smol/src/winio.c

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/* $Id$ */
/**************************************************************************
* winio.c *
* *
* Copyright (C) 1999-2005 Chris Allegretta *
* This program 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 2, or (at your option) *
* any later version. *
* *
* This program 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. *
* *
* You should have received a copy of the GNU General Public License *
* along with this program; if not, write to the Free Software *
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA *
* 02110-1301, USA. *
* *
**************************************************************************/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <stdarg.h>
#include <string.h>
#include <stdlib.h>
#include <unistd.h>
#include <ctype.h>
#include <assert.h>
#include "proto.h"
static int *key_buffer = NULL;
/* The default keystroke buffer,
* containing all the keystrokes we have
* at a given point. */
static size_t key_buffer_len = 0;
/* The length of the default keystroke
* buffer. */
static int statusblank = 0; /* The number of keystrokes left after
* we call statusbar(), before we
* actually blank the statusbar. */
static size_t statusbar_x = (size_t)-1;
/* The cursor position in answer. */
static bool resetstatuspos = FALSE;
/* Should we reset the cursor position
* at the statusbar prompt? */
/* Control character compatibility:
*
* - NANO_BACKSPACE_KEY is Ctrl-H, which is Backspace under ASCII, ANSI,
* VT100, and VT220.
* - NANO_TAB_KEY is Ctrl-I, which is Tab under ASCII, ANSI, VT100,
* VT220, and VT320.
* - NANO_ENTER_KEY is Ctrl-M, which is Enter under ASCII, ANSI, VT100,
* VT220, and VT320.
* - NANO_XON_KEY is Ctrl-Q, which is XON under ASCII, ANSI, VT100,
* VT220, and VT320.
* - NANO_XOFF_KEY is Ctrl-S, which is XOFF under ASCII, ANSI, VT100,
* VT220, and VT320.
* - NANO_CONTROL_8 is Ctrl-8 (Ctrl-?), which is Delete under ASCII,
* ANSI, VT100, and VT220, and which is Backspace under VT320.
*
* Note: VT220 and VT320 also generate Esc [ 3 ~ for Delete. By
* default, xterm assumes it's running on a VT320 and generates Ctrl-8
* (Ctrl-?) for Backspace and Esc [ 3 ~ for Delete. This causes
* problems for VT100-derived terminals such as the FreeBSD console,
* which expect Ctrl-H for Backspace and Ctrl-8 (Ctrl-?) for Delete, and
* on which the VT320 sequences are translated by the keypad to KEY_DC
* and [nothing]. We work around this conflict via the REBIND_DELETE
* flag: if it's not set, we assume VT320 compatibility, and if it is,
* we assume VT100 compatibility. Thanks to Lee Nelson and Wouter van
* Hemel for helping work this conflict out.
*
* Escape sequence compatibility:
*
* We support escape sequences for ANSI, VT100, VT220, VT320, the Linux
* console, the FreeBSD console, the Mach console (a.k.a. the Hurd
* console), xterm, rxvt, and Eterm. Among these, there are several
* conflicts and omissions, outlined as follows:
*
* - Tab on ANSI == PageUp on FreeBSD console; the former is omitted.
* (Ctrl-I is also Tab on ANSI, which we already support.)
* - PageDown on FreeBSD console == Center (5) on numeric keypad with
* NumLock off on Linux console; the latter is omitted. (The editing
* keypad key is more important to have working than the numeric
* keypad key, because the latter has no value when NumLock is off.)
* - F1 on FreeBSD console == the mouse key on xterm/rxvt/Eterm; the
* latter is omitted. (Mouse input will only work properly if the
* extended keypad value KEY_MOUSE is generated on mouse events
* instead of the escape sequence.)
* - F9 on FreeBSD console == PageDown on Mach console; the former is
* omitted. (The editing keypad is more important to have working
* than the function keys, because the functions of the former are not
* arbitrary and the functions of the latter are.)
* - F10 on FreeBSD console == PageUp on Mach console; the former is
* omitted. (Same as above.)
* - F13 on FreeBSD console == End on Mach console; the former is
* omitted. (Same as above.)
* - F15 on FreeBSD console == Shift-Up on rxvt/Eterm; the former is
* omitted. (The arrow keys, with or without modifiers, are more
* important to have working than the function keys, because the
* functions of the former are not arbitrary and the functions of the
* latter are.)
* - F16 on FreeBSD console == Shift-Down on rxvt/Eterm; the former is
* omitted. (Same as above.)
