of all commands given new bindings since a certain time
102 when nil was stored here.
103 This is used to speed up recomputation of menu key equivalents
104 when Emacs starts up. t means don't record anything here. */
105 Lisp_Object Vdefine_key_rebound_commands;
109 /* Alist of elements like (DEL . "\d"). */
112 /* Pre-allocated 2-element vector for Fcommand_remapping to use. */
115 /* A char with the CHAR_META bit set in a vector or the 0200 bit set
116 in a string key sequence is equivalent to prefixing with this
117 character. */
122 /* Hash table used to cache a reverse-map to speed up calls to where-is. */
124 /* Which keymaps are reverse-stored in the cache. */
141 \f
142 /* Keymap object support - constructors and predicates. */
146 CHARTABLE is a char-table that holds the bindings for all characters
147 without modifiers. All entries in it are initially nil, meaning
148 "command undefined". ALIST is an assoc-list which holds bindings for
149 function keys, mouse events, and any other things that appear in the
150 input stream. Initially, ALIST is nil.
152 The optional arg STRING supplies a menu name for the keymap
155 Lisp_Object string;
156 {
157 Lisp_Object tail;
160 else
164 }
168 Its car is `keymap' and its cdr is an alist of (CHAR . DEFINITION),
169 which binds the character CHAR to DEFINITION, or (SYMBOL . DEFINITION),
170 which binds the function key or mouse event SYMBOL to DEFINITION.
171 Initially the alist is nil.
173 The optional arg STRING supplies a menu name for the keymap
176 Lisp_Object string;
177 {
181 }
183 /* This function is used for installing the standard key bindings
184 at initialization time.
186 For example:
188 initial_define_key (control_x_map, Ctl('X'), "exchange-point-and-mark"); */
190 void
192 Lisp_Object keymap;
195 {
197 }
199 void
201 Lisp_Object keymap;
204 {
206 }
211 A keymap is a list (keymap . ALIST),
212 or a symbol whose function definition is itself a keymap.
213 ALIST elements look like (CHAR . DEFN) or (SYMBOL . DEFN);
214 a vector of densely packed bindings for small character codes
217 Lisp_Object object;
218 {
220 }
224 If non-nil, the prompt is shown in the echo-area
227 Lisp_Object map;
228 {
231 {
236 }
238 }
240 /* Check that OBJECT is a keymap (after dereferencing through any
241 symbols). If it is, return it.
243 If AUTOLOAD is non-zero and OBJECT is a symbol whose function value
244 is an autoload form, do the autoload and try again.
245 If AUTOLOAD is nonzero, callers must assume GC is possible.
247 If the map needs to be autoloaded, but AUTOLOAD is zero (and ERROR
248 is zero as well), return Qt.
250 ERROR controls how we respond if OBJECT isn't a keymap.
251 If ERROR is non-zero, signal an error; otherwise, just return Qnil.
253 Note that most of the time, we don't want to pursue autoloads.
254 Functions like Faccessible_keymaps which scan entire keymap trees
255 shouldn't load every autoloaded keymap. I'm not sure about this,
256 but it seems to me that only read_key_sequence, Flookup_key, and
257 Fdefine_key should cause keymaps to be autoloaded.
259 This function can GC when AUTOLOAD is non-zero, because it calls
260 do_autoload which can GC. */
262 Lisp_Object
264 Lisp_Object object;
266 {
267 Lisp_Object tem;
269 autoload_retry:
277 {
281 /* Should we do an autoload? Autoload forms for keymaps have
282 Qkeymap as their fifth element. */
285 {
286 Lisp_Object tail;
290 {
292 {
297 UNGCPRO;
300 }
301 else
303 }
304 }
305 }
307 end:
311 }
312 \f
313 /* Return the parent map of KEYMAP, or nil if it has none.
314 We assume that KEYMAP is a valid keymap. */
316 Lisp_Object
318 Lisp_Object keymap;
320 {
321 Lisp_Object list;
325 /* Skip past the initial element `keymap'. */
328 {
329 /* See if there is another `keymap'. */
332 }
335 }
340 Lisp_Object keymap;
341 {
343 }
345 /* Check whether MAP is one of MAPS parents. */
346 int
349 {
354 }
356 /* Set the parent keymap of MAP to PARENT. */
363 {
368 /* Force a keymap flush for the next call to where-is.
369 Since this can be called from within where-is, we don't set where_is_cache
370 directly but only where_is_cache_keymaps, since where_is_cache shouldn't
371 be changed during where-is, while where_is_cache_keymaps is only used at
372 the very beginning of where-is and can thus be changed here without any
373 adverse effect.
374 This is a very minor correctness (rather than safety) issue. */
381 {
384 /* Check for cycles. */
387 }
389 /* Skip past the initial element `keymap'. */
392 {
394 /* If there is a parent keymap here, replace it.
395 If we came to the end, add the parent in PREV. */
397 {
398 /* If we already have the right parent, return now
399 so that we avoid the loops below. */
406 }
408 }
410 /* Scan through for submaps, and set their parents too. */
413 {
414 /* Stop the scan when we come to the parent. */
418 /* If this element holds a prefix map, deal with it. */
431 {
437 }
438 }
441 }
443 /* EVENT is defined in MAP as a prefix, and SUBMAP is its definition.
444 if EVENT is also a prefix in MAP's parent,
445 make sure that SUBMAP inherits that definition as its own parent. */
447 static void
450 {
453 /* SUBMAP is a cons that we found as a key binding.
454 Discard the other things found in a menu key binding. */
458 /* If it isn't a keymap now, there's no work to do. */
464 parent_entry =
466 else
469 /* If MAP's parent has something other than a keymap,
470 our own submap shadows it completely. */
475 {
476 Lisp_Object submap_parent;
479 {
480 Lisp_Object tem;
485 {
487 /* Fset_keymap_parent could create a cycle. */
490 }
491 else
493 }
495 }
496 }
497 \f
498 /* Look up IDX in MAP. IDX may be any sort of event.
499 Note that this does only one level of lookup; IDX must be a single
500 event, not a sequence.
502 If T_OK is non-zero, bindings for Qt are treated as default
503 bindings; any key left unmentioned by other tables and bindings is
504 given the binding of Qt.
