gdb/
[deliverable/binutils-gdb.git] / readline / readline.c
1 /* readline.c -- a general facility for reading lines of input
2 with emacs style editing and completion. */
3
4 /* Copyright (C) 1987-2009 Free Software Foundation, Inc.
5
6 This file is part of the GNU Readline Library (Readline), a library
7 for reading lines of text with interactive input and history editing.
8
9 Readline is free software: you can redistribute it and/or modify
10 it under the terms of the GNU General Public License as published by
11 the Free Software Foundation, either version 3 of the License, or
12 (at your option) any later version.
13
14 Readline is distributed in the hope that it will be useful,
15 but WITHOUT ANY WARRANTY; without even the implied warranty of
16 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17 GNU General Public License for more details.
18
19 You should have received a copy of the GNU General Public License
20 along with Readline. If not, see <http://www.gnu.org/licenses/>.
21 */
22
23 #define READLINE_LIBRARY
24
25 #if defined (HAVE_CONFIG_H)
26 # include <config.h>
27 #endif
28
29 #include <sys/types.h>
30 #include "posixstat.h"
31 #include <fcntl.h>
32 #if defined (HAVE_SYS_FILE_H)
33 # include <sys/file.h>
34 #endif /* HAVE_SYS_FILE_H */
35
36 #if defined (HAVE_UNISTD_H)
37 # include <unistd.h>
38 #endif /* HAVE_UNISTD_H */
39
40 #if defined (HAVE_STDLIB_H)
41 # include <stdlib.h>
42 #else
43 # include "ansi_stdlib.h"
44 #endif /* HAVE_STDLIB_H */
45
46 #if defined (HAVE_LOCALE_H)
47 # include <locale.h>
48 #endif
49
50 #include <stdio.h>
51 #include "posixjmp.h"
52 #include <errno.h>
53
54 #if !defined (errno)
55 extern int errno;
56 #endif /* !errno */
57
58 /* System-specific feature definitions and include files. */
59 #include "rldefs.h"
60 #include "rlmbutil.h"
61
62 #if defined (__EMX__)
63 # define INCL_DOSPROCESS
64 # include <os2.h>
65 #endif /* __EMX__ */
66
67 /* Some standard library routines. */
68 #include "readline.h"
69 #include "history.h"
70
71 #include "rlprivate.h"
72 #include "rlshell.h"
73 #include "xmalloc.h"
74
75 #ifndef RL_LIBRARY_VERSION
76 # define RL_LIBRARY_VERSION "5.1"
77 #endif
78
79 #ifndef RL_READLINE_VERSION
80 # define RL_READLINE_VERSION 0x0501
81 #endif
82
83 extern void _rl_free_history_entry PARAMS((HIST_ENTRY *));
84
85 /* Forward declarations used in this file. */
86 static char *readline_internal PARAMS((void));
87 static void readline_initialize_everything PARAMS((void));
88
89 static void bind_arrow_keys_internal PARAMS((Keymap));
90 static void bind_arrow_keys PARAMS((void));
91
92 static void readline_default_bindings PARAMS((void));
93 static void reset_default_bindings PARAMS((void));
94
95 static int _rl_subseq_result PARAMS((int, Keymap, int, int));
96 static int _rl_subseq_getchar PARAMS((int));
97
98 /* **************************************************************** */
99 /* */
100 /* Line editing input utility */
101 /* */
102 /* **************************************************************** */
103
104 const char *rl_library_version = RL_LIBRARY_VERSION;
105
106 int rl_readline_version = RL_READLINE_VERSION;
107
108 /* True if this is `real' readline as opposed to some stub substitute. */
109 int rl_gnu_readline_p = 1;
110
111 /* A pointer to the keymap that is currently in use.
112 By default, it is the standard emacs keymap. */
113 Keymap _rl_keymap = emacs_standard_keymap;
114
115
116 /* The current style of editing. */
117 int rl_editing_mode = emacs_mode;
118
119 /* The current insert mode: input (the default) or overwrite */
120 int rl_insert_mode = RL_IM_DEFAULT;
121
122 /* Non-zero if we called this function from _rl_dispatch(). It's present
123 so functions can find out whether they were called from a key binding
124 or directly from an application. */
125 int rl_dispatching;
126
127 /* Non-zero if the previous command was a kill command. */
128 int _rl_last_command_was_kill = 0;
129
130 /* The current value of the numeric argument specified by the user. */
131 int rl_numeric_arg = 1;
132
133 /* Non-zero if an argument was typed. */
134 int rl_explicit_arg = 0;
135
136 /* Temporary value used while generating the argument. */
137 int rl_arg_sign = 1;
138
139 /* Non-zero means we have been called at least once before. */
140 static int rl_initialized;
141
142 #if 0
143 /* If non-zero, this program is running in an EMACS buffer. */
144 static int running_in_emacs;
145 #endif
146
147 /* Flags word encapsulating the current readline state. */