*
* Note that Center (5) on the numeric keypad with NumLock off can also
* be the Begin key. */
#ifndef NANO_SMALL
/* Reset all the input routines that rely on character sequences. */
void reset_kbinput(void)
{
parse_kbinput(NULL, NULL, NULL, TRUE);
get_byte_kbinput(0, TRUE);
get_word_kbinput(0, TRUE);
}
#endif
/* Read in a sequence of keystrokes from win and save them in the
* default keystroke buffer. This should only be called when the
* default keystroke buffer is empty. */
void get_buffer(WINDOW *win)
{
int input;
/* If the keystroke buffer isn't empty, get out. */
if (key_buffer != NULL)
return;
/* Read in the first character using blocking input. */
#ifndef NANO_SMALL
allow_pending_sigwinch(TRUE);
#endif
input = wgetch(win);
/* If we get ERR when using blocking input, it means that the input
* source that we were using is gone, so die gracefully. */
if (input == ERR)
handle_hupterm(0);
#ifndef NANO_SMALL
allow_pending_sigwinch(FALSE);
#endif
/* Increment the length of the keystroke buffer, save the value of
* the keystroke in key, and set key_code to TRUE if the keystroke
* is an extended keypad value or FALSE if it isn't. */
key_buffer_len++;
key_buffer = (int *)nmalloc(sizeof(int));
key_buffer[0] = input;
/* Read in the remaining characters using non-blocking input. */
nodelay(win, TRUE);
while (TRUE) {
#ifndef NANO_SMALL
allow_pending_sigwinch(TRUE);
#endif
input = wgetch(win);
/* If there aren't any more characters, stop reading. */
if (input == ERR)
break;
/* Otherwise, increment the length of the keystroke buffer, save
* the value of the keystroke in key, and set key_code to TRUE
* if the keystroke is an extended keypad value or FALSE if it
* isn't. */
key_buffer_len++;
key_buffer = (int *)nrealloc(key_buffer, key_buffer_len *
sizeof(int));
key_buffer[key_buffer_len - 1] = input;
#ifndef NANO_SMALL
allow_pending_sigwinch(FALSE);
#endif
}
/* Switch back to non-blocking input. */
nodelay(win, FALSE);
#ifdef DEBUG
fprintf(stderr, "get_buffer(): key_buffer_len = %lu\n", (unsigned long)key_buffer_len);
#endif
}
/* Return the length of the default keystroke buffer. */
size_t get_buffer_len(void)
{
return key_buffer_len;
}
/* Add the contents of the keystroke buffer input to the default
* keystroke buffer. */
void unget_input(int *input, size_t input_len)
{
#ifndef NANO_SMALL
allow_pending_sigwinch(TRUE);
allow_pending_sigwinch(FALSE);
#endif
/* If input is empty, get out. */
if (input_len == 0)
return;
/* If adding input would put the default keystroke buffer beyond
* maximum capacity, only add enough of input to put it at maximum
* capacity. */
if (key_buffer_len + input_len < key_buffer_len)
input_len = (size_t)-1 - key_buffer_len;
/* Add the length of input to the length of the default keystroke
* buffer, and reallocate the default keystroke buffer so that it
* has enough room for input. */
key_buffer_len += input_len;
key_buffer = (int *)nrealloc(key_buffer, key_buffer_len *
sizeof(int));
/* If the default keystroke buffer wasn't empty before, move its
* beginning forward far enough so that we can add input to its
* beginning. */
if (key_buffer_len > input_len)
memmove(key_buffer + input_len, key_buffer,
(key_buffer_len - input_len) * sizeof(int));
/* Copy input to the beginning of the default keystroke buffer. */
memcpy(key_buffer, input, input_len * sizeof(int));
}
/* Put back the character stored in kbinput, putting it in byte range
* beforehand. If meta_key is TRUE, put back the Escape character after
* putting back kbinput. If func_key is TRUE, put back the function key
* (a value outside byte range) without putting it in byte range. */
void unget_kbinput(int kbinput, bool meta_key, bool func_key)
{
if (!func_key)
kbinput = (char)kbinput;
unget_input(&kbinput, 1);
if (meta_key) {
kbinput = NANO_CONTROL_3;
unget_input(&kbinput, 1);
}
}
/* Try to read input_len characters from the default keystroke buffer.