506 If T_OK is zero, bindings for Qt are not treated specially.
508 If NOINHERIT, don't accept a subkeymap found in an inherited keymap. */
510 Lisp_Object
512 Lisp_Object map;
513 Lisp_Object idx;
517 {
518 Lisp_Object val;
520 /* Qunbound in VAL means we have found no binding yet. */
523 /* If idx is a list (some sort of mouse click, perhaps?),
524 the index we want to use is the car of the list, which
525 ought to be a symbol. */
528 /* If idx is a symbol, it might have modifiers, which need to
529 be put in the canonical order. */
533 /* Clobber the high bits that can be present on a machine
534 with more than 24 bits of integer. */
537 /* Handle the special meta -> esc mapping. */
539 {
540 /* See if there is a meta-map. If there's none, there is
541 no binding for IDX, unless a default binding exists in MAP. */
543 Lisp_Object meta_map;
545 /* A strange value in which Meta is set would cause
546 infinite recursion. Protect against that. */
552 UNGCPRO;
554 {
557 }
559 /* Set IDX to t, so that we only find a default binding. */
561 else
562 /* We know there is no binding. */
564 }
566 /* t_binding is where we put a default binding that applies,
567 to use in case we do not find a binding specifically
568 for this key sequence. */
569 {
570 Lisp_Object tail;
576 /* If `t_ok' is 2, both `t' and generic-char bindings are accepted.
577 If it is 1, only generic-char bindings are accepted.
578 Otherwise, neither are. */
585 {
586 Lisp_Object binding;
590 {
591 /* If NOINHERIT, stop finding prefix definitions
592 after we pass a second occurrence of the `keymap' symbol. */
595 }
597 {
613 {
614 /* KEY is the generic character of the charset of IDX.
615 Use KEY's binding if there isn't a binding for IDX
616 itself. */
619 }
621 {
624 }
625 }
627 {
630 }
632 {
633 /* Character codes with modifiers
634 are not included in a char-table.
635 All character codes without modifiers are included. */
637 {
639 /* `nil' has a special meaning for char-tables, so
640 we use something else to record an explicitly
641 unbound entry. */
644 }
645 }
647 /* If we found a binding, clean it up and return it. */
649 {
651 /* A Qt binding is just like an explicit nil binding
652 (i.e. it shadows any parent binding but not bindings in
653 keymaps of lower precedence). */
659 }
660 QUIT;
661 }
662 UNGCPRO;
664 }
665 }
667 static void
669 map_keymap_function_t fun;
672 {
673 /* We should maybe try to detect bindings shadowed by previous
674 ones and things like that. */
678 }
680 static void
683 {
685 {
690 }
691 }
693 /* Call FUN for every binding in MAP.
694 FUN is called with 4 arguments: FUN (KEY, BINDING, ARGS, DATA).
695 AUTOLOAD if non-zero means that we can autoload keymaps if necessary. */
696 void
698 map_keymap_function_t fun;
702 {
704 Lisp_Object tail;
712 {
718 {
719 /* Loop over the char values represented in the vector. */
723 {
724 Lisp_Object character;
727 }
728 }
730 {
735 args)),
737 }
738 }
739 UNGCPRO;
740 }
742 static void
746 {
748 }
752 FUNCTION is called with two arguments: the event that is bound, and
753 the definition it is bound to. If the event is an integer, it may be
754 a generic character (see Info node `(elisp)Splitting Characters'), and
755 that means that all actual character events belonging to that generic
756 character are bound to the definition.
758 If KEYMAP has a parent, the parent's bindings are included as well.
759 This works recursively: if the parent has itself a parent, then the
760 grandparent's bindings are also included and so on.
764 {
766 /* We have to stop integers early since map_keymap gives them special
767 significance. */
774 }
776 /* Given OBJECT which was found in a slot in a keymap,
777 trace indirect definitions to get the actual definition of that slot.
778 An indirect definition is a list of the form
779 (KEYMAP . INDEX), where KEYMAP is a keymap or a symbol defined as one
780 and INDEX is the object to look up in KEYMAP to yield the definition.
782 Also if OBJECT has a menu string as the first element,
783 remove that. Also remove a menu help string as second element.
785 If AUTOLOAD is nonzero, load autoloadable keymaps
786 that are referred to with indirection.
788 This can GC because menu_item_eval_property calls Feval. */
790 Lisp_Object
792 Lisp_Object object;
794 {
796 {
798 /* This is really the value. */
801 /* If the keymap contents looks like (keymap ...) or (lambda ...)
802 then use itself. */
806 /* If the keymap contents looks like (menu-item name . DEFN)
807 or (menu-item name DEFN ...) then use DEFN.
808 This is a new format menu item. */
810 {
812 {
813 Lisp_Object tem;
820 /* If there's a `:filter FILTER', apply FILTER to the
821 menu-item's definition to get the real definition to
822 use. */
825 {
826 Lisp_Object filter;
831 }
832 }
833 else
834 /* Invalid keymap. */
836 }
838 /* If the keymap contents looks like (STRING . DEFN), use DEFN.
839 Keymap alist elements like (CHAR MENUSTRING . DEFN)
840 will be used by HierarKey menus. */
842 {
844 /* Also remove a menu help string, if any,
845 following the menu item name. */
848 /* Also remove the sublist that caches key equivalences, if any. */
850 {
851 Lisp_Object carcar;
855 }
856 }
858 /* If the contents are (KEYMAP . ELEMENT), go indirect. */
859 else
860 {
862 Lisp_Object map;
865 UNGCPRO;
868 }
869 }
870 }
872 static Lisp_Object
874 Lisp_Object keymap;
876 Lisp_Object def;
877 {
878 /* Flush any reverse-map cache. */
882 /* If we are preparing to dump, and DEF is a menu element
883 with a menu item indicator, copy it to ensure it is not pure. */
891 /* If idx is a list (some sort of mouse click, perhaps?),
892 the index we want to use is the car of the list, which
893 ought to be a symbol. */
896 /* If idx is a symbol, it might have modifiers, which need to
897 be put in the canonical order. */
901 /* Clobber the high bits that can be present on a machine
902 with more than 24 bits of integer. */
905 /* Scan the keymap for a binding of idx. */
906 {
907 Lisp_Object tail;
909 /* The cons after which we should insert new bindings. If the
910 keymap has a table element, we record its position here, so new
911 bindings will go after it; this way, the table will stay
912 towards the front of the alist and character lookups in dense
913 keymaps will remain fast. Otherwise, this just points at the
914 front of the keymap. */
915 Lisp_Object insertion_point;
919 {
920 Lisp_Object elt;
924 {
926 {
930 }
932 }
934 {
935 /* Character codes with modifiers
936 are not included in a char-table.