148 int rl_readline_state = RL_STATE_NONE;
149
150 /* The current offset in the current input line. */
151 int rl_point;
152
153 /* Mark in the current input line. */
154 int rl_mark;
155
156 /* Length of the current input line. */
157 int rl_end;
158
159 /* Make this non-zero to return the current input_line. */
160 int rl_done;
161
162 /* The last function executed by readline. */
163 rl_command_func_t *rl_last_func = (rl_command_func_t *)NULL;
164
165 /* Top level environment for readline_internal (). */
166 procenv_t _rl_top_level;
167
168 /* The streams we interact with. */
169 FILE *_rl_in_stream, *_rl_out_stream;
170
171 /* The names of the streams that we do input and output to. */
172 FILE *rl_instream = (FILE *)NULL;
173 FILE *rl_outstream = (FILE *)NULL;
174
175 /* Non-zero means echo characters as they are read. Defaults to no echo;
176 set to 1 if there is a controlling terminal, we can get its attributes,
177 and the attributes include `echo'. Look at rltty.c:prepare_terminal_settings
178 for the code that sets it. */
179 int _rl_echoing_p = 0;
180
181 /* Current prompt. */
182 char *rl_prompt = (char *)NULL;
183 int rl_visible_prompt_length = 0;
184
185 /* Set to non-zero by calling application if it has already printed rl_prompt
186 and does not want readline to do it the first time. */
187 int rl_already_prompted = 0;
188
189 /* The number of characters read in order to type this complete command. */
190 int rl_key_sequence_length = 0;
191
192 /* If non-zero, then this is the address of a function to call just
193 before readline_internal_setup () prints the first prompt. */
194 rl_hook_func_t *rl_startup_hook = (rl_hook_func_t *)NULL;
195
196 /* If non-zero, this is the address of a function to call just before
197 readline_internal_setup () returns and readline_internal starts
198 reading input characters. */
199 rl_hook_func_t *rl_pre_input_hook = (rl_hook_func_t *)NULL;
200
201 /* What we use internally. You should always refer to RL_LINE_BUFFER. */
202 static char *the_line;
203
204 /* The character that can generate an EOF. Really read from
205 the terminal driver... just defaulted here. */
206 int _rl_eof_char = CTRL ('D');
207
208 /* Non-zero makes this the next keystroke to read. */
209 int rl_pending_input = 0;
210
211 /* Pointer to a useful terminal name. */
212 const char *rl_terminal_name = (const char *)NULL;
213
214 /* Non-zero means to always use horizontal scrolling in line display. */
215 int _rl_horizontal_scroll_mode = 0;
216
217 /* Non-zero means to display an asterisk at the starts of history lines
218 which have been modified. */
219 int _rl_mark_modified_lines = 0;
220
221 /* The style of `bell' notification preferred. This can be set to NO_BELL,
222 AUDIBLE_BELL, or VISIBLE_BELL. */
223 int _rl_bell_preference = AUDIBLE_BELL;
224
225 /* String inserted into the line by rl_insert_comment (). */
226 char *_rl_comment_begin;
227
228 /* Keymap holding the function currently being executed. */
229 Keymap rl_executing_keymap;
230
231 /* Keymap we're currently using to dispatch. */
232 Keymap _rl_dispatching_keymap;
233
234 /* Non-zero means to erase entire line, including prompt, on empty input lines. */
235 int rl_erase_empty_line = 0;
236
237 /* Non-zero means to read only this many characters rather than up to a
238 character bound to accept-line. */
239 int rl_num_chars_to_read;
240
241 /* Line buffer and maintenence. */
242 char *rl_line_buffer = (char *)NULL;
243 int rl_line_buffer_len = 0;
244
245 /* Key sequence `contexts' */
246 _rl_keyseq_cxt *_rl_kscxt = 0;
247
248 /* Forward declarations used by the display, termcap, and history code. */
249
250 /* **************************************************************** */
251 /* */
252 /* `Forward' declarations */
253 /* */
254 /* **************************************************************** */
255
256 /* Non-zero means do not parse any lines other than comments and
257 parser directives. */
258 unsigned char _rl_parsing_conditionalized_out = 0;
259
260 /* Non-zero means to convert characters with the meta bit set to
261 escape-prefixed characters so we can indirect through
262 emacs_meta_keymap or vi_escape_keymap. */
263 int _rl_convert_meta_chars_to_ascii = 1;
264
265 /* Non-zero means to output characters with the meta bit set directly
266 rather than as a meta-prefixed escape sequence. */
267 int _rl_output_meta_chars = 0;
268
269 /* Non-zero means to look at the termios special characters and bind