* If the default keystroke buffer is empty and win isn't NULL, try to
* read in more characters from win and add them to the default
* keystroke buffer before doing anything else. If the default
* keystroke buffer is empty and win is NULL, return NULL. */
int *get_input(WINDOW *win, size_t input_len)
{
int *input;
#ifndef NANO_SMALL
allow_pending_sigwinch(TRUE);
allow_pending_sigwinch(FALSE);
#endif
if (key_buffer_len == 0) {
if (win != NULL)
get_buffer(win);
if (key_buffer_len == 0)
return NULL;
}
/* If input_len is greater than the length of the default keystroke
* buffer, only read the number of characters in the default
* keystroke buffer. */
if (input_len > key_buffer_len)
input_len = key_buffer_len;
/* Subtract input_len from the length of the default keystroke
* buffer, and allocate the keystroke buffer input so that it
* has enough room for input_len keystrokes. */
key_buffer_len -= input_len;
input = (int *)nmalloc(input_len * sizeof(int));
/* Copy input_len characters from the beginning of the default
* keystroke buffer into input. */
memcpy(input, key_buffer, input_len * sizeof(int));
/* If the default keystroke buffer is empty, mark it as such. */
if (key_buffer_len == 0) {
free(key_buffer);
key_buffer = NULL;
/* If the default keystroke buffer isn't empty, move its
* beginning forward far enough back so that the keystrokes in input
* are no longer at its beginning. */
} else {
memmove(key_buffer, key_buffer + input_len, key_buffer_len *
sizeof(int));
key_buffer = (int *)nrealloc(key_buffer, key_buffer_len *
sizeof(int));
}
return input;
}
/* Read in a single character. If it's ignored, swallow it and go on.
* Otherwise, try to translate it from ASCII, meta key sequences, escape
* sequences, and/or extended keypad values. Set meta_key to TRUE when
* we get a meta key sequence, and set func_key to TRUE when we get an
* extended keypad value. Supported extended keypad values consist of
* [arrow key], Ctrl-[arrow key], Shift-[arrow key], Enter, Backspace,
* the editing keypad (Insert, Delete, Home, End, PageUp, and PageDown),
* the function keypad (F1-F16), and the numeric keypad with NumLock
* off. Assume nodelay(win) is FALSE. */
int get_kbinput(WINDOW *win, bool *meta_key, bool *func_key)
{
int kbinput;
/* Read in a character and interpret it. Continue doing this until
* we get a recognized value or sequence. */
while ((kbinput = parse_kbinput(win, meta_key, func_key
#ifndef NANO_SMALL
, FALSE
#endif
)) == ERR);
return kbinput;
}
/* Translate ASCII characters, extended keypad values, and escape
* sequences into their corresponding key values. Set meta_key to TRUE
* when we get a meta key sequence, and set func_key to TRUE when we get
* a function key. Assume nodelay(win) is FALSE. */
int parse_kbinput(WINDOW *win, bool *meta_key, bool *func_key
#ifndef NANO_SMALL
, bool reset
#endif
)
{
static int escapes = 0, byte_digits = 0;
int *kbinput, retval = ERR;
#ifndef NANO_SMALL
if (reset) {
escapes = 0;
byte_digits = 0;
return ERR;
}
#endif
*meta_key = FALSE;
*func_key = FALSE;
/* Read in a character. */
while ((kbinput = get_input(win, 1)) == NULL);
switch (*kbinput) {
case ERR:
break;
case NANO_CONTROL_3:
/* Increment the escape counter. */
escapes++;
switch (escapes) {
case 1:
/* One escape: wait for more input. */
case 2:
/* Two escapes: wait for more input. */
break;
default:
/* More than two escapes: reset the escape counter
* and wait for more input. */
escapes = 0;
}
break;
#if !defined(NANO_SMALL) && defined(KEY_RESIZE)
/* Since we don't change the default SIGWINCH handler when
* NANO_SMALL is defined, KEY_RESIZE is never generated. Also,
* Slang and SunOS 5.7-5.9 don't support KEY_RESIZE. */
case KEY_RESIZE:
break;
#endif
#ifdef PDCURSES
case KEY_SHIFT_L:
case KEY_SHIFT_R:
case KEY_CONTROL_L:
case KEY_CONTROL_R:
case KEY_ALT_L:
case KEY_ALT_R:
break;
#endif
default:
switch (escapes) {
case 0:
switch (*kbinput) {
case NANO_CONTROL_8:
retval = ISSET(REBIND_DELETE) ?
NANO_DELETE_KEY : NANO_BACKSPACE_KEY;
break;
case KEY_DOWN:
retval = NANO_NEXTLINE_KEY;
break;
case KEY_UP:
retval = NANO_PREVLINE_KEY;
break;
case KEY_LEFT:
retval = NANO_BACK_KEY;
break;
case KEY_RIGHT:
retval = NANO_FORWARD_KEY;
break;
#ifdef KEY_HOME
/* HP-UX 10 and 11 don't support KEY_HOME. */
case KEY_HOME:
retval = NANO_HOME_KEY;
break;
#endif
case KEY_BACKSPACE:
retval = NANO_BACKSPACE_KEY;
break;
case KEY_DC:
retval = ISSET(REBIND_DELETE) ?
