Mercurial > octave
view readline/readline.c @ 2996:9d4e3a9de17e
[project @ 1997-05-22 20:58:07 by jwe]
| author | jwe |
|---|---|
| date | Thu, 22 May 1997 20:59:27 +0000 |
| parents | |
| children | f7e4a95916f2 |
line wrap: on
line source
/* readline.c -- a general facility for reading lines of input with emacs style editing and completion. */ /* Copyright (C) 1987, 1989, 1992 Free Software Foundation, Inc. This file is part of the GNU Readline Library, a library for reading lines of text with interactive input and history editing. The GNU Readline Library is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 1, or (at your option) any later version. The GNU Readline Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. The GNU General Public License is often shipped with GNU software, and is generally kept in a file called COPYING or LICENSE. If you do not have a copy of the license, write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */ #define READLINE_LIBRARY #if defined (HAVE_CONFIG_H) # include <config.h> #endif #include <sys/types.h> #include "posixstat.h" #include <fcntl.h> #if defined (HAVE_SYS_FILE_H) # include <sys/file.h> #endif /* HAVE_SYS_FILE_H */ #if defined (HAVE_UNISTD_H) # include <unistd.h> #endif /* HAVE_UNISTD_H */ #if defined (HAVE_STDLIB_H) # include <stdlib.h> #else # include "ansi_stdlib.h" #endif /* HAVE_STDLIB_H */ #if defined (HAVE_LOCALE_H) # include <locale.h> #endif #include <signal.h> #include <stdio.h> #include "posixjmp.h" /* System-specific feature definitions and include files. */ #include "rldefs.h" #if defined (__EMX__) # define INCL_DOSPROCESS # include <os2.h> #endif /* __EMX__ */ /* Some standard library routines. */ #include "readline.h" #include "history.h" #ifndef RL_LIBRARY_VERSION # define RL_LIBRARY_VERSION "2.1-bash" #endif /* Evaluates its arguments multiple times. */ #define SWAP(s, e) do { int t; t = s; s = e; e = t; } while (0) /* NOTE: Functions and variables prefixed with `_rl_' are pseudo-global: they are global so they can be shared between files in the readline library, but are not intended to be visible to readline callers. */ /* Variables and functions imported from terminal.c */ extern int _rl_init_terminal_io (); extern void _rl_enable_meta_key (); extern int _rl_output_character_function (); extern void _rl_get_screen_size (); extern int _rl_enable_meta; extern int _rl_term_autowrap; extern int screenwidth, screenheight, screenchars; /* Variables and functions imported from rltty.c. */ extern void rl_prep_terminal (), rl_deprep_terminal (); extern void rltty_set_default_bindings (); /* Functions imported from util.c. */ extern void _rl_abort_internal (); extern void rl_extend_line_buffer (); extern int alphabetic (); /* Functions imported from bind.c. */ extern void _rl_bind_if_unbound (); extern int rl_set_keymap_from_edit_mode (); /* Functions imported from input.c. */ extern int _rl_any_typein (); extern void _rl_insert_typein (); extern int rl_read_key (); /* Functions imported from nls.c */ extern int _rl_init_eightbit (); /* Functions imported from shell.c */ extern char *get_env_value (); /* External redisplay functions and variables from display.c */ extern void _rl_move_vert (); extern void _rl_update_final (); extern void _rl_clear_to_eol (); extern void _rl_clear_screen (); extern void _rl_save_prompt (); extern void _rl_restore_prompt (); extern void _rl_erase_at_end_of_line (); extern void _rl_move_cursor_relative (); extern int _rl_vis_botlin; extern int _rl_last_c_pos; extern int _rl_horizontal_scroll_mode; extern int rl_display_fixed; extern int _rl_suppress_redisplay; extern char *rl_display_prompt; /* Variables imported from complete.c. */ extern char *rl_completer_word_break_characters; extern char *rl_basic_word_break_characters; extern int rl_completion_query_items; extern int rl_complete_with_tilde_expansion; /* Variables and functions from macro.c. */ extern void _rl_add_macro_char (); extern void _rl_with_macro_input (); extern int _rl_next_macro_key (); extern int _rl_defining_kbd_macro; #if defined (VI_MODE) /* Functions imported from vi_mode.c. */ extern void _rl_vi_set_last (); extern void _rl_vi_reset_last (); extern void _rl_vi_done_inserting (); extern int _rl_vi_textmod_command (); extern void _rl_vi_initialize_line (); #endif /* VI_MODE */ extern UNDO_LIST *rl_undo_list; extern int _rl_doing_an_undo; /* Forward declarations used in this file. */ void _rl_free_history_entry (); int _rl_dispatch (); int _rl_init_argument (); static char *readline_internal (); static void readline_initialize_everything (); static void start_using_history (); static void bind_arrow_keys (); #if !defined (__GO32__) static void readline_default_bindings (); #endif /* !