270 them to equivalent readline functions at startup. */
271 int _rl_bind_stty_chars = 1;
272
273 /* Non-zero means to go through the history list at every newline (or
274 whenever rl_done is set and readline returns) and revert each line to
275 its initial state. */
276 int _rl_revert_all_at_newline = 0;
277
278 /* Non-zero means to honor the termios ECHOCTL bit and echo control
279 characters corresponding to keyboard-generated signals. */
280 int _rl_echo_control_chars = 1;
281
282 /* **************************************************************** */
283 /* */
284 /* Top Level Functions */
285 /* */
286 /* **************************************************************** */
287
288 /* Non-zero means treat 0200 bit in terminal input as Meta bit. */
289 int _rl_meta_flag = 0; /* Forward declaration */
290
291 /* Set up the prompt and expand it. Called from readline() and
292 rl_callback_handler_install (). */
293 int
294 rl_set_prompt (prompt)
295 const char *prompt;
296 {
297 FREE (rl_prompt);
298 rl_prompt = prompt ? savestring (prompt) : (char *)NULL;
299 rl_display_prompt = rl_prompt ? rl_prompt : "";
300
301 rl_visible_prompt_length = rl_expand_prompt (rl_prompt);
302 return 0;
303 }
304
305 /* Read a line of input. Prompt with PROMPT. An empty PROMPT means
306 none. A return value of NULL means that EOF was encountered. */
307 char *
308 readline (prompt)
309 const char *prompt;
310 {
311 char *value;
312 #if 0
313 int in_callback;
314 #endif
315
316 /* If we are at EOF return a NULL string. */
317 if (rl_pending_input == EOF)
318 {
319 rl_clear_pending_input ();
320 return ((char *)NULL);
321 }
322
323 #if 0
324 /* If readline() is called after installing a callback handler, temporarily
325 turn off the callback state to avoid ensuing messiness. Patch supplied
326 by the gdb folks. XXX -- disabled. This can be fooled and readline
327 left in a strange state by a poorly-timed longjmp. */
328 if (in_callback = RL_ISSTATE (RL_STATE_CALLBACK))
329 RL_UNSETSTATE (RL_STATE_CALLBACK);
330 #endif
331
332 rl_set_prompt (prompt);
333
334 rl_initialize ();
335 if (rl_prep_term_function)
336 (*rl_prep_term_function) (_rl_meta_flag);
337
338 #if defined (HANDLE_SIGNALS)
339 rl_set_signals ();
340 #endif
341
342 value = readline_internal ();
343 if (rl_deprep_term_function)
344 (*rl_deprep_term_function) ();
345
346 #if defined (HANDLE_SIGNALS)
347 rl_clear_signals ();
348 #endif
349
350 #if 0
351 if (in_callback)
352 RL_SETSTATE (RL_STATE_CALLBACK);
353 #endif
354
355 return (value);
356 }
357
358 #if defined (READLINE_CALLBACKS)
359 # define STATIC_CALLBACK
360 #else
361 # define STATIC_CALLBACK static
362 #endif
363
364 STATIC_CALLBACK void
365 readline_internal_setup ()
366 {
367 char *nprompt;
368
369 _rl_in_stream = rl_instream;
370 _rl_out_stream = rl_outstream;
371
372 if (rl_startup_hook)
373 (*rl_startup_hook) ();
374
375 /* If we're not echoing, we still want to at least print a prompt, because
376 rl_redisplay will not do it for us. If the calling application has a
377 custom redisplay function, though, let that function handle it. */
378 if (_rl_echoing_p == 0 && rl_redisplay_function == rl_redisplay)
379 {
380 if (rl_prompt && rl_already_prompted == 0)
381 {
382 nprompt = _rl_strip_prompt (rl_prompt);
383 fprintf (_rl_out_stream, "%s", nprompt);
384 fflush (_rl_out_stream);
385 xfree (nprompt);
386 }
387 }
388 else
389 {
390 if (rl_prompt && rl_already_prompted)
391 rl_on_new_line_with_prompt ();
392 else
393 rl_on_new_line ();
394 (*rl_redisplay_function) ();
395 }
396
397 #if defined (VI_MODE)
398 if (rl_editing_mode == vi_mode)
399 rl_vi_insert_mode (1, 'i');
400 #endif /* VI_MODE */
401
402 if (rl_pre_input_hook)
403 (*rl_pre_input_hook) ();
404
405 RL_CHECK_SIGNALS ();
406 }
407
408 STATIC_CALLBACK char *
409 readline_internal_teardown (eof)
410 int eof;
411 {
412 char *temp;
413 HIST_ENTRY *entry;
414
415 RL_CHECK_SIGNALS ();
416
417 /* Restore the original of this history line, iff the line that we
418 are editing was originally in the history, AND the line has changed. */
419 entry = current_history ();
420
421 if (entry && rl_undo_list)
422 {
423 temp = savestring (the_line);
424 rl_revert_line (1, 0);
425 entry = replace_history_entry (where_history (), the_line, (histdata_t)NULL);
426 _rl_free_history_entry (entry);
427
428 strcpy (the_line, temp);
429 xfree (temp);
430 }
431
432 if (_rl_revert_all_at_newline)
433 _rl_revert_all_lines ();
434
435 /* At any rate, it is highly likely that this line has an undo list. Get