937 All character codes without modifiers are included. */
939 {
941 /* `nil' has a special meaning for char-tables, so
942 we use something else to record an explicitly
943 unbound entry. */
946 }
948 }
950 {
952 {
956 }
957 }
959 /* If we find a 'keymap' symbol in the spine of KEYMAP,
960 then we must have found the start of a second keymap
961 being used as the tail of KEYMAP, and a binding for IDX
962 should be inserted before it. */
965 QUIT;
966 }
968 keymap_end:
969 /* We have scanned the entire keymap, and not found a binding for
970 IDX. Let's add one. */
974 }
977 }
981 Lisp_Object
983 Lisp_Object elt;
984 {
992 /* Is this a new format menu item. */
994 {
995 /* Copy cell with menu-item marker. */
999 {
1000 /* Copy cell with menu-item name. */
1004 }
1006 {
1007 /* Copy cell with binding and if the binding is a keymap,
1008 copy that. */
1016 /* Delete cache for key equivalences. */
1018 }
1019 }
1020 else
1021 {
1022 /* It may be an old fomat menu item.
1023 Skip the optional menu string. */
1025 {
1026 /* Copy the cell, since copy-alist didn't go this deep. */
1029 /* Also skip the optional menu help string. */
1031 {
1035 }
1036 /* There may also be a list that caches key equivalences.
1037 Just delete it for the new keymap. */
1042 {
1045 }
1048 }
1051 }
1053 }
1055 static void
1058 {
1060 }
1064 The copy starts out with the same definitions of KEYMAP,
1065 but changing either the copy or KEYMAP does not affect the other.
1066 Any key definitions that are subkeymaps are recursively copied.
1067 However, a key definition which is a symbol whose definition is a keymap
1070 Lisp_Object keymap;
1071 {
1078 {
1081 {
1085 }
1087 {
1092 }
1098 }
1101 }
1102 \f
1103 /* Simple Keymap mutators and accessors. */
1105 /* GC is possible in this function if it autoloads a keymap. */
1109 KEYMAP is a keymap.
1111 KEY is a string or a vector of symbols and characters meaning a
1112 sequence of keystrokes and events. Non-ASCII characters with codes
1113 above 127 (such as ISO Latin-1) can be included if you use a vector.
1114 Using [t] for KEY creates a default definition, which applies to any
1115 event type that has no other definition in this keymap.
1117 DEF is anything that can be a key's definition:
1118 nil (means key is undefined in this keymap),
1119 a command (a Lisp function suitable for interactive calling),
1120 a string (treated as a keyboard macro),
1121 a keymap (to define a prefix key),
1122 a symbol (when the key is looked up, the symbol will stand for its
1123 function definition, which should at that time be one of the above,
1124 or another symbol whose function definition is used, etc.),
1125 a cons (STRING . DEFN), meaning that DEFN is the definition
1126 (DEFN should be a valid definition in its own right),
1127 or a cons (MAP . CHAR), meaning use definition of CHAR in keymap MAP,
1128 or an extended menu item definition.
1129 (See info node `(elisp)Extended Menu Items'.)
1131 If KEYMAP is a sparse keymap with a binding for KEY, the existing
1132 binding is altered. If there is no binding for KEY, the new pair
1135 Lisp_Object keymap;
1136 Lisp_Object key;
1137 Lisp_Object def;
1138 {
1166 {
1171 }
1173 }
1177 {
1189 {
1192 }
1193 else
1194 {
1199 idx++;
1200 }
1210 /* If this key is undefined, make it a prefix. */
1216 /* We must use Fkey_description rather than just passing key to
1217 error; key might be a vector, not a string. */
1222 Qnil)));
1223 }
1224 }
1226 /* This function may GC (it calls Fkey_binding). */
1230 Returns nil if COMMAND is not remapped (or not a symbol).
1232 If the optional argument POSITION is non-nil, it specifies a mouse
1233 position as returned by `event-start' and `event-end', and the
1234 remapping occurs in the keymaps associated with it. It can also be a
1235 number or marker, in which case the keymap properties at the specified
1236 buffer position instead of point are used. The KEYMAPS argument is
1237 ignored if POSITION is non-nil.
1239 If the optional argument KEYMAPS is non-nil, it should be a list of
1240 keymaps to search for command remapping. Otherwise, search for the
1244 {
1252 else
1253 {
1257 {
1261 }
1263 }
1264 }
1266 /* Value is number if KEY is too long; nil if valid but has no definition. */
1267 /* GC is possible in this function if it autoloads a keymap. */
1271 A value of nil means undefined. See doc of `define-key'
1272 for kinds of definitions.
1274 A number as value means KEY is "too long";
1275 that is, characters or symbols in it except for the last one
1276 fail to be a valid sequence of prefix characters in KEYMAP.
1277 The number is how many characters at the front of KEY
1278 it takes to reach a non-prefix key.
1280 Normally, `lookup-key' ignores bindings for t, which act as default
1281 bindings, used when nothing else in the keymap applies; this makes it
1282 usable as a general function for probing keymaps. However, if the
1283 third optional argument ACCEPT-DEFAULT is non-nil, `lookup-key' will
1286 Lisp_Object keymap;
1287 Lisp_Object key;
1288 Lisp_Object accept_default;
1289 {
1308 {
1314 /* Turn the 8th bit of string chars into a meta modifier. */
1318 /* Allow string since binding for `menu-bar-select-buffer'
1319 includes the buffer name in the key sequence. */
1331 QUIT;
1332 }
1333 }
1335 /* Make KEYMAP define event C as a keymap (i.e., as a prefix).
1336 Assume that currently it does not define C at all.
1337 Return the keymap. */
1339 static Lisp_Object
1342 {
1343 Lisp_Object cmd;
1346 /* If this key is defined as a prefix in an inherited keymap,
1347 make it a prefix in this map, and make its definition
1348 inherit the other prefix definition. */
1353 }
1355 /* Append a key to the end of a key sequence. We always make a vector. */
1357 Lisp_Object
1360 {
1367 }
1369 /* Given a event type C which is a symbol,
1370 signal an error if is a mistake such as RET or M-RET or C-DEL, etc. */
1372 static void
1374 Lisp_Object c;
1375 {
1383 /* This alist includes elements such as ("RET" . "\\r"). */
1387 {
1390 Lisp_Object keystring;
1413 }
1414 }
1415 \f
1416 /* Global, local, and minor mode keymap stuff. */
1418 /* We can't put these variables inside current_minor_maps, since under
1419 some systems, static gets macro-defined to be the empty string.
1420 Ickypoo. */
1424 /* Store a pointer to an array of the currently active minor modes in
1425 *modeptr, a pointer to an array of the keymaps of the currently
1426 active minor modes in *mapptr, and return the number of maps
1427 *mapptr contains.