__GO32__ */ #if defined (__GO32__) # include <go32.h> # include <pc.h> # undef HANDLE_SIGNALS #endif /* __GO32__ */ extern char *xmalloc (), *xrealloc (); /* **************************************************************** */ /* */ /* Line editing input utility */ /* */ /* **************************************************************** */ char *rl_library_version = RL_LIBRARY_VERSION; /* A pointer to the keymap that is currently in use. By default, it is the standard emacs keymap. */ Keymap _rl_keymap = emacs_standard_keymap; /* The current style of editing. */ int rl_editing_mode = emacs_mode; /* Non-zero if we called this function from _rl_dispatch(). It's present so functions can find out whether they were called from a key binding or directly from an application. */ int rl_dispatching; /* Non-zero if the previous command was a kill command. */ int _rl_last_command_was_kill = 0; /* The current value of the numeric argument specified by the user. */ int rl_numeric_arg = 1; /* Non-zero if an argument was typed. */ int rl_explicit_arg = 0; /* Temporary value used while generating the argument. */ int rl_arg_sign = 1; /* Non-zero means we have been called at least once before. */ static int rl_initialized; /* If non-zero, this program is running in an EMACS buffer. */ static int running_in_emacs; /* The current offset in the current input line. */ int rl_point; /* Mark in the current input line. */ int rl_mark; /* Length of the current input line. */ int rl_end; /* Make this non-zero to return the current input_line. */ int rl_done; /* The last function executed by readline. */ Function *rl_last_func = (Function *)NULL; /* Top level environment for readline_internal (). */ procenv_t readline_top_level; /* The streams we interact with. */ FILE *_rl_in_stream, *_rl_out_stream; /* The names of the streams that we do input and output to. */ FILE *rl_instream = (FILE *)NULL; FILE *rl_outstream = (FILE *)NULL; /* Non-zero means echo characters as they are read. */ int readline_echoing_p = 1; /* Current prompt. */ char *rl_prompt; int rl_visible_prompt_length = 0; /* The number of characters read in order to type this complete command. */ int rl_key_sequence_length = 0; /* If non-zero, then this is the address of a function to call just before readline_internal () prints the first prompt. */ Function *rl_startup_hook = (Function *)NULL; /* What we use internally. You should always refer to RL_LINE_BUFFER. */ static char *the_line; /* The character that can generate an EOF. Really read from the terminal driver... just defaulted here. */ int _rl_eof_char = CTRL ('D'); /* Non-zero makes this the next keystroke to read. */ int rl_pending_input = 0; /* Pointer to a useful terminal name. */ char *rl_terminal_name = (char *)NULL; /* Non-zero means to always use horizontal scrolling in line display. */ int _rl_horizontal_scroll_mode = 0; /* Non-zero means to display an asterisk at the starts of history lines which have been modified. */ int _rl_mark_modified_lines = 0; /* The style of `bell' notification preferred. This can be set to NO_BELL, AUDIBLE_BELL, or VISIBLE_BELL. */ int _rl_bell_preference = AUDIBLE_BELL; /* String inserted into the line by rl_insert_comment (). */ char *_rl_comment_begin; /* Keymap holding the function currently being executed. */ Keymap rl_executing_keymap; /* Line buffer and maintenence. */ char *rl_line_buffer = (char *)NULL; int rl_line_buffer_len = 0; /* Forward declarations used by the display and termcap code. */ /* **************************************************************** */ /* */ /* `Forward' declarations */ /* */ /* **************************************************************** */ /* Non-zero means do not parse any lines other than comments and parser directives. */ unsigned char _rl_parsing_conditionalized_out = 0; /* Non-zero means to convert characters with the meta bit set to escape-prefixed characters so we can indirect through emacs_meta_keymap or vi_escape_keymap. */ int _rl_convert_meta_chars_to_ascii = 1; /* Non-zero means to output characters with the meta bit set directly rather than as a meta-prefixed escape sequence. */ int _rl_output_meta_chars = 0; /* **************************************************************** */ /* */ /* Top Level Functions */ /* */ /* **************************************************************** */ /* Non-zero means treat 0200 bit in terminal input as Meta bit. */ int _rl_meta_flag = 0; /* Forward declaration */ /* Read a line of input. Prompt with PROMPT. An empty PROMPT means none. A return value of NULL means that EOF was encountered. */ char * readline (prompt) char *prompt; { char *value; rl_prompt = prompt; /* If we are at EOF return a NULL string. */ if (rl_pending_input == EOF) { rl_pending_input = 0; return ((char *)NULL); } rl_visible_prompt_length = rl_expand_prompt (rl_prompt); rl_initialize (); (*rl_prep_term_function) (_rl_meta_flag); #if defined (HANDLE_SIGNALS) rl_set_signals (); #endif value = readline_internal (); (*rl_deprep_term_function) (); #if defined (HANDLE_SIGNALS) rl_clear_signals (); #endif return (value); } #if defined (READLINE_CALLBACKS) # define STATIC_CALLBACK #else # define STATIC_CALLBACK static #endif STATIC_CALLBACK void readline_internal_setup () { _rl_in_stream = rl_instream; _rl_out_stream = rl_outstream; if (rl_startup_hook) (*rl_startup_hook) (); if (readline_echoing_p == 0) { if (rl_prompt) { fprintf (_rl_out_stream, "%s", rl_prompt); fflush (_rl_out_stream); } } else { rl_on_new_line (); (*rl_redisplay_function) (); #if defined (VI_MODE) if (rl_editing_mode == vi_mode) rl_vi_insertion_mode (1, 0); #endif /* VI_MODE */ } } STATIC_CALLBACK char * readline_internal_teardown (eof) int eof; { char *temp; HIST_ENTRY *entry; /* Restore the original of this history line, iff the line that we are editing was originally in the history, AND the line has changed. */ entry = current_history (); if (entry && rl_undo_list) { temp = savestring (the_line); rl_revert_line (1, 0); entry = replace_history_entry (where_history (), the_line, (HIST_ENTRY *)NULL); _rl_free_history_entry (entry); strcpy (the_line, temp); free (temp); } /* At any rate, it is highly likely that this line has an undo list. Get rid of it now. */ if (rl_undo_list) free_undo_list (); return (eof ? (char *)NULL : savestring (the_line)); } STATIC_CALLBACK int #if defined (READLINE_CALLBACKS) readline_internal_char () #else readline_internal_charloop () #endif { static int lastc, eof_found; int c, code, lk; lastc = -1; eof_found = 0; #if !defined (READLINE_CALLBACKS) while (rl_done == 0) { #endif lk = _rl_last_command_was_kill; code = setjmp (readline_top_level); if (code) (*rl_redisplay_function) (); if (rl_pending_input == 0) { /* Then initialize the argument and number of keys read. */ _rl_init_argument (); rl_key_sequence_length = 0; } c = rl_read_key (); /* EOF typed to a non-blank line is a <NL>. */ if (c == EOF && rl_end) c = NEWLINE; /* The character _rl_eof_char typed to blank line, and not as the previous character is interpreted as EOF. */ if (((c == _rl_eof_char && lastc != c) || c == EOF) && !rl_end) { #if defined (READLINE_CALLBACKS) return (rl_done = 1); #else eof_found = 1; break; #endif } lastc = c; _rl_dispatch (c, _rl_keymap); /* If there was no change in _rl_last_command_was_kill, then no kill has taken place. Note that if input is pending we are reading a prefix command, so nothing has changed yet. */ if (rl_pending_input == 0 && lk == _rl_last_command_was_kill) _rl_last_command_was_kill = 0; #if defined (VI_MODE) /* In vi mode, when you exit insert mode, the cursor moves back over the previous character. We explicitly check for that here. */ if (rl_editing_mode == vi_mode && _rl_keymap == vi_movement_keymap) rl_vi_check (); #endif /* VI_MODE */ if (rl_done == 0) (*rl_redisplay_function) (); #if defined (READLINE_CALLBACKS) return 0; #else } return (eof_found); #endif } #if defined (READLINE_CALLBACKS) static int readline_internal_charloop () { int eof; while (rl_done == 0) eof = readline_internal_char (); return (eof); } #endif /* READLINE_CALLBACKS */ /* Read a line of input from the global rl_instream, doing output on the global rl_outstream. If rl_prompt is non-null, then that is our prompt. */ static char * readline_internal () { int eof; readline_internal_setup (); eof = readline_internal_charloop (); return (readline_internal_teardown (eof)); } void _rl_init_line_state () { rl_point = rl_end = 0; the_line = rl_line_buffer; the_line[0] = 0; } void _rl_set_the_line () { the_line = rl_line_buffer; } /* Do the command associated with KEY in MAP. If the associated command is really a keymap, then read another key, and dispatch into that map. */ int _rl_dispatch (key, map) register int key; Keymap map; { int r, newkey; char *macro; Function *func; if (META_CHAR (key) && _rl_convert_meta_chars_to_ascii) { if (map[ESC].type == ISKMAP) { if (_rl_defining_kbd_macro) _rl_add_macro_char (ESC); map = FUNCTION_TO_KEYMAP (map, ESC); key = UNMETA (key); rl_key_sequence_length += 2; return (_rl_dispatch (key, map)); } else ding (); return 0; } if (_rl_defining_kbd_macro) _rl_add_macro_char (key); r = 0; switch (map[key].type) { case ISFUNC: func = map[key].function; if (func != (Function *)NULL) { /* Special case rl_do_lowercase_version (). */ if (func == rl_do_lowercase_version) return (_rl_dispatch (_rl_to_lower (key), map)); rl_executing_keymap = map; #if 0 _rl_suppress_redisplay = (map[key].function == rl_insert) && _rl_input_available (); #endif rl_dispatching = 1; r = (*map[key].function)(rl_numeric_arg * rl_arg_sign, key); rl_dispatching = 0; /* If we have input pending, then the last command was a prefix command. Don't change the state of rl_last_func. Otherwise, remember the last command executed in this variable. */ if (!rl_pending_input && map[key].function != rl_digit_argument) rl_last_func = map[key].function; } else { _rl_abort_internal (); return -1; } break; case ISKMAP: if (map[key].function != (Function *)NULL) { rl_key_sequence_length++; newkey = rl_read_key (); r = _rl_dispatch (newkey, FUNCTION_TO_KEYMAP (map, key)); } else { _rl_abort_internal (); return -1; } break; case ISMACR: if (map[key].function != (Function *)NULL) { macro = savestring ((char *)map[key].function); _rl_with_macro_input (macro); return 0; } break; } #if defined (VI_MODE) if (rl_editing_mode == vi_mode && _rl_keymap == vi_movement_keymap && _rl_vi_textmod_command (key)) _rl_vi_set_last (key, rl_numeric_arg, rl_arg_sign); #endif return (r); } /* **************************************************************** */ /* */ /* Initializations */ /* */ /* **************************************************************** */ /* Initialize readline (and terminal if not already). */ int rl_initialize () { /* If we have never been called before, initialize the terminal and data structures. */ if (!rl_initialized) { readline_initialize_everything (); rl_initialized++; } /* Initalize the current line information. */ _rl_init_line_state (); /* We aren't done yet. We haven't even gotten started yet! */ rl_done = 0; /* Tell the history routines what is going on. */ start_using_history (); /* Make the display buffer match the state of the line. */ rl_reset_line_state (); /* No such function typed yet. */ rl_last_func = (Function *)NULL; /* Parsing of key-bindings begins in an enabled state. */ _rl_parsing_conditionalized_out = 0; #if defined (VI_MODE) if (rl_editing_mode == vi_mode) _rl_vi_initialize_line (); #endif return 0; } #if defined (__EMX__) static void _emx_build_environ () { TIB *tibp; PIB *pibp; char *t, **tp; int c; DosGetInfoBlocks (&tibp, &pibp); t = pibp->pib_pchenv; for (c = 1; *t; c++) t += strlen (t) + 1; tp = environ = (char **)xmalloc ((c + 1) * sizeof (char *)); t = pibp->pib_pchenv; while (*t) { *tp++ = t; t += strlen (t) + 1; } *tp = 0; } #endif /* __EMX__ */ /* Initialize the entire state of the world. */ static void readline_initialize_everything () { #if defined (__EMX__) if (environ == 0) _emx_build_environ (); #endif /* Find out if we are running in Emacs. */ running_in_emacs = get_env_value ("EMACS") != (char *)0; /* Set up input and output if they are not already set up. */ if (!rl_instream) rl_instream = stdin; if (!rl_outstream) rl_outstream = stdout; /* Bind _rl_in_stream and _rl_out_stream immediately. These values may change, but they may also be used before readline_internal () is called. */ _rl_in_stream = rl_instream; _rl_out_stream = rl_outstream; /* Allocate data structures. */ if (rl_line_buffer == 0) rl_line_buffer = xmalloc (rl_line_buffer_len = DEFAULT_BUFFER_SIZE); /* Initialize the terminal interface. */ _rl_init_terminal_io ((char *)NULL); #if !defined (__GO32__) /* Bind tty characters to readline functions. */ readline_default_bindings (); #endif /* !__GO32__ */ /* Initialize the function names. */ rl_initialize_funmap (); /* Decide whether we should automatically go into eight-bit mode. */ _rl_init_eightbit (); /* Read in the init file. */ rl_read_init_file ((char *)NULL); /* XXX */ if (_rl_horizontal_scroll_mode && _rl_term_autowrap) { screenwidth--; screenchars -= screenheight; } /* Override the effect of any `set keymap' assignments in the inputrc file. */ rl_set_keymap_from_edit_mode (); /* Try to bind a common arrow key prefix, if not already bound. */ bind_arrow_keys (); /* Enable the meta key, if this terminal has one. */ if (_rl_enable_meta) _rl_enable_meta_key (); /* If the completion parser's default word break characters haven't been set yet, then do so now. */ if (rl_completer_word_break_characters == (char *)NULL) rl_completer_word_break_characters = rl_basic_word_break_characters; } /* If this system allows us to look at the values of the regular input editing characters, then bind them to their readline equivalents, iff the characters are not bound to keymaps. */ static void readline_default_bindings () { rltty_set_default_bindings (_rl_keymap); } static void bind_arrow_keys_internal () { Function *f; f = rl_function_of_keyseq ("\033[A", _rl_keymap, (int *)NULL); if (!f || f == rl_do_lowercase_version) { _rl_bind_if_unbound ("\033[A", rl_get_previous_history); _rl_bind_if_unbound ("\033[B", rl_get_next_history); _rl_bind_if_unbound ("\033[C", rl_forward); _rl_bind_if_unbound ("\033[D", rl_backward); } f = rl_function_of_keyseq ("\033OA", _rl_keymap, (int *)NULL); if (!f || f == rl_do_lowercase_version) { _rl_bind_if_unbound ("\033OA", rl_get_previous_history); _rl_bind_if_unbound ("\033OB", rl_get_next_history); _rl_bind_if_unbound ("\033OC", rl_forward); _rl_bind_if_unbound ("\033OD", rl_backward); } } /* Try and bind the common arrow key prefix after giving termcap and the inputrc file a chance to bind them and create `real' keymaps for the arrow key prefix. */ static void bind_arrow_keys () { Keymap xkeymap; xkeymap = _rl_keymap; _rl_keymap = emacs_standard_keymap; bind_arrow_keys_internal (); #if defined (VI_MODE) _rl_keymap = vi_movement_keymap; bind_arrow_keys_internal (); #endif _rl_keymap = xkeymap; } /* **************************************************************** */ /* */ /* Numeric Arguments */ /* */ /* **************************************************************** */ /* Handle C-u style numeric args, as well as M--, and M-digits. */ static int rl_digit_loop () { int key, c, sawminus, sawdigits; _rl_save_prompt (); sawminus = sawdigits = 0; while (1) { rl_message ("(arg: %d) ", rl_arg_sign * rl_numeric_arg); key = c = rl_read_key (); /* If we see a key bound to `universal-argument' after seeing digits, it ends the argument but is otherwise ignored. */ if (_rl_keymap[c].type == ISFUNC && _rl_keymap[c].function == rl_universal_argument) { if (sawdigits == 0) { rl_numeric_arg *= 4; continue; } else { key = rl_read_key (); _rl_restore_prompt (); rl_clear_message (); return (_rl_dispatch (key, _rl_keymap)); } } c = UNMETA (c); if (_rl_digit_p (c)) { rl_numeric_arg = rl_explicit_arg ? (rl_numeric_arg * 10) + c - '0' : c - '0'; sawdigits = rl_explicit_arg = 1; } else if (c == '-' && rl_explicit_arg == 0) { rl_numeric_arg = sawminus = 1; rl_arg_sign = -1; } else { /* Make M-- command equivalent to M--1 command. */ if (sawminus && rl_numeric_arg == 1 && rl_explicit_arg == 0) rl_explicit_arg = 1; _rl_restore_prompt (); rl_clear_message (); return (_rl_dispatch (key, _rl_keymap)); } } return 0; } /* Add the current digit to the argument in progress. */ int rl_digit_argument (ignore, key) int ignore, key; { rl_pending_input = key; return (rl_digit_loop ()); } /* What to do when you abort reading an argument. */ int rl_discard_argument () { ding (); rl_clear_message (); _rl_init_argument (); return 0; } /* Create a default argument. */ int _rl_init_argument () { rl_numeric_arg = rl_arg_sign = 1; rl_explicit_arg = 0; return 0; } /* C-u, universal argument. Multiply the current argument by 4. Read a key. If the key has nothing to do with