436 rid of it now. */
437 if (rl_undo_list)
438 rl_free_undo_list ();
439
440 /* Restore normal cursor, if available. */
441 _rl_set_insert_mode (RL_IM_INSERT, 0);
442
443 return (eof ? (char *)NULL : savestring (the_line));
444 }
445
446 void
447 _rl_internal_char_cleanup ()
448 {
449 #if defined (VI_MODE)
450 /* In vi mode, when you exit insert mode, the cursor moves back
451 over the previous character. We explicitly check for that here. */
452 if (rl_editing_mode == vi_mode && _rl_keymap == vi_movement_keymap)
453 rl_vi_check ();
454 #endif /* VI_MODE */
455
456 if (rl_num_chars_to_read && rl_end >= rl_num_chars_to_read)
457 {
458 (*rl_redisplay_function) ();
459 _rl_want_redisplay = 0;
460 rl_newline (1, '\n');
461 }
462
463 if (rl_done == 0)
464 {
465 (*rl_redisplay_function) ();
466 _rl_want_redisplay = 0;
467 }
468
469 /* If the application writer has told us to erase the entire line if
470 the only character typed was something bound to rl_newline, do so. */
471 if (rl_erase_empty_line && rl_done && rl_last_func == rl_newline &&
472 rl_point == 0 && rl_end == 0)
473 _rl_erase_entire_line ();
474 }
475
476 STATIC_CALLBACK int
477 #if defined (READLINE_CALLBACKS)
478 readline_internal_char ()
479 #else
480 readline_internal_charloop ()
481 #endif
482 {
483 static int lastc, eof_found;
484 int c, code, lk;
485
486 lastc = -1;
487 eof_found = 0;
488
489 #if !defined (READLINE_CALLBACKS)
490 while (rl_done == 0)
491 {
492 #endif
493 lk = _rl_last_command_was_kill;
494
495 code = setjmp (_rl_top_level);
496
497 if (code)
498 {
499 (*rl_redisplay_function) ();
500 _rl_want_redisplay = 0;
501 /* If we get here, we're not being called from something dispatched
502 from _rl_callback_read_char(), which sets up its own value of
503 _rl_top_level (saving and restoring the old, of course), so
504 we can just return here. */
505 if (RL_ISSTATE (RL_STATE_CALLBACK))
506 return (0);
507 }
508
509 if (rl_pending_input == 0)
510 {
511 /* Then initialize the argument and number of keys read. */
512 _rl_reset_argument ();
513 rl_key_sequence_length = 0;
514 }
515
516 RL_SETSTATE(RL_STATE_READCMD);
517 c = rl_read_key ();
518 RL_UNSETSTATE(RL_STATE_READCMD);
519
520 /* look at input.c:rl_getc() for the circumstances under which this will
521 be returned; punt immediately on read error without converting it to
522 a newline. */
523 if (c == READERR)
524 {
525 #if defined (READLINE_CALLBACKS)
526 RL_SETSTATE(RL_STATE_DONE);
527 return (rl_done = 1);
528 #else
529 eof_found = 1;
530 break;
531 #endif
532 }
533
534 /* EOF typed to a non-blank line is a <NL>. */
535 if (c == EOF && rl_end)
536 c = NEWLINE;
537
538 /* The character _rl_eof_char typed to blank line, and not as the
539 previous character is interpreted as EOF. */
540 if (((c == _rl_eof_char && lastc != c) || c == EOF) && !rl_end)
541 {
542 #if defined (READLINE_CALLBACKS)
543 RL_SETSTATE(RL_STATE_DONE);
544 return (rl_done = 1);
545 #else
546 eof_found = 1;
547 break;
548 #endif
549 }
550
551 lastc = c;
552 _rl_dispatch ((unsigned char)c, _rl_keymap);
553 RL_CHECK_SIGNALS ();
554
555 /* If there was no change in _rl_last_command_was_kill, then no kill
556 has taken place. Note that if input is pending we are reading
557 a prefix command, so nothing has changed yet. */
558 if (rl_pending_input == 0 && lk == _rl_last_command_was_kill)
559 _rl_last_command_was_kill = 0;
560
561 _rl_internal_char_cleanup ();
562
563 #if defined (READLINE_CALLBACKS)
564 return 0;
565 #else
566 }
567
568 return (eof_found);
569 #endif
570 }
571
572 #if defined (READLINE_CALLBACKS)
573 static int
574 readline_internal_charloop ()
575 {
576 int eof = 1;
577
578 while (rl_done == 0)
579 eof = readline_internal_char ();
580 return (eof);
581 }
582 #endif /* READLINE_CALLBACKS */
583
584 /* Read a line of input from the global rl_instream, doing output on
585 the global rl_outstream.
586 If rl_prompt is non-null, then that is our prompt. */
587 static char *
588 readline_internal ()
589 {
590 int eof;
591
592 readline_internal_setup ();
593 eof = readline_internal_charloop ();
594 return (readline_internal_teardown (eof));
595 }
596
597 void
598 _rl_init_line_state ()
599 {
600 rl_point = rl_end = rl_mark = 0;
601 the_line = rl_line_buffer;
602 the_line[0] = 0;
603 }
604
605 void
606 _rl_set_the_line ()
607 {
608 the_line = rl_line_buffer;
609 }
610
611 #if defined (READLINE_CALLBACKS)
612 _rl_keyseq_cxt *
613 _rl_keyseq_cxt_alloc ()
614 {
615 _rl_keyseq_cxt *cxt;
616
617 cxt = (_rl_keyseq_cxt *)xmalloc (sizeof (_rl_keyseq_cxt));