1429 This function always returns a pointer to the same buffer, and may
1430 free or reallocate it, so if you want to keep it for a long time or
1431 hand it out to lisp code, copy it. This procedure will be called
1432 for every key sequence read, so the nice lispy approach (return a
1433 new assoclist, list, what have you) for each invocation would
1434 result in a lot of consing over time.
1436 If we used xrealloc/xmalloc and ran out of memory, they would throw
1437 back to the command loop, which would try to read a key sequence,
1438 which would call this function again, resulting in an infinite
1439 loop. Instead, we'll use realloc/malloc and silently truncate the
1440 list, let the key sequence be read, and hope some other piece of
1441 code signals the error. */
1442 int
1445 {
1449 Lisp_Object emulation_alists;
1457 {
1459 {
1465 }
1466 else
1474 {
1475 Lisp_Object temp;
1477 /* If a variable has an entry in Vminor_mode_overriding_map_alist,
1478 and also an entry in Vminor_mode_map_alist,
1479 ignore the latter. */
1481 {
1485 }
1488 {
1495 /* Use malloc here. See the comment above this function.
1496 Avoid realloc here; it causes spurious traps on GNU/Linux [KFS] */
1497 BLOCK_INPUT;
1500 {
1502 {
1505 }
1507 }
1511 {
1513 {
1516 }
1518 }
1519 UNBLOCK_INPUT;
1524 }
1526 /* Get the keymap definition--or nil if it is not defined. */
1529 {
1532 i++;
1533 }
1534 }
1535 }
1540 }
1545 OLP if non-nil indicates that we should obey `overriding-local-map' and
1548 Lisp_Object olp;
1549 {
1553 {
1556 /* The doc said that overriding-terminal-local-map should
1557 override overriding-local-map. The code used them both,
1558 but it seems clearer to use just one. rms, jan 2005. */
1561 }
1563 {
1564 Lisp_Object local;
1568 /* This usually returns the buffer's local map,
1569 but that can be overridden by a `local-map' property. */
1574 /* Now put all the minor mode keymaps on the list. */
1581 /* This returns nil unless there is a `keymap' property. */
1585 }
1588 }
1590 /* GC is possible in this function if it autoloads a keymap. */
1594 KEY is a string or vector, a sequence of keystrokes.
1595 The binding is probably a symbol with a function definition.
1597 Normally, `key-binding' ignores bindings for t, which act as default
1598 bindings, used when nothing else in the keymap applies; this makes it
1599 usable as a general function for probing keymaps. However, if the
1600 optional second argument ACCEPT-DEFAULT is non-nil, `key-binding' does
1601 recognize the default bindings, just as `read-key-sequence' does.
1603 Like the normal command loop, `key-binding' will remap the command
1604 resulting from looking up KEY by looking up the command in the
1605 current keymaps. However, if the optional third argument NO-REMAP
1606 is non-nil, `key-binding' returns the unmapped command.
1608 If KEY is a key sequence initiated with the mouse, the used keymaps
1609 will depend on the clicked mouse position with regard to the buffer
1610 and possible local keymaps on strings.
1612 If the optional argument POSITION is non-nil, it specifies a mouse
1613 position as returned by `event-start' and `event-end', and the lookup
1614 occurs in the keymaps associated with it instead of KEY. It can also
1615 be a number or marker, in which case the keymap properties at the
1616 specified buffer position instead of point are used.
1620 {
1629 {
1630 Lisp_Object event
1631 /* mouse events may have a symbolic prefix indicating the
1632 scrollbar or mode line */
1635 /* We are not interested in locations without event data */
1638 {
1642 }
1643 }
1645 /* Key sequences beginning with mouse clicks
1646 are read using the keymaps of the buffer clicked on, not
1647 the current buffer. So we may have to switch the buffer
1648 here. */
1651 {
1652 Lisp_Object window;
1659 {
1660 /* Arrange to go back to the original buffer once we're done
1661 processing the key sequence. We don't use
1662 save_excursion_{save,restore} here, in analogy to
1663 `read-key-sequence' to avoid saving point. Maybe this
1664 would not be a problem here, but it is easier to keep
1665 things the same.
1666 */
1671 }
1672 }
1675 {
1680 }
1682 {
1686 }
1687 else
1688 {
1690 EMACS_INT pt;
1700 {
1701 Lisp_Object string;
1703 /* For a mouse click, get the local text-property keymap
1704 of the place clicked on, rather than point. */
1707 {
1708 Lisp_Object pos;
1713 {
1719 }
1720 }
1722 /* If on a mode line string with a local keymap,
1723 or for a click on a string, i.e. overlay string or a
1724 string displayed via the `display' property,
1725 consider `local-map' and `keymap' properties of
1726 that string. */
1730 {
1738 {
1746 }
1747 }
1749 }
1752 {
1756 }
1759 /* Note that all these maps are GCPRO'd
1760 in the places where we found them. */
1764 {
1768 }
1771 {
1775 }
1776 }
1780 done:
1783 UNGCPRO;
1787 /* If the result of the ordinary keymap lookup is an interactive
1788 command, look for a key binding (ie. remapping) for that command. */
1791 {
1792 Lisp_Object value1;
1795 }
1798 }
1800 /* GC is possible in this function if it autoloads a keymap. */
1804 KEYS is a string or vector, a sequence of keystrokes.
1805 The binding is probably a symbol with a function definition.
1807 If optional argument ACCEPT-DEFAULT is non-nil, recognize default
1811 {
1817 }
1819 /* GC is possible in this function if it autoloads a keymap. */
1823 KEYS is a string or vector, a sequence of keystrokes.
1824 The binding is probably a symbol with a function definition.
1825 This function's return values are the same as those of `lookup-key'
1826 \(which see).
1828 If optional argument ACCEPT-DEFAULT is non-nil, recognize default
1832 {
1834 }
1836 /* GC is possible in this function if it autoloads a keymap. */
1840 Return an alist of pairs (MODENAME . BINDING), where MODENAME is
1841 the symbol which names the minor mode binding KEY, and BINDING is
1842 KEY's definition in that mode. In particular, if KEY has no
1843 minor-mode bindings, return nil. If the first binding is a
1844 non-prefix, all subsequent bindings will be omitted, since they would
1845 be ignored. Similarly, the list doesn't include non-prefix bindings
1846 that come after prefix bindings.
1848 If optional argument ACCEPT-DEFAULT is non-nil, recognize default
1852 {
1855 Lisp_Object binding;
1860 /* Note that all these maps are GCPRO'd
1861 in the places where we found them. */
1870 {
1875 }
1877 UNGCPRO;
1879 }
1883 A new sparse keymap is stored as COMMAND's function definition and its value.
1884 If a second optional argument MAPVAR is given, the map is stored as
1885 its value instead of as COMMAND's value; but COMMAND is still defined
1886 as a function.
