When the read-key-sequence
function reads a key sequence (see Key Sequence Input), it uses translation keymaps to translate certain event sequences into others. The translation keymaps are input-decode-map
, local-function-key-map
, and key-translation-map
(in order of priority).
Translation keymaps have the same structure as other keymaps, but are used differently: they specify translations to make while reading key sequences, rather than bindings for complete key sequences. As each key sequence is read, it is checked against each translation keymap. If one of the translation keymaps binds k to a vector v, then whenever k appears as a sub-sequence anywhere in a key sequence, that sub-sequence is replaced with the events in v.
For example, VT100 terminals send ESC O P when the keypad key PF1 is pressed. On such terminals, Emacs must translate that sequence of events into a single event pf1
. This is done by binding ESC O P to [pf1]
in input-decode-map
. Thus, when you type C-c PF1 on the terminal, the terminal emits the character sequence C-c ESC O P, and read-key-sequence
translates this back into C-c PF1 and returns it as the vector [?\C-c pf1]
.
Translation keymaps take effect only after Emacs has decoded the keyboard input (via the input coding system specified by keyboard-coding-system
). See Terminal I/O Encoding.
This variable holds a keymap that describes the character sequences sent by function keys on an ordinary character terminal.
The value of input-decode-map
is usually set up automatically according to the terminal’s Terminfo or Termcap entry, but sometimes those need help from terminal-specific Lisp files. Emacs comes with terminal-specific files for many common terminals; their main purpose is to make entries in input-decode-map
beyond those that can be deduced from Termcap and Terminfo. See Terminal-Specific.
This variable holds a keymap similar to input-decode-map
except that it describes key sequences which should be translated to alternative interpretations that are usually preferred. It applies after input-decode-map
and before key-translation-map
.
Entries in local-function-key-map
are ignored if they conflict with bindings made in the minor mode, local, or global keymaps. I.e., the remapping only applies if the original key sequence would otherwise not have any binding.
local-function-key-map
inherits from function-key-map
. The latter should only be altered if you want the binding to apply in all terminals, so using the former is almost always preferred.
This variable is another keymap used just like input-decode-map
to translate input events into other events. It differs from input-decode-map
in that it goes to work after local-function-key-map
is finished rather than before; it receives the results of translation by local-function-key-map
.
Just like input-decode-map
, but unlike local-function-key-map
, this keymap is applied regardless of whether the input key-sequence has a normal binding. Note however that actual key bindings can have an effect on key-translation-map
, even though they are overridden by it. Indeed, actual key bindings override local-function-key-map
and thus may alter the key sequence that key-translation-map
receives. Clearly, it is better to avoid this type of situation.
The intent of key-translation-map
is for users to map one character set to another, including ordinary characters normally bound to self-insert-command
.
You can use input-decode-map
, local-function-key-map
, and key-translation-map
for more than simple aliases, by using a function, instead of a key sequence, as the translation of a key. Then this function is called to compute the translation of that key.
The key translation function receives one argument, which is the prompt that was specified in read-key-sequence
—or nil
if the key sequence is being read by the editor command loop. In most cases you can ignore the prompt value.
If the function reads input itself, it can have the effect of altering the event that follows. For example, here’s how to define C-c h to turn the character that follows into a Hyper character:
(defun hyperify (prompt) (let ((e (read-event))) (vector (if (numberp e) (logior (ash 1 24) e) (if (memq 'hyper (event-modifiers e)) e (add-event-modifier "H-" e)))))) (defun add-event-modifier (string e) (let ((symbol (if (symbolp e) e (car e)))) (setq symbol (intern (concat string (symbol-name symbol)))) (if (symbolp e) symbol (cons symbol (cdr e))))) (define-key local-function-key-map "\C-ch" 'hyperify)
The end of a key sequence is detected when that key sequence either is bound to a command, or when Emacs determines that no additional event can lead to a sequence that is bound to a command.
This means that, while input-decode-map
and key-translation-map
apply regardless of whether the original key sequence would have a binding, the presence of such a binding can still prevent translation from taking place. For example, let us return to our VT100 example above and add a binding for C-c ESC to the global map; now when the user hits C-c PF1 Emacs will fail to decode C-c ESC O P into C-c PF1 because it will stop reading keys right after C-x ESC, leaving O P for later. This is in case the user really hit C-c ESC, in which case Emacs should not sit there waiting for the next key to decide whether the user really pressed ESC or PF1.
For that reason, it is better to avoid binding commands to key sequences where the end of the key sequence is a prefix of a key translation. The main such problematic suffixes/prefixes are ESC, M-O (which is really ESC O) and M-[ (which is really ESC [).
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Licensed under the GNU GPL license.
https://www.gnu.org/software/emacs/manual/html_node/elisp/Translation-Keymaps.html