618
619 cxt->flags = cxt->subseq_arg = cxt->subseq_retval = 0;
620
621 cxt->okey = 0;
622 cxt->ocxt = _rl_kscxt;
623 cxt->childval = 42; /* sentinel value */
624
625 return cxt;
626 }
627
628 void
629 _rl_keyseq_cxt_dispose (cxt)
630 _rl_keyseq_cxt *cxt;
631 {
632 xfree (cxt);
633 }
634
635 void
636 _rl_keyseq_chain_dispose ()
637 {
638 _rl_keyseq_cxt *cxt;
639
640 while (_rl_kscxt)
641 {
642 cxt = _rl_kscxt;
643 _rl_kscxt = _rl_kscxt->ocxt;
644 _rl_keyseq_cxt_dispose (cxt);
645 }
646 }
647 #endif
648
649 static int
650 _rl_subseq_getchar (key)
651 int key;
652 {
653 int k;
654
655 if (key == ESC)
656 RL_SETSTATE(RL_STATE_METANEXT);
657 RL_SETSTATE(RL_STATE_MOREINPUT);
658 k = rl_read_key ();
659 RL_UNSETSTATE(RL_STATE_MOREINPUT);
660 if (key == ESC)
661 RL_UNSETSTATE(RL_STATE_METANEXT);
662
663 return k;
664 }
665
666 #if defined (READLINE_CALLBACKS)
667 int
668 _rl_dispatch_callback (cxt)
669 _rl_keyseq_cxt *cxt;
670 {
671 int nkey, r;
672
673 /* For now */
674 /* The first time this context is used, we want to read input and dispatch
675 on it. When traversing the chain of contexts back `up', we want to use
676 the value from the next context down. We're simulating recursion using
677 a chain of contexts. */
678 if ((cxt->flags & KSEQ_DISPATCHED) == 0)
679 {
680 nkey = _rl_subseq_getchar (cxt->okey);
681 if (nkey < 0)
682 {
683 _rl_abort_internal ();
684 return -1;
685 }
686 r = _rl_dispatch_subseq (nkey, cxt->dmap, cxt->subseq_arg);
687 cxt->flags |= KSEQ_DISPATCHED;
688 }
689 else
690 r = cxt->childval;
691
692 /* For now */
693 if (r != -3) /* don't do this if we indicate there will be other matches */
694 r = _rl_subseq_result (r, cxt->oldmap, cxt->okey, (cxt->flags & KSEQ_SUBSEQ));
695
696 RL_CHECK_SIGNALS ();
697 if (r == 0) /* success! */
698 {
699 _rl_keyseq_chain_dispose ();
700 RL_UNSETSTATE (RL_STATE_MULTIKEY);
701 return r;
702 }
703
704 if (r != -3) /* magic value that says we added to the chain */
705 _rl_kscxt = cxt->ocxt;
706 if (_rl_kscxt)
707 _rl_kscxt->childval = r;
708 if (r != -3)
709 _rl_keyseq_cxt_dispose (cxt);
710
711 return r;
712 }
713 #endif /* READLINE_CALLBACKS */
714
715 /* Do the command associated with KEY in MAP.
716 If the associated command is really a keymap, then read
717 another key, and dispatch into that map. */
718 int
719 _rl_dispatch (key, map)
720 register int key;
721 Keymap map;
722 {
723 _rl_dispatching_keymap = map;
724 return _rl_dispatch_subseq (key, map, 0);
725 }
726
727 int
728 _rl_dispatch_subseq (key, map, got_subseq)
729 register int key;
730 Keymap map;
731 int got_subseq;
732 {
733 int r, newkey;
734 char *macro;
735 rl_command_func_t *func;
736 #if defined (READLINE_CALLBACKS)
737 _rl_keyseq_cxt *cxt;
738 #endif
739
740 if (META_CHAR (key) && _rl_convert_meta_chars_to_ascii)
741 {
742 if (map[ESC].type == ISKMAP)
743 {
744 if (RL_ISSTATE (RL_STATE_MACRODEF))
745 _rl_add_macro_char (ESC);
746 map = FUNCTION_TO_KEYMAP (map, ESC);
747 key = UNMETA (key);
748 rl_key_sequence_length += 2;
749 return (_rl_dispatch (key, map));
750 }
751 else
752 rl_ding ();
753 return 0;
754 }
755
756 if (RL_ISSTATE (RL_STATE_MACRODEF))
757 _rl_add_macro_char (key);
758
759 r = 0;
760 switch (map[key].type)
761 {
762 case ISFUNC:
763 func = map[key].function;
764 if (func)
765 {
766 /* Special case rl_do_lowercase_version (). */
767 if (func == rl_do_lowercase_version)
768 return (_rl_dispatch (_rl_to_lower (key), map));
769
770 rl_executing_keymap = map;
771
772 rl_dispatching = 1;
773 RL_SETSTATE(RL_STATE_DISPATCHING);
774 (*map[key].function)(rl_numeric_arg * rl_arg_sign, key);
775 RL_UNSETSTATE(RL_STATE_DISPATCHING);
776 rl_dispatching = 0;
777
778 /* If we have input pending, then the last command was a prefix
779 command. Don't change the state of rl_last_func. Otherwise,
780 remember the last command executed in this variable. */
781 if (rl_pending_input == 0 && map[key].function != rl_digit_argument)
782 rl_last_func = map[key].function;
783
784 RL_CHECK_SIGNALS ();
785 }
786 else if (map[ANYOTHERKEY].function)
787 {
788 /* OK, there's no function bound in this map, but there is a
789 shadow function that was overridden when the current keymap
790 was created. Return -2 to note that. */
791 _rl_unget_char (key);
792 return -2;
793 }
794 else if (got_subseq)
795 {
796 /* Return -1 to note that we're in a subsequence, but we don't
797 have a matching key, nor was one overridden. This means
798 we need to back up the recursion chain and find the last