1887 The third optional argument NAME, if given, supplies a menu name
1888 string for the map. This is required to use the keymap as a menu.
1892 {
1893 Lisp_Object map;
1898 else
1901 }
1906 Lisp_Object keymap;
1907 {
1912 }
1918 Lisp_Object keymap;
1919 {
1926 }
1930 ()
1931 {
1933 }
1937 ()
1938 {
1940 }
1944 ()
1945 {
1950 }
1951 \f
1952 /* Help functions for describing and documenting keymaps. */
1955 static void
1959 {
1960 Lisp_Object tem;
1966 /* Look for and break cycles. */
1968 {
1976 i++;
1978 /* `prefix' is a prefix of `thisseq' => there's a cycle. */
1980 }
1981 /* This occurrence of `cmd' in `maps' does not correspond to a cycle,
1982 but maybe `cmd' occurs again further down in `maps', so keep
1983 looking. */
1985 }
1987 /* If the last key in thisseq is meta-prefix-char,
1988 turn it into a meta-ized keystroke. We know
1989 that the event we're about to append is an
1990 ascii keystroke since we're processing a
1991 keymap table. */
1993 {
2000 /* This new sequence is the same length as
2001 thisseq, so stick it in the list right
2002 after this one. */
2005 }
2006 else
2007 {
2010 }
2011 }
2013 static void
2016 {
2022 }
2024 /* This function cannot GC. */
2029 Returns a list of elements of the form (KEYS . MAP), where the sequence
2030 KEYS starting from KEYMAP gets you to MAP. These elements are ordered
2031 so that the KEYS increase in length. The first element is ([] . KEYMAP).
2032 An optional argument PREFIX, if non-nil, should be a key sequence;
2036 {
2040 /* no need for gcpro because we don't autoload any keymaps. */
2046 {
2047 /* If a prefix was specified, start with the keymap (if any) for
2048 that prefix, so we don't waste time considering other prefixes. */
2049 Lisp_Object tem;
2051 /* Flookup_key may give us nil, or a number,
2052 if the prefix is not defined in this particular map.
2053 It might even give us a list that isn't a keymap. */
2056 {
2057 /* Convert PREFIX to a vector now, so that later on
2058 we don't have to deal with the possibility of a string. */
2060 {
2062 Lisp_Object copy;
2066 {
2073 }
2075 }
2077 }
2078 else
2080 }
2081 else
2084 Qnil);
2086 /* For each map in the list maps,
2087 look at any other maps it points to,
2088 and stick them at the end if they are not already in the list.
2090 This is a breadth-first traversal, where tail is the queue of
2091 nodes, and maps accumulates a list of all nodes visited. */
2094 {
2096 Lisp_Object last;
2097 /* Does the current sequence end in the meta-prefix-char? */
2104 /* Don't metize the last char of PREFIX. */
2109 {
2110 Lisp_Object elt;
2114 QUIT;
2117 {
2124 }
2126 {
2129 /* Vector keymap. Scan all the elements. */
2134 }
2140 }
2141 }
2144 }
2145 \f
2148 /* This function cannot GC. */
2152 Optional arg PREFIX is the sequence of keys leading up to KEYS.
2153 Control characters turn into "C-foo" sequences, meta into "M-foo",
2157 {
2162 Lisp_Object list;
2164 Lisp_Object key;
2170 /* This has one extra element at the end that we don't pass to Fconcat. */
2173 /* In effect, this computes
2174 (mapconcat 'single-key-description keys " ")
2175 but we shouldn't use mapconcat because it can do GC. */
2177 next_list:
2182 else
2183 {
2185 {
2188 }
2192 }
2200 else
2206 {
2208 {
2214 }
2216 {
2218 }
2219 else
2220 {
2223 i++;
2224 }
2227 {
2231 {
2236 }
2237 else
2240 }
2242 {
2245 }
2248 }
2250 }
2258 {
2262 /* Clear all the meaningless bits above the meta bit. */
2269 {
2270 /* KEY_DESCRIPTION_SIZE is large enough for this. */
2273 }
2276 {
2280 }
2283 {
2287 }
2289 {
2293 }
2295 {
2299 }
2301 {
2305 }
2307 {
2311 }
2313 {
2315 {
2319 }
2321 {
2325 }
2327 {
2331 }
2332 else
2333 {
2334 /* `C-' already added above. */
2337 else
2339 }
2340 }
2342 {
2346 }
2348 {
2352 }
2357 {
2359 }
2360 else
2361 {
2363 {
2367 }
2369 {
2372 /* The biggest character code uses 19 bits. */
2374 {
2377 }
2378 }
2379 else
2381 }
2384 }
2386 /* This function cannot GC. */
2391 Control characters turn into C-whatever, etc.
2392 Optional argument NO-ANGLES non-nil means don't put angle brackets
2396 {
2403 {
2409 else
2413 {
2418 }
2421 {
2422 /* Handle a generic character. */
2423 Lisp_Object name;
2429 /* Only a charset is specified. */
2431 else
2432 /* 1st code-point of 2-dimensional charset is specified. */
2435 }
2436 else
2437 {
2440 Lisp_Object string;
2446 {
2449 }
2450 else
2453 }
2454 }
2456 {
2458 {
2463 }
2464 else
2466 }
2469 else
2472 }
2478 {
2480 {
2484 }
2486 {
2489 }
2491 {
2494 }
2495 else
2498 }
2500 /* This function cannot GC. */
2504 Control characters turn into "^char", etc. This differs from
2505 `single-key-description' which turns them into "C-char".
2506 Also, this function recognizes the 2**7 bit as the Meta character,
2507 whereas `single-key-description' uses the 2**27 bit for Meta.
2510 Lisp_Object character;
2511 {
2512 /* Currently MAX_MULTIBYTE_LENGTH is 4 (< 6). */
2520 {
2524 }
2529 }
2531 /* Return non-zero if SEQ contains only ASCII characters, perhaps with
2532 a meta bit. */
2533 static int
2535 Lisp_Object seq;
2536 {
2541 {
2550 }
2553 }
2555 \f
2556 /* where-is - finding a command in a set of keymaps. */
2562 /* Like Flookup_key, but uses a list of keymaps SHADOW instead of a single map.