arguments, then dispatch on it. If the key is the abort character then abort. */ int rl_universal_argument (count, key) int count, key; { rl_numeric_arg *= 4; return (rl_digit_loop ()); } /* **************************************************************** */ /* */ /* Insert and Delete */ /* */ /* **************************************************************** */ /* Insert a string of text into the line at point. This is the only way that you should do insertion. rl_insert () calls this function. */ int rl_insert_text (string) char *string; { register int i, l = strlen (string); if (rl_end + l >= rl_line_buffer_len) rl_extend_line_buffer (rl_end + l); for (i = rl_end; i >= rl_point; i--) the_line[i + l] = the_line[i]; strncpy (the_line + rl_point, string, l); /* Remember how to undo this if we aren't undoing something. */ if (!_rl_doing_an_undo) { /* If possible and desirable, concatenate the undos. */ if ((l == 1) && rl_undo_list && (rl_undo_list->what == UNDO_INSERT) && (rl_undo_list->end == rl_point) && (rl_undo_list->end - rl_undo_list->start < 20)) rl_undo_list->end++; else rl_add_undo (UNDO_INSERT, rl_point, rl_point + l, (char *)NULL); } rl_point += l; rl_end += l; the_line[rl_end] = '\0'; return l; } /* Delete the string between FROM and TO. FROM is inclusive, TO is not. */ int rl_delete_text (from, to) int from, to; { register char *text; register int diff, i; /* Fix it if the caller is confused. */ if (from > to) SWAP (from, to); /* fix boundaries */ if (to > rl_end) { to = rl_end; if (from > to) from = to; } text = rl_copy_text (from, to); /* Some versions of strncpy() can't handle overlapping arguments. */ diff = to - from; for (i = from; i < rl_end - diff; i++) the_line[i] = the_line[i + diff]; /* Remember how to undo this delete. */ if (_rl_doing_an_undo == 0) rl_add_undo (UNDO_DELETE, from, to, text); else free (text); rl_end -= diff; the_line[rl_end] = '\0'; return (diff); } /* Fix up point so that it is within the line boundaries after killing text. If FIX_MARK_TOO is non-zero, the mark is forced within line boundaries also. */ #define _RL_FIX_POINT(x) \ do { \ if (x > rl_end) \ x = rl_end; \ else if (x < 0) \ x = 0; \ } while (0) void _rl_fix_point (fix_mark_too) int fix_mark_too; { _RL_FIX_POINT (rl_point); if (fix_mark_too) _RL_FIX_POINT (rl_mark); } #undef _RL_FIX_POINT /* **************************************************************** */ /* */ /* Readline character functions */ /* */ /* **************************************************************** */ /* This is not a gap editor, just a stupid line input routine. No hair is involved in writing any of the functions, and none should be. */ /* Note that: rl_end is the place in the string that we would place '\0'; i.e., it is always safe to place '\0' there. rl_point is the place in the string where the cursor is. Sometimes this is the same as rl_end. Any command that is called interactively receives two arguments. The first is a count: the numeric arg pased to this command. The second is the key which invoked this command. */ /* **************************************************************** */ /* */ /* Movement Commands */ /* */ /* **************************************************************** */ /* Note that if you `optimize' the display for these functions, you cannot use said functions in other functions which do not do optimizing display. I.e., you will have to update the data base for rl_redisplay, and you might as well let rl_redisplay do that job. */ /* Move forward COUNT characters. */ int rl_forward (count, key) int count, key; { if (count < 0) rl_backward (-count, key); else if (count > 0) { int end = rl_point + count; #if defined (VI_MODE) int lend = rl_end - (rl_editing_mode == vi_mode); #else int lend = rl_end; #endif if (end > lend) { rl_point = lend; ding (); } else rl_point = end; } return 0; } /* Move backward COUNT characters. */ int rl_backward (count, key) int count, key; { if (count < 0) rl_forward (-count, key); else if (count > 0) { if (rl_point < count) { rl_point = 0; ding (); } else rl_point -= count; } return 0; } /* Move to the beginning of the line. */ int rl_beg_of_line (count, key) int count, key; { rl_point = 0; return 0; } /* Move to the end of the line. */ int rl_end_of_line (count, key) int count, key; { rl_point = rl_end; return 0; } /* Move forward a word. We do what Emacs does. */ int rl_forward_word (count, key) int count, key; { int c; if (count < 0) { rl_backward_word (-count, key); return 0; } while (count) { if (rl_point == rl_end) return 0; /* If we are not in a word, move forward until we are in one. Then, move forward until we hit a non-alphabetic character. */ c = the_line[rl_point]; if (alphabetic (c) == 0) { while (++rl_point < rl_end) { c = the_line[rl_point]; if (alphabetic (c)) break; } } if (rl_point == rl_end) return 0; while (++rl_point < rl_end) { c = the_line[rl_point]; if (alphabetic (c) == 0) break; } --count; } return 0; } /* Move backward a word. We do what Emacs does. */ int rl_backward_word (count, key) int count, key; { int c; if (count < 0) { rl_forward_word (-count, key); return 0; } while (count) { if (!rl_point) return 0; /* Like rl_forward_word (), except that we look at the characters just before point. */ c = the_line[rl_point - 1]; if (alphabetic (c) == 0) { while (--rl_point) { c = the_line[rl_point - 1]; if (alphabetic (c)) break; } } while (rl_point) { c = the_line[rl_point - 1]; if (alphabetic (c) == 0) break; else --rl_point; } --count; } return 0; } /* Clear the current line. Numeric argument to C-l does this. */ int rl_refresh_line () { int curr_line, nleft; /* Find out whether or not there might be invisible characters in the editing buffer. */ if (rl_display_prompt == rl_prompt) nleft = _rl_last_c_pos - screenwidth - rl_visible_prompt_length; else nleft = _rl_last_c_pos - screenwidth; if (nleft > 0) curr_line = 1 + nleft / screenwidth; else curr_line = 0; _rl_move_vert (curr_line); _rl_move_cursor_relative (0, the_line); /* XXX is this right */ #if defined (__GO32__) { int row, col, width, row_start; ScreenGetCursor (&row, &col); width = ScreenCols (); row_start = ScreenPrimary + (row * width); memset (row_start + col, 0, (width - col) * 2); } #else /* !__GO32__ */ _rl_clear_to_eol (0); /* arg of 0 means to not use spaces */ #endif /* !__GO32__ */ rl_forced_update_display (); rl_display_fixed = 1; return 0; } /* C-l typed to a line without quoting clears the screen, and then reprints the prompt and the current input line. Given a numeric arg, redraw only the current line. */ int rl_clear_screen (count, key) int count, key; { if (rl_explicit_arg) { rl_refresh_line (); return 0; } _rl_clear_screen (); /* calls termcap function to clear screen */ rl_forced_update_display (); rl_display_fixed = 1; return 0; } int rl_arrow_keys (count, c) int count, c; { int ch; ch = rl_read_key (); switch (_rl_to_upper (ch)) { case 'A': rl_get_previous_history (count, ch); break; case 'B': rl_get_next_history (count, ch); break; case 'C': rl_forward (count, ch); break; case 'D': rl_backward (count, ch); break; default: ding (); } return 0; } /* **************************************************************** */ /* */ /* Text commands */ /* */ /* **************************************************************** */ /* Insert the character C at the current location, moving point forward. */ int rl_insert (count, c) int count, c; { register int i; char *string; if (count <= 0) return 0; /* If we can optimize, then do it. But don't let people crash readline because of extra large arguments. */ if (count > 1 && count <= 1024) { string = xmalloc (1 + count); for (i = 0; i < count; i++) string[i] = c; string[i] = '\0'; rl_insert_text (string); free (string); return 0; } if (count > 1024) { int decreaser; char str[1024+1]; for (i = 0; i < 1024; i++) str[i] = c; while (count) { decreaser = (count > 1024 ? 1024 : count); str[decreaser] = '\0'; rl_insert_text (str); count -= decreaser; } return 0; } /* We are inserting a single character. If there is pending input, then make a string of all of the pending characters that are bound to rl_insert, and insert them all. */ if (_rl_any_typein ()) _rl_insert_typein (c); else { /* Inserting a single character. */ char str[2]; str[1] = '\0'; str[0] = c; rl_insert_text (str); } return 0; } /* Insert the next typed character verbatim. */ int rl_quoted_insert (count, key) int count, key; { int c; c = rl_read_key (); return (rl_insert (count, c)); } /* Insert a tab character. */ int rl_tab_insert (count, key) int count, key; { return (rl_insert (count, '\t')); } /* What to do when a NEWLINE is pressed. We accept the whole line. KEY is the key that invoked this command. I guess it could have meaning in the future. */ int rl_newline (count, key) int count, key; { rl_done = 1; #if defined (VI_MODE) if (rl_editing_mode == vi_mode) { _rl_vi_done_inserting (); _rl_vi_reset_last (); } #endif /* VI_MODE */ if (readline_echoing_p) _rl_update_final (); return 0; } /* What to do for some uppercase characters, like meta characters, and some characters appearing in emacs_ctlx_keymap. This function is just a stub, you bind keys to it and the code in _rl_dispatch () is special cased. */ int rl_do_lowercase_version (ignore1, ignore2) int ignore1, ignore2; { return 0; } /* Rubout the character behind point. */ int rl_rubout (count, key) int count, key; { if (count < 0) { rl_delete (-count, key); return 0; } if (!rl_point) { ding (); return -1; } if (count > 1 || rl_explicit_arg) { int orig_point = rl_point; rl_backward (count, key); rl_kill_text (orig_point, rl_point); } else { int c = the_line[--rl_point]; rl_delete_text (rl_point, rl_point + 1); if (rl_point == rl_end && isprint (c) && _rl_last_c_pos) { int l; l = rl_character_len (c, rl_point); _rl_erase_at_end_of_line (l); } } return 0; } /* Delete the character under the cursor. Given a numeric argument, kill that many characters instead. */ int rl_delete (count, key) int count, key; { if (count < 0) return (rl_rubout (-count, key)); if (rl_point == rl_end) { ding (); return -1; } if (count > 1 || rl_explicit_arg) { int orig_point = rl_point; rl_forward (count, key); rl_kill_text (orig_point, rl_point); rl_point = orig_point; return 0; } else return (rl_delete_text (rl_point, rl_point + 1)); } /* Delete all spaces and tabs around point. */ int rl_delete_horizontal_space (count, ignore) int count, ignore; { int start = rl_point; while (rl_point && whitespace (the_line[rl_point - 1])) rl_point--; start = rl_point; while (rl_point < rl_end && whitespace (the_line[rl_point])) rl_point++; if (start != rl_point) { rl_delete_text (start, rl_point); rl_point = start; } return 0; } #ifndef RL_COMMENT_BEGIN_DEFAULT #define RL_COMMENT_BEGIN_DEFAULT "#" #endif /* Turn the current line into a comment in shell