799 subsequence that is bound to a function. */
800 _rl_unget_char (key);
801 return -1;
802 }
803 else
804 {
805 #if defined (READLINE_CALLBACKS)
806 RL_UNSETSTATE (RL_STATE_MULTIKEY);
807 _rl_keyseq_chain_dispose ();
808 #endif
809 _rl_abort_internal ();
810 return -1;
811 }
812 break;
813
814 case ISKMAP:
815 if (map[key].function != 0)
816 {
817 #if defined (VI_MODE)
818 /* The only way this test will be true is if a subsequence has been
819 bound starting with ESC, generally the arrow keys. What we do is
820 check whether there's input in the queue, which there generally
821 will be if an arrow key has been pressed, and, if there's not,
822 just dispatch to (what we assume is) rl_vi_movement_mode right
823 away. This is essentially an input test with a zero timeout. */
824 if (rl_editing_mode == vi_mode && key == ESC && map == vi_insertion_keymap
825 && _rl_input_queued (0) == 0)
826 return (_rl_dispatch (ANYOTHERKEY, FUNCTION_TO_KEYMAP (map, key)));
827 #endif
828
829 rl_key_sequence_length++;
830 _rl_dispatching_keymap = FUNCTION_TO_KEYMAP (map, key);
831
832 /* Allocate new context here. Use linked contexts (linked through
833 cxt->ocxt) to simulate recursion */
834 #if defined (READLINE_CALLBACKS)
835 if (RL_ISSTATE (RL_STATE_CALLBACK))
836 {
837 /* Return 0 only the first time, to indicate success to
838 _rl_callback_read_char. The rest of the time, we're called
839 from _rl_dispatch_callback, so we return -3 to indicate
840 special handling is necessary. */
841 r = RL_ISSTATE (RL_STATE_MULTIKEY) ? -3 : 0;
842 cxt = _rl_keyseq_cxt_alloc ();
843
844 if (got_subseq)
845 cxt->flags |= KSEQ_SUBSEQ;
846 cxt->okey = key;
847 cxt->oldmap = map;
848 cxt->dmap = _rl_dispatching_keymap;
849 cxt->subseq_arg = got_subseq || cxt->dmap[ANYOTHERKEY].function;
850
851 RL_SETSTATE (RL_STATE_MULTIKEY);
852 _rl_kscxt = cxt;
853
854 return r; /* don't indicate immediate success */
855 }
856 #endif
857
858 newkey = _rl_subseq_getchar (key);
859 if (newkey < 0)
860 {
861 _rl_abort_internal ();
862 return -1;
863 }
864
865 r = _rl_dispatch_subseq (newkey, _rl_dispatching_keymap, got_subseq || map[ANYOTHERKEY].function);
866 return _rl_subseq_result (r, map, key, got_subseq);
867 }
868 else
869 {
870 _rl_abort_internal ();
871 return -1;
872 }
873 break;
874
875 case ISMACR:
876 if (map[key].function != 0)
877 {
878 macro = savestring ((char *)map[key].function);
879 _rl_with_macro_input (macro);
880 return 0;
881 }
882 break;
883 }
884 #if defined (VI_MODE)
885 if (rl_editing_mode == vi_mode && _rl_keymap == vi_movement_keymap &&
886 key != ANYOTHERKEY &&
887 _rl_vi_textmod_command (key))
888 _rl_vi_set_last (key, rl_numeric_arg, rl_arg_sign);
889 #endif
890
891 return (r);
892 }
893
894 static int
895 _rl_subseq_result (r, map, key, got_subseq)
896 int r;
897 Keymap map;
898 int key, got_subseq;
899 {
900 Keymap m;
901 int type, nt;
902 rl_command_func_t *func, *nf;
903
904 if (r == -2)
905 /* We didn't match anything, and the keymap we're indexed into
906 shadowed a function previously bound to that prefix. Call
907 the function. The recursive call to _rl_dispatch_subseq has
908 already taken care of pushing any necessary input back onto
909 the input queue with _rl_unget_char. */
910 {
911 m = _rl_dispatching_keymap;
912 type = m[ANYOTHERKEY].type;
913 func = m[ANYOTHERKEY].function;
914 if (type == ISFUNC && func == rl_do_lowercase_version)
915 r = _rl_dispatch (_rl_to_lower (key), map);
916 else if (type == ISFUNC && func == rl_insert)
917 {
918 /* If the function that was shadowed was self-insert, we
919 somehow need a keymap with map[key].func == self-insert.
920 Let's use this one. */
921 nt = m[key].type;
922 nf = m[key].function;
923
924 m[key].type = type;
925 m[key].function = func;
926 r = _rl_dispatch (key, m);
927 m[key].type = nt;
928 m[key].function = nf;
929 }
930 else
931 r = _rl_dispatch (ANYOTHERKEY, m);
932 }
933 else if (r && map[ANYOTHERKEY].function)
934 {
935 /* We didn't match (r is probably -1), so return something to
936 tell the caller that it should try ANYOTHERKEY for an
937 overridden function. */
938 _rl_unget_char (key);
939 _rl_dispatching_keymap = map;
940 return -2;
941 }
942 else if (r && got_subseq)
943 {
944 /* OK, back up the chain. */
945 _rl_unget_char (key);
946 _rl_dispatching_keymap = map;
947 return -1;
948 }
949
950 return r;
951 }
952
953 /* **************************************************************** */
954 /* */
955 /* Initializations */
956 /* */