2563 Returns the first non-nil binding found in any of those maps. */
2565 static Lisp_Object
2568 {
2572 {
2575 {
2580 }
2583 }
2585 }
2589 /* This function can GC if Flookup_key autoloads any keymaps. */
2591 static Lisp_Object
2595 {
2599 /* 1 means ignore all menu bindings entirely. */
2604 {
2605 maps =
2609 }
2615 /* If this command is remapped, then it has no key bindings
2616 of its own. */
2623 {
2624 /* Key sequence to reach map, and the map that it reaches */
2627 /* In order to fold [META-PREFIX-CHAR CHAR] sequences into
2628 [M-CHAR] sequences, check if last character of the sequence
2629 is the meta-prefix char. */
2630 Lisp_Object last;
2639 /* if (nomenus && !ascii_sequence_p (this)) */
2643 /* If no menu entries should be returned, skip over the
2644 keymaps bound to `menu-bar' and `tool-bar' and other
2645 non-ascii prefixes like `C-down-mouse-2'. */
2648 QUIT;
2651 {
2652 /* Because the code we want to run on each binding is rather
2653 large, we don't want to have two separate loop bodies for
2654 sparse keymap bindings and tables; we want to iterate one
2655 loop body over both keymap and vector bindings.
2657 For this reason, if Fcar (map) is a vector, we don't
2658 advance map to the next element until i indicates that we
2659 have finished off the vector. */
2666 QUIT;
2668 /* Set key and binding to the current key and binding, and
2669 advance map and i to the next binding. */
2671 {
2672 Lisp_Object sequence;
2674 /* In a vector, look at each element. */
2676 {
2684 }
2685 }
2687 {
2689 Lisp_Object args;
2699 }
2701 {
2702 Lisp_Object sequence;
2712 }
2716 {
2722 /* If the current sequence is a command remapping with
2723 format [remap COMMAND], find the key sequences
2724 which run COMMAND, and use those sequences instead. */
2730 {
2731 Lisp_Object remapped1;
2735 {
2736 /* Verify that this key binding actually maps to the
2737 remapped command (see below). */
2743 }
2744 }
2746 /* Verify that this key binding is not shadowed by another
2747 binding for the same key, before we say it exists.
2749 Mechanism: look for local definition of this key and if
2750 it is defined and does not match what we found then
2751 ignore this key.
2753 Either nil or number as value from Flookup_key
2754 means undefined. */
2758 record_sequence:
2759 /* Don't annoy user with strings from a menu such as
2760 Select Paste. Change them all to "(any string)",
2761 so that there seems to be only one menu item
2762 to report. */
2764 {
2765 Lisp_Object tem;
2770 }
2772 /* It is a true unshadowed match. Record it, unless it's already
2773 been seen (as could happen when inheriting keymaps). */
2777 /* If firstonly is Qnon_ascii, then we can return the first
2778 binding we find. If firstonly is not Qnon_ascii but not
2779 nil, then we should return the first ascii-only binding
2780 we find. */
2787 {
2791 }
2792 }
2793 }
2794 }
2796 UNGCPRO;
2800 /* firstonly may have been t, but we may have gone all the way through
2801 the keymaps without finding an all-ASCII key sequence. So just
2802 return the best we could find. */
2807 }
2811 If KEYMAP is a keymap, search only KEYMAP and the global keymap.
2812 If KEYMAP is nil, search all the currently active keymaps.
2813 If KEYMAP is a list of keymaps, search only those keymaps.
2815 If optional 3rd arg FIRSTONLY is non-nil, return the first key sequence found,
2816 rather than a list of all possible key sequences.
2817 If FIRSTONLY is the symbol `non-ascii', return the first binding found,
2818 no matter what it is.
2819 If FIRSTONLY has another non-nil value, prefer sequences of ASCII characters
2820 \(or their meta variants) and entirely reject menu bindings.
2822 If optional 4th arg NOINDIRECT is non-nil, don't follow indirections
2823 to other keymaps or slots. This makes it possible to search for an
2824 indirect definition itself.
2826 If optional 5th arg NO-REMAP is non-nil, don't search for key sequences
2827 that invoke a command which is remapped to DEFINITION, but include the
2832 {
2834 /* 1 means ignore all menu bindings entirely. */
2836 Lisp_Object result;
2838 /* Find the relevant keymaps. */
2843 else
2846 /* Only use caching for the menubar (i.e. called with (def nil t nil).
2847 We don't really need to check `keymap'. */
2849 {
2854 /* Check heuristic-consistency of the cache. */
2859 {
2860 /* We need to create the cache. */
2865 /* Fill in the cache. */
2868 UNGCPRO;
2871 }
2873 /* We want to process definitions from the last to the first.
2874 Instead of consing, copy definitions to a vector and step
2875 over that vector. */
2882 /* Verify that the key bindings are not shadowed. Note that
2883 the following can GC. */
2889 {
2894 }
2897 UNGCPRO;
2898 }
2899 else
2900 {
2901 /* Kill the cache so that where_is_internal_1 doesn't think
2902 we're filling it up. */
2905 }
2908 }
2910 /* This is the function that Fwhere_is_internal calls using map_char_table.
2911 ARGS has the form
2912 (((DEFINITION . NOINDIRECT) . (KEYMAP . RESULT))
2913 .
2914 ((THIS . LAST) . (NOMENUS . LAST_IS_META)))
2915 Since map_char_table doesn't really use the return value from this function,
2916 we the result append to RESULT, the slot in ARGS.
2918 This function can GC because it calls where_is_internal_1 which can
2919 GC. */
2921 static void
2924 {
2945 UNGCPRO;
2946 }
2949 /* This function can GC because get_keyelt can. */
2951 static Lisp_Object
2956 {
2957 Lisp_Object sequence;
2959 /* Search through indirections unless that's not wanted. */
2963 /* End this iteration if this element does not match
2964 the target. */
2969 /* Doesn't match. */
2972 /* We have found a match. Construct the key sequence where we found it. */
2974 {
2977 }
2978 else
2982 {
2986 }
2987 else
2989 }
2990 \f
2991 /* describe-bindings - summarizing all the bindings in a set of keymaps. */
2993 DEFUN ("describe-buffer-bindings", Fdescribe_buffer_bindings, Sdescribe_buffer_bindings, 1, 3, 0,
2995 The list is inserted in the current buffer, while the bindings are
2996 looked up in BUFFER.
2997 The optional argument PREFIX, if non-nil, should be a key sequence;
2998 then we display only bindings that start with that prefix.