history. A K*rn shell style function. */ int rl_insert_comment (count, key) int count, key; { rl_beg_of_line (1, key); rl_insert_text (_rl_comment_begin ? _rl_comment_begin : RL_COMMENT_BEGIN_DEFAULT); (*rl_redisplay_function) (); rl_newline (1, '\n'); return (0); } /* **************************************************************** */ /* */ /* Changing Case */ /* */ /* **************************************************************** */ /* The three kinds of things that we know how to do. */ #define UpCase 1 #define DownCase 2 #define CapCase 3 static int rl_change_case (); /* Uppercase the word at point. */ int rl_upcase_word (count, key) int count, key; { return (rl_change_case (count, UpCase)); } /* Lowercase the word at point. */ int rl_downcase_word (count, key) int count, key; { return (rl_change_case (count, DownCase)); } /* Upcase the first letter, downcase the rest. */ int rl_capitalize_word (count, key) int count, key; { return (rl_change_case (count, CapCase)); } /* The meaty function. Change the case of COUNT words, performing OP on them. OP is one of UpCase, DownCase, or CapCase. If a negative argument is given, leave point where it started, otherwise, leave it where it moves to. */ static int rl_change_case (count, op) int count, op; { register int start, end; int inword, c; start = rl_point; rl_forward_word (count, 0); end = rl_point; if (count < 0) SWAP (start, end); /* We are going to modify some text, so let's prepare to undo it. */ rl_modifying (start, end); for (inword = 0; start < end; start++) { c = the_line[start]; switch (op) { case UpCase: the_line[start] = _rl_to_upper (c); break; case DownCase: the_line[start] = _rl_to_lower (c); break; case CapCase: the_line[start] = (inword == 0) ? _rl_to_upper (c) : _rl_to_lower (c); inword = alphabetic (the_line[start]); break; default: ding (); return -1; } } rl_point = end; return 0; } /* **************************************************************** */ /* */ /* Transposition */ /* */ /* **************************************************************** */ /* Transpose the words at point. */ int rl_transpose_words (count, key) int count, key; { char *word1, *word2; int w1_beg, w1_end, w2_beg, w2_end; int orig_point = rl_point; if (!count) return 0; /* Find the two words. */ rl_forward_word (count, key); w2_end = rl_point; rl_backward_word (1, key); w2_beg = rl_point; rl_backward_word (count, key); w1_beg = rl_point; rl_forward_word (1, key); w1_end = rl_point; /* Do some check to make sure that there really are two words. */ if ((w1_beg == w2_beg) || (w2_beg < w1_end)) { ding (); rl_point = orig_point; return -1; } /* Get the text of the words. */ word1 = rl_copy_text (w1_beg, w1_end); word2 = rl_copy_text (w2_beg, w2_end); /* We are about to do many insertions and deletions. Remember them as one operation. */ rl_begin_undo_group (); /* Do the stuff at word2 first, so that we don't have to worry about word1 moving. */ rl_point = w2_beg; rl_delete_text (w2_beg, w2_end); rl_insert_text (word1); rl_point = w1_beg; rl_delete_text (w1_beg, w1_end); rl_insert_text (word2); /* This is exactly correct since the text before this point has not changed in length. */ rl_point = w2_end; /* I think that does it. */ rl_end_undo_group (); free (word1); free (word2); return 0; } /* Transpose the characters at point. If point is at the end of the line, then transpose the characters before point. */ int rl_transpose_chars (count, key) int count, key; { char dummy[2]; if (!count) return 0; if (!rl_point || rl_end < 2) { ding (); return -1; } rl_begin_undo_group (); if (rl_point == rl_end) { --rl_point; count = 1; } rl_point--; dummy[0] = the_line[rl_point]; dummy[1] = '\0'; rl_delete_text (rl_point, rl_point + 1); rl_point += count; _rl_fix_point (0); rl_insert_text (dummy); rl_end_undo_group (); return 0; } /* **************************************************************** */ /* */ /* Character Searching */ /* */ /* **************************************************************** */ int _rl_char_search_internal (count, dir, schar) int count, dir, schar; { int pos, inc; pos = rl_point; inc = (dir < 0) ? -1 : 1; while (count) { if ((dir < 0 && pos <= 0) || (dir > 0 && pos >= rl_end)) { ding (); return -1; } pos += inc; do { if (rl_line_buffer[pos] == schar) { count--; if (dir < 0) rl_point = (dir == BTO) ? pos + 1 : pos; else rl_point = (dir == FTO) ? pos - 1 : pos; break; } } while ((dir < 0) ? pos-- : ++pos < rl_end); } return (0); } /* Search COUNT times for a character read from the current input stream. FDIR is the direction to search if COUNT is non-negative; otherwise the search goes in BDIR. */ static int _rl_char_search (count, fdir, bdir) int count, fdir, bdir; { int c; c = rl_read_key (); if (count < 0) return (_rl_char_search_internal (-count, bdir, c)); else return (_rl_char_search_internal (count, fdir, c)); } int rl_char_search (count, key) int count, key; { return (_rl_char_search (count, FFIND, BFIND)); } int rl_backward_char_search (count, key) int count, key; { return (_rl_char_search (count, BFIND, FFIND)); } /* **************************************************************** */ /* */ /* History Utilities */ /* */ /* **************************************************************** */ /* We already have a history library, and that is what we use to control the history features of readline. This is our local interface to the history mechanism. */ /* While we are editing the history, this is the saved version of the original line. */ HIST_ENTRY *saved_line_for_history = (HIST_ENTRY *)NULL; /* Set the history pointer back to the last entry in the history. */ static void start_using_history () { using_history (); if (saved_line_for_history) _rl_free_history_entry (saved_line_for_history); saved_line_for_history = (HIST_ENTRY *)NULL; } /* Free the contents (and containing structure) of a HIST_ENTRY. */ void _rl_free_history_entry (entry) HIST_ENTRY *entry; { if (entry == 0) return; if (entry->line) free (entry->line); free (entry); } /* Perhaps put back the current line if it has changed. */ int maybe_replace_line () { HIST_ENTRY *temp; temp = current_history (); /* If the current line has changed, save the changes. */ if (temp && ((UNDO_LIST *)(temp->data) != rl_undo_list)) { temp = replace_history_entry (where_history (), the_line, rl_undo_list); free (temp->line); free (temp); } return 0; } /* Put back the saved_line_for_history if there is one. */ int maybe_unsave_line () { int line_len; if (saved_line_for_history) { line_len = strlen (saved_line_for_history->line); if (line_len >= rl_line_buffer_len) rl_extend_line_buffer (line_len); strcpy (the_line, saved_line_for_history->line); rl_undo_list = (UNDO_LIST *)saved_line_for_history->data; _rl_free_history_entry (saved_line_for_history); saved_line_for_history = (HIST_ENTRY *)NULL; rl_end = rl_point = strlen (the_line); } else ding (); return 0; } /* Save the current line in saved_line_for_history. */ int maybe_save_line () { if (saved_line_for_history == 0) { saved_line_for_history = (HIST_ENTRY *)xmalloc (sizeof (HIST_ENTRY)); saved_line_for_history->line = savestring (the_line); saved_line_for_history->data = (char *)rl_undo_list; } return 0; } /* **************************************************************** */ /* */ /* History Commands */ /* */ /* **************************************************************** */ /* Meta-< goes to the start of the history. */ int rl_beginning_of_history (count, key) int count, key; { return (rl_get_previous_history (1 + where_history (), key)); } /* Meta-> goes to the end of the history. (The current line). */ int rl_end_of_history (count, key) int count, key; { maybe_replace_line (); using_history (); maybe_unsave_line (); return 0; } /* Move down to the next history line. */ int rl_get_next_history (count, key) int count, key; { HIST_ENTRY *temp; int line_len; if (count < 0) return (rl_get_previous_history (-count, key)); if (count == 0) return 0; maybe_replace_line (); temp = (HIST_ENTRY *)NULL; while (count) { temp = next_history (); if (!temp) break; --count; } if (temp == 0) maybe_unsave_line (); else { line_len = strlen (temp->line); if (line_len >= rl_line_buffer_len) rl_extend_line_buffer (line_len); strcpy (the_line, temp->line); rl_undo_list = (UNDO_LIST *)temp->data; rl_end = rl_point = strlen (the_line); #if defined (VI_MODE) if (rl_editing_mode == vi_mode) rl_point = 0; #endif /* VI_MODE */ } return 0; } /* Get the previous item out of our interactive history, making it the current line. If there is no previous history, just ding. */ int rl_get_previous_history (count, key) int count, key; { HIST_ENTRY *old_temp, *temp; int line_len; if (count < 0) return (rl_get_next_history (-count, key)); if (count == 0) return 0; /* If we don't have a line saved, then save this one. */ maybe_save_line (); /* If the current line has changed, save the changes. */ maybe_replace_line (); temp = old_temp = (HIST_ENTRY *)NULL; while (count) { temp = previous_history (); if (temp == 0) break; old_temp = temp; --count; } /* If there was a large argument, and we moved back to the start of the history, that is not an error. So use the last value found. */ if (!temp && old_temp) temp = old_temp; if (temp == 0) ding (); else { line_len = strlen (temp->line); if (line_len >= rl_line_buffer_len) rl_extend_line_buffer (line_len); strcpy (the_line, temp->line); rl_undo_list = (UNDO_LIST *)temp->data; rl_end = rl_point = line_len; #if defined (VI_MODE) if (rl_editing_mode == vi_mode) rl_point = 0; #endif /* VI_MODE */ } return 0; } /* **************************************************************** */ /* */ /* The Mark and the Region. */ /* */ /* **************************************************************** */ /* Set the mark at POSITION. */ int _rl_set_mark_at_pos (position) int position; { if (position > rl_end) return -1; rl_mark = position; return 0; } /* A bindable command to set the mark. */ int rl_set_mark (count, key) int count, key; { return (_rl_set_mark_at_pos (rl_explicit_arg ? count : rl_point)); } /* Exchange the position of mark and point. */ int rl_exchange_point_and_mark (count, key) int count, key; { if (rl_mark > rl_end) rl_mark = -1; if (rl_mark == -1) { ding (); return -1; } else SWAP (rl_point, rl_mark); return 0; } /* **************************************************************** */ /* */ /* Editing Modes */ /* */ /* **************************************************************** */ /* How to toggle back and forth between editing modes. */ int rl_vi_editing_mode (count, key) int count, key; { #if defined (VI_MODE) rl_editing_mode = vi_mode; rl_vi_insertion_mode (1, key); #endif /* VI_MODE */ return 0; } int rl_emacs_editing_mode (count, key) int count, key; { rl_editing_mode = emacs_mode; _rl_keymap = emacs_standard_keymap; return 0; }