957 /* **************************************************************** */
958
959 /* Initialize readline (and terminal if not already). */
960 int
961 rl_initialize ()
962 {
963 /* If we have never been called before, initialize the
964 terminal and data structures. */
965 if (!rl_initialized)
966 {
967 RL_SETSTATE(RL_STATE_INITIALIZING);
968 readline_initialize_everything ();
969 RL_UNSETSTATE(RL_STATE_INITIALIZING);
970 rl_initialized++;
971 RL_SETSTATE(RL_STATE_INITIALIZED);
972 }
973
974 /* Initalize the current line information. */
975 _rl_init_line_state ();
976
977 /* We aren't done yet. We haven't even gotten started yet! */
978 rl_done = 0;
979 RL_UNSETSTATE(RL_STATE_DONE);
980
981 /* Tell the history routines what is going on. */
982 _rl_start_using_history ();
983
984 /* Make the display buffer match the state of the line. */
985 rl_reset_line_state ();
986
987 /* No such function typed yet. */
988 rl_last_func = (rl_command_func_t *)NULL;
989
990 /* Parsing of key-bindings begins in an enabled state. */
991 _rl_parsing_conditionalized_out = 0;
992
993 #if defined (VI_MODE)
994 if (rl_editing_mode == vi_mode)
995 _rl_vi_initialize_line ();
996 #endif
997
998 /* Each line starts in insert mode (the default). */
999 _rl_set_insert_mode (RL_IM_DEFAULT, 1);
1000
1001 return 0;
1002 }
1003
1004 #if 0
1005 #if defined (__EMX__)
1006 static void
1007 _emx_build_environ ()
1008 {
1009 TIB *tibp;
1010 PIB *pibp;
1011 char *t, **tp;
1012 int c;
1013
1014 DosGetInfoBlocks (&tibp, &pibp);
1015 t = pibp->pib_pchenv;
1016 for (c = 1; *t; c++)
1017 t += strlen (t) + 1;
1018 tp = environ = (char **)xmalloc ((c + 1) * sizeof (char *));
1019 t = pibp->pib_pchenv;
1020 while (*t)
1021 {
1022 *tp++ = t;
1023 t += strlen (t) + 1;
1024 }
1025 *tp = 0;
1026 }
1027 #endif /* __EMX__ */
1028 #endif
1029
1030 /* Initialize the entire state of the world. */
1031 static void
1032 readline_initialize_everything ()
1033 {
1034 #if 0
1035 #if defined (__EMX__)
1036 if (environ == 0)
1037 _emx_build_environ ();
1038 #endif
1039 #endif
1040
1041 #if 0
1042 /* Find out if we are running in Emacs -- UNUSED. */
1043 running_in_emacs = sh_get_env_value ("EMACS") != (char *)0;
1044 #endif
1045
1046 /* Set up input and output if they are not already set up. */
1047 if (!rl_instream)
1048 rl_instream = stdin;
1049
1050 if (!rl_outstream)
1051 rl_outstream = stdout;
1052
1053 /* Bind _rl_in_stream and _rl_out_stream immediately. These values
1054 may change, but they may also be used before readline_internal ()
1055 is called. */
1056 _rl_in_stream = rl_instream;
1057 _rl_out_stream = rl_outstream;
1058
1059 /* Allocate data structures. */
1060 if (rl_line_buffer == 0)
1061 rl_line_buffer = (char *)xmalloc (rl_line_buffer_len = DEFAULT_BUFFER_SIZE);
1062
1063 /* Initialize the terminal interface. */
1064 if (rl_terminal_name == 0)
1065 rl_terminal_name = sh_get_env_value ("TERM");
1066 _rl_init_terminal_io (rl_terminal_name);
1067
1068 /* Bind tty characters to readline functions. */
1069 readline_default_bindings ();
1070
1071 /* Initialize the function names. */
1072 rl_initialize_funmap ();
1073
1074 /* Decide whether we should automatically go into eight-bit mode. */
1075 _rl_init_eightbit ();
1076
1077 /* Read in the init file. */
1078 rl_read_init_file ((char *)NULL);
1079
1080 /* XXX */
1081 if (_rl_horizontal_scroll_mode && _rl_term_autowrap)
1082 {
1083 _rl_screenwidth--;
1084 _rl_screenchars -= _rl_screenheight;
1085 }
1086
1087 /* Override the effect of any `set keymap' assignments in the
1088 inputrc file. */
1089 rl_set_keymap_from_edit_mode ();
1090
1091 /* Try to bind a common arrow key prefix, if not already bound. */
1092 bind_arrow_keys ();
1093
1094 /* Enable the meta key, if this terminal has one. */
1095 if (_rl_enable_meta)
1096 _rl_enable_meta_key ();
1097
1098 /* If the completion parser's default word break characters haven't
1099 been set yet, then do so now. */
1100 if (rl_completer_word_break_characters == (char *)NULL)
1101 rl_completer_word_break_characters = (char *)rl_basic_word_break_characters;
1102 }
1103
1104 /* If this system allows us to look at the values of the regular
1105 input editing characters, then bind them to their readline
1106 equivalents, iff the characters are not bound to keymaps. */
1107 static void
1108 readline_default_bindings ()
1109 {
1110 if (_rl_bind_stty_chars)
1111 rl_tty_set_default_bindings (_rl_keymap);
1112 }
1113
1114 /* Reset the default bindings for the terminal special characters we're