2999 The optional argument MENUS, if non-nil, says to mention menu bindings.
3003 {
3022 /* Report on alternates for keys. */
3024 {
3031 {
3036 {
3039 }
3049 /* Insert calls signal_after_change which may GC. */
3051 }
3054 }
3061 /* Print the (major mode) local map. */
3069 {
3073 }
3074 else
3075 {
3076 /* Print the minor mode and major mode keymaps. */
3080 /* Temporarily switch to `buffer', so that we can get that buffer's
3081 minor modes correctly. */
3090 {
3095 }
3097 /* Print the minor mode maps. */
3099 {
3100 /* The title for a minor mode keymap
3101 is constructed at run time.
3102 We let describe_map_tree do the actual insertion
3103 because it takes care of other features when doing so. */
3124 }
3129 {
3133 else
3139 }
3140 }
3145 /* Print the function-key-map translations under this prefix. */
3150 UNGCPRO;
3152 }
3154 /* Insert a description of the key bindings in STARTMAP,
3155 followed by those of all maps reachable through STARTMAP.
3156 If PARTIAL is nonzero, omit certain "uninteresting" commands
3157 (such as `undefined').
3158 If SHADOW is non-nil, it is a list of maps;
3159 don't mention keys which would be shadowed by any of them.
3160 PREFIX, if non-nil, says mention only keys that start with PREFIX.
3161 TITLE, if not 0, is a string to insert at the beginning.
3162 TITLE should not end with a colon or a newline; we supply that.
3163 If NOMENU is not 0, then omit menu-bar commands.
3165 If TRANSL is nonzero, the definitions are actually key translations
3166 so print strings and vectors differently.
3168 If ALWAYS_TITLE is nonzero, print the title even if there are no maps
3169 to look through.
3171 If MENTION_SHADOW is nonzero, then when something is shadowed by SHADOW,
3172 don't omit it; instead, mention it but say it is shadowed. */
3174 void
3184 {
3199 {
3200 Lisp_Object list;
3202 /* Delete from MAPS each element that is for the menu bar. */
3204 {
3210 {
3214 }
3215 }
3216 }
3219 {
3221 {
3224 {
3227 }
3229 }
3232 }
3235 {
3244 {
3245 Lisp_Object shmap;
3249 /* If the sequence by which we reach this keymap is zero-length,
3250 then the shadow map for this keymap is just SHADOW. */
3253 ;
3254 /* If the sequence by which we reach this keymap actually has
3255 some elements, then the sequence's definition in SHADOW is
3256 what we should use. */
3257 else
3258 {
3262 }
3264 /* If shmap is not nil and not a keymap,
3265 it completely shadows this map, so don't
3266 describe this map at all. */
3272 }
3274 /* Maps we have already listed in this loop shadow this map. */
3276 {
3277 Lisp_Object tem;
3281 }
3287 skip: ;
3288 }
3293 UNGCPRO;
3294 }
3298 static void
3301 {
3306 /* If column 16 is no good, go to col 32;
3307 but don't push beyond that--go to next line instead. */
3309 {
3312 }
3315 else
3322 {
3326 }
3331 else
3333 }
3335 static void
3338 {
3344 {
3348 }
3350 {
3353 }
3356 else
3358 }
3360 /* describe_map puts all the usable elements of a sparse keymap
3361 into an array of `struct describe_map_elt',
3362 then sorts them by the events. */
3366 /* qsort comparison function for sorting `struct describe_map_elt' by
3367 the event field. */
3369 static int
3372 {
3386 }
3388 /* Describe the contents of map MAP, assuming that this map itself is
3389 reached by the sequence of prefix keys PREFIX (a string or vector).
3390 PARTIAL, SHADOW, NOMENU are as in `describe_map_tree' above. */
3392 static void
3396 Lisp_Object prefix;
3399 Lisp_Object shadow;
3403 {
3405 Lisp_Object tem;
3406 Lisp_Object suppress;
3407 Lisp_Object kludge;
3411 /* These accumulate the values from sparse keymap bindings,
3412 so we can sort them and handle them in order. */
3423 /* This vector gets used to present single keys to Flookup_key. Since
3424 that is done once per keymap element, we don't want to cons up a
3425 fresh vector every time. */
3430 length_needed++;
3438 {
3439 QUIT;
3447 {
3452 /* Ignore bindings whose "prefix" are not really valid events.
3453 (We get these in the frames and buffers menu.) */
3462 /* Don't show undefined commands or suppressed commands. */
3465 {
3469 }
3471 /* Don't show a command that isn't really visible
3472 because a local definition of the same key shadows it. */
3476 {
3479 {
3480 /* If both bindings are keymaps, this key is a prefix key,
3481 so don't say it is shadowed. */
3483 ;
3484 /* Avoid generating duplicate entries if the
3485 shadowed binding has the same definition. */
3488 else
3490 }
3491 }
3499 slots_used++;
3500 }
3502 {
3503 /* The same keymap might be in the structure twice, if we're
3504 using an inherited keymap. So skip anything we've already
3505 encountered. */
3510 }
3511 }
3513 /* If we found some sparse map events, sort them. */
3516 describe_map_compare);
3518 /* Now output them in sorted order. */
3521 {
3525 {
3529 }
3537 /* Find consecutive chars that are identically defined. */
3539 {
3544 i++;
3546 }
3548 /* Now START .. END is the range to describe next. */
3550 /* Insert the string to describe the event START. */
3554 {
3558 /* Insert the string to describe the character END. */
3560 }
3562 /* Print a description of the definition of this character.
3563 elt_describer will take care of spacing out far enough
3564 for alignment purposes. */
3568 {
3572 }
3573 }
3575 UNGCPRO;
3576 }
3578 static void
3581 {
3585 }
3589 This is text showing the elements of vector matched against indices.
3593 {
3603 }
3605 /* Insert in the current buffer a description of the contents of VECTOR.
3606 We call ELT_DESCRIBER to insert the description of one value found
3607 in VECTOR.
3609 ELT_PREFIX describes what "comes before" the keys or indices defined
3610 by this vector. This is a human-readable string whose size
3611 is not necessarily related to the situation.
3613 If the vector is in a keymap, ELT_PREFIX is a prefix key which
3614 leads to this keymap.
3616 If the vector is a chartable, ELT_PREFIX is the vector
3617 of bytes that lead to the character set or portion of a character
3618 set described by this chartable.
3620 If PARTIAL is nonzero, it means do not mention suppressed commands
3621 (that assumes the vector is in a keymap).
3623 SHADOW is a list of keymaps that shadow this map.
3624 If it is non-nil, then we look up the key in those maps
3625 and we don't mention it now if it is defined by any of them.
3627 ENTIRE_MAP is the keymap in which this vector appears.
3628 If the definition in effect in the whole map does not match
3629 the one in this vector, we ignore this one.
3631 When describing a sub-char-table, INDICES is a list of
3632 indices at higher levels in this char-table,
3633 and CHAR_TABLE_DEPTH says how many levels down we have gone.
3635 KEYMAP_P is 1 if vector is known to be a keymap, so map ESC to M-.
3637 ARGS is simply passed as the second argument to ELT_DESCRIBER. */
3639 static void
3643 mention_shadow)
3648 Lisp_Object shadow;
3649 Lisp_Object entire_map;
3654 {
3655 Lisp_Object definition;
3656 Lisp_Object tem2;
3659 Lisp_Object suppress;
3660 Lisp_Object kludge;
3663 /* Range of elements to be handled. */
3665 /* A flag to tell if a leaf in this level of char-table is not a
3666 generic character (i.e. a complete multibyte character). */
3679 {
3680 /* Call Fkey_description first, to avoid GC bug for the other string. */
3682 {
3683 Lisp_Object tem;
3686 }
3688 }
3690 /* This vector gets used to present single keys to Flookup_key. Since
3691 that is done once per vector element, we don't want to cons up a
3692 fresh vector every time. */
3700 {
3702 {
3703 /* VECTOR is a top level char-table. */
3707 }
3708 else
3709 {
3710 /* VECTOR is a sub char-table. */
3712 /* A char-table is never that deep. */
3715 complete_char
3721 /* Meaningful elements are from 32th to 127th. */
3724 }
3725 }
3726 else
3727 {
3728 /* This does the right thing for ordinary vectors. */
3733 }
3736 {
3738 QUIT;
3741 {
3749 definition
3751 }
3752 else
3757 /* Don't mention suppressed commands. */
3759 {
3760 Lisp_Object tem;
3765 }
3767 /* Set CHARACTER to the character this entry describes, if any.
3768 Also update *INDICES. */
3770 {
3774 {
3777 }
3779 {
3781 }
3782 else
3784 }
3785 else
3790 /* If this binding is shadowed by some other map, ignore it. */
3792 {
3793 Lisp_Object tem;
3798 {
3801 else
3803 }
3804 }
3806 /* Ignore this definition if it is shadowed by an earlier
3807 one in the same keymap. */
3809 {
3810 Lisp_Object tem;
3816 }
3819 {
3823 }
3825 /* For a sub char-table, show the depth by indentation.
3826 CHAR_TABLE_DEPTH can be greater than 0 only for a char-table. */
3830 /* Output the prefix that applies to every entry in this map. */
3834 /* Insert or describe the character this slot is for,
3835 or a description of what it is for. */
3837 {
3840 else
3841 {
3842 /* We need an octal representation for this block of
3843 characters. */
3847 }
3848 }
3850 {
3853 else
3854 {
3855 /* Print the information for this character set. */
3861 else
3864 }
3865 }
3866 else
3867 {
3869 }
3871 /* If we find a sub char-table within a char-table,
3872 scan it recursively; it defines the details for
3873 a character set or a portion of a character set. */
3875 {
3880 mention_shadow);
3882 }
3886 /* Find all consecutive characters or rows that have the same
3887 definition. But, for elements of a top level char table, if
3888 they are for charsets, we had better describe one by one even
3889 if they have the same definition. */
3891 {
3901 i++;
3902 }
3903 else
3908 i++;
3911 /* If we have a range of more than one character,
3912 print where the range reaches to. */
3915 {
3924 {
3926 {
3928 }
3930 {
3934 }
3935 else
3936 {
3937 /* We need an octal representation for this block of
3938 characters. */
3942 }
3943 }
3944 else
3945 {
3947 }
3948 }
3950 /* Print a description of the definition of this character.
3951 elt_describer will take care of spacing out far enough
3952 for alignment purposes. */
3956 {
3960 }
3961 }
3963 /* For (sub) char-table, print `defalt' slot at last. */
3965 {
3969 }
3971 UNGCPRO;
3972 }
3973 \f
3974 /* Apropos - finding all symbols whose names match a regexp. */
3978 static void
3981 {
3989 }
3993 If optional 2nd arg PREDICATE is non-nil, (funcall PREDICATE SYMBOL) is done
3994 for each symbol and a symbol is mentioned only if that returns non-nil.
3998 {
3999 Lisp_Object tem;
4008 }
4009 \f
4010 void
4012 {
4020 /* Now we are ready to set up this property, so we can
4021 create char tables. */
4024 /* Initialize the keymaps standardly used.
4025 Each one is the value of a Lisp variable, and is also
4026 pointed to by a C variable */
4043 exclude_keys
4049 Qnil)))));
4054 This is used for internal purposes during Emacs startup;
4077 Vminibuffer_local_completion_map);
4084 Vminibuffer_local_completion_map);
4091 Vminibuffer_local_must_match_map);
4095 Each element looks like (VARIABLE . KEYMAP); KEYMAP is used to read
4096 key sequences and look up bindings if VARIABLE's value is non-nil.
4097 If two active keymaps bind the same key, the keymap appearing earlier
4103 This variable is an alist just like `minor-mode-map-alist', and it is
4104 used the same way (and before `minor-mode-map-alist'); however,
4110 It is intended for modes or packages using multiple minor-mode keymaps.
4111 Each element is a keymap alist just like `minor-mode-map-alist', or a
4112 symbol with a variable binding which is a keymap alist, and it is used
4113 the same way. The "active" keymaps in each alist are used before
4120 This is used mainly for mapping ASCII function key sequences into
4121 real Emacs function key events (symbols).
4123 The `read-key-sequence' function replaces any subsequence bound by
4124 `function-key-map' with its binding. More precisely, when the active
4125 keymaps have no binding for the current key sequence but
4126 `function-key-map' binds a suffix of the sequence to a vector or string,
4127 `read-key-sequence' replaces the matching suffix with its binding, and
4128 continues with the new sequence.
4130 If the binding is a function, it is called with one argument (the prompt)
4131 and its return value (a key sequence) is used.
4133 The events that come from bindings in `function-key-map' are not
4134 themselves looked up in `function-key-map'.
4136 For example, suppose `function-key-map' binds `ESC O P' to [f1].
4137 Typing `ESC O P' to `read-key-sequence' would return [f1]. Typing
4138 `C-x ESC O P' would return [?\\C-x f1]. If [f1] were a prefix
4144 This keymap works like `function-key-map', but comes after that,
4158 Qnil)))))))));
4217 }
4219 void
4221 {
4224 }
4226 /* arch-tag: 6dd15c26-7cf1-41c4-b904-f42f7ddda463
4227 (do not change this comment) */