1115 interested in back to rl_insert and read the new ones. */
1116 static void
1117 reset_default_bindings ()
1118 {
1119 if (_rl_bind_stty_chars)
1120 {
1121 rl_tty_unset_default_bindings (_rl_keymap);
1122 rl_tty_set_default_bindings (_rl_keymap);
1123 }
1124 }
1125
1126 /* Bind some common arrow key sequences in MAP. */
1127 static void
1128 bind_arrow_keys_internal (map)
1129 Keymap map;
1130 {
1131 Keymap xkeymap;
1132
1133 xkeymap = _rl_keymap;
1134 _rl_keymap = map;
1135
1136 #if defined (__MSDOS__)
1137 rl_bind_keyseq_if_unbound ("\033[0A", rl_get_previous_history);
1138 rl_bind_keyseq_if_unbound ("\033[0B", rl_backward_char);
1139 rl_bind_keyseq_if_unbound ("\033[0C", rl_forward_char);
1140 rl_bind_keyseq_if_unbound ("\033[0D", rl_get_next_history);
1141 #endif
1142
1143 rl_bind_keyseq_if_unbound ("\033[A", rl_get_previous_history);
1144 rl_bind_keyseq_if_unbound ("\033[B", rl_get_next_history);
1145 rl_bind_keyseq_if_unbound ("\033[C", rl_forward_char);
1146 rl_bind_keyseq_if_unbound ("\033[D", rl_backward_char);
1147 rl_bind_keyseq_if_unbound ("\033[H", rl_beg_of_line);
1148 rl_bind_keyseq_if_unbound ("\033[F", rl_end_of_line);
1149
1150 rl_bind_keyseq_if_unbound ("\033OA", rl_get_previous_history);
1151 rl_bind_keyseq_if_unbound ("\033OB", rl_get_next_history);
1152 rl_bind_keyseq_if_unbound ("\033OC", rl_forward_char);
1153 rl_bind_keyseq_if_unbound ("\033OD", rl_backward_char);
1154 rl_bind_keyseq_if_unbound ("\033OH", rl_beg_of_line);
1155 rl_bind_keyseq_if_unbound ("\033OF", rl_end_of_line);
1156
1157 #if defined (__MINGW32__)
1158 rl_bind_keyseq_if_unbound ("\340H", rl_get_previous_history);
1159 rl_bind_keyseq_if_unbound ("\340P", rl_get_next_history);
1160 rl_bind_keyseq_if_unbound ("\340M", rl_forward_char);
1161 rl_bind_keyseq_if_unbound ("\340K", rl_backward_char);
1162 #endif
1163
1164 _rl_keymap = xkeymap;
1165 }
1166
1167 /* Try and bind the common arrow key prefixes after giving termcap and
1168 the inputrc file a chance to bind them and create `real' keymaps
1169 for the arrow key prefix. */
1170 static void
1171 bind_arrow_keys ()
1172 {
1173 bind_arrow_keys_internal (emacs_standard_keymap);
1174
1175 #if defined (VI_MODE)
1176 bind_arrow_keys_internal (vi_movement_keymap);
1177 /* Unbind vi_movement_keymap[ESC] to allow users to repeatedly hit ESC
1178 in vi command mode while still allowing the arrow keys to work. */
1179 if (vi_movement_keymap[ESC].type == ISKMAP)
1180 rl_bind_keyseq_in_map ("\033", (rl_command_func_t *)NULL, vi_movement_keymap);
1181 bind_arrow_keys_internal (vi_insertion_keymap);
1182 #endif
1183 }
1184
1185 /* **************************************************************** */
1186 /* */
1187 /* Saving and Restoring Readline's state */
1188 /* */
1189 /* **************************************************************** */
1190
1191 int
1192 rl_save_state (sp)
1193 struct readline_state *sp;
1194 {
1195 if (sp == 0)
1196 return -1;
1197
1198 sp->point = rl_point;
1199 sp->end = rl_end;
1200 sp->mark = rl_mark;
1201 sp->buffer = rl_line_buffer;
1202 sp->buflen = rl_line_buffer_len;
1203 sp->ul = rl_undo_list;
1204 sp->prompt = rl_prompt;
1205
1206 sp->rlstate = rl_readline_state;
1207 sp->done = rl_done;
1208 sp->kmap = _rl_keymap;
1209
1210 sp->lastfunc = rl_last_func;
1211 sp->insmode = rl_insert_mode;
1212 sp->edmode = rl_editing_mode;
1213 sp->kseqlen = rl_key_sequence_length;
1214 sp->inf = rl_instream;
1215 sp->outf = rl_outstream;
1216 sp->pendingin = rl_pending_input;
1217 sp->macro = rl_executing_macro;
1218
1219 sp->catchsigs = rl_catch_signals;
1220 sp->catchsigwinch = rl_catch_sigwinch;
1221
1222 return (0);
1223 }
1224
1225 int
1226 rl_restore_state (sp)
1227 struct readline_state *sp;
1228 {
1229 if (sp == 0)
1230 return -1;
1231
1232 rl_point = sp->point;
1233 rl_end = sp->end;
1234 rl_mark = sp->mark;
1235 the_line = rl_line_buffer = sp->buffer;
1236 rl_line_buffer_len = sp->buflen;
1237 rl_undo_list = sp->ul;
1238 rl_prompt = sp->prompt;
1239
1240 rl_readline_state = sp->rlstate;
1241 rl_done = sp->done;
1242 _rl_keymap = sp->kmap;
1243
1244 rl_last_func = sp->lastfunc;
1245 rl_insert_mode = sp->insmode;
1246 rl_editing_mode = sp->edmode;
1247 rl_key_sequence_length = sp->kseqlen;
1248 rl_instream = sp->inf;
1249 rl_outstream = sp->outf;
1250 rl_pending_input = sp->pendingin;
1251 rl_executing_macro = sp->macro;
1252
1253 rl_catch_signals = sp->catchsigs;
1254 rl_catch_sigwinch = sp->catchsigwinch;
1255
1256 return (0);
1257 }
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