NANO_BACKSPACE_KEY : NANO_DELETE_KEY;
break;
case KEY_IC:
retval = NANO_INSERTFILE_KEY;
break;
case KEY_NPAGE:
retval = NANO_NEXTPAGE_KEY;
break;
case KEY_PPAGE:
retval = NANO_PREVPAGE_KEY;
break;
case KEY_ENTER:
retval = NANO_ENTER_KEY;
break;
case KEY_A1: /* Home (7) on numeric keypad
* with NumLock off. */
retval = NANO_HOME_KEY;
break;
case KEY_A3: /* PageUp (9) on numeric keypad
* with NumLock off. */
retval = NANO_PREVPAGE_KEY;
break;
case KEY_B2: /* Center (5) on numeric keypad
* with NumLock off. */
break;
case KEY_C1: /* End (1) on numeric keypad
* with NumLock off. */
retval = NANO_END_KEY;
break;
case KEY_C3: /* PageDown (4) on numeric
* keypad with NumLock off. */
retval = NANO_NEXTPAGE_KEY;
break;
#ifdef KEY_BEG
/* Slang doesn't support KEY_BEG. */
case KEY_BEG: /* Center (5) on numeric keypad
* with NumLock off. */
break;
#endif
#ifdef KEY_END
/* HP-UX 10 and 11 don't support KEY_END. */
case KEY_END:
retval = NANO_END_KEY;
break;
#endif
#ifdef KEY_SUSPEND
/* Slang doesn't support KEY_SUSPEND. */
case KEY_SUSPEND:
retval = NANO_SUSPEND_KEY;
break;
#endif
#ifdef KEY_SLEFT
/* Slang doesn't support KEY_SLEFT. */
case KEY_SLEFT:
retval = NANO_BACK_KEY;
break;
#endif
#ifdef KEY_SRIGHT
/* Slang doesn't support KEY_SRIGHT. */
case KEY_SRIGHT:
retval = NANO_FORWARD_KEY;
break;
#endif
default:
retval = *kbinput;
break;
}
break;
case 1:
/* One escape followed by a non-escape: escape
* sequence mode. Reset the escape counter. If
* there aren't any other keys waiting, we have a
* meta key sequence, so set meta_key to TRUE and
* save the lowercase version of the non-escape
* character as the result. If there are other keys
* waiting, we have a true escape sequence, so
* interpret it. */
escapes = 0;
if (get_buffer_len() == 0) {
*meta_key = TRUE;
retval = tolower(*kbinput);
} else {
int *seq;
size_t seq_len;
bool ignore_seq;
/* Put back the non-escape character, get the
* complete escape sequence, translate the
* sequence into its corresponding key value,
* and save that as the result. */
unget_input(kbinput, 1);
seq_len = get_buffer_len();
seq = get_input(NULL, seq_len);
retval = get_escape_seq_kbinput(seq, seq_len,
&ignore_seq);
/* If the escape sequence is unrecognized and
* not ignored, put back all of its characters
* except for the initial escape. */
if (retval == ERR && !ignore_seq)
unget_input(seq, seq_len);
free(seq);
}
break;
case 2:
/* Two escapes followed by one or more decimal
* digits: byte sequence mode. If the word
* sequence's range is limited to 2XX (the first
* digit is in the '0' to '2' range and it's the
* first digit, or it's in the '0' to '9' range and
* it's not the first digit), increment the byte
* sequence counter and interpret the digit. If the
* byte sequence's range is not limited to 2XX, fall
* through. */
if (('0' <= *kbinput && *kbinput <= '6' &&
byte_digits == 0) || ('0' <= *kbinput &&
*kbinput <= '9' && byte_digits > 0)) {
int byte;
byte_digits++;
byte = get_byte_kbinput(*kbinput
#ifndef NANO_SMALL
, FALSE
#endif
);
if (byte != ERR) {
char *byte_mb;
int byte_mb_len, *seq, i;
/* If we've read in a complete byte
* sequence, reset the byte sequence counter
* and the escape counter, and put back the
* corresponding byte value. */
byte_digits = 0;
escapes = 0;
/* Put back the multibyte equivalent of the
* byte value. */
byte_mb = make_mbchar(byte, &byte_mb_len);
seq = (int *)nmalloc(byte_mb_len *
sizeof(int));
for (i = 0; i < byte_mb_len; i++)
seq[i] = (unsigned char)byte_mb[i];
unget_input(seq, byte_mb_len);
free(seq);
free(byte_mb);
}
} else {
/* Reset the escape counter. */
escapes = 0;
if (byte_digits == 0)
/* Two escapes followed by a non-decimal
* digit or a decimal digit that would
* create a byte sequence greater than 2XX,
* and we're not in the middle of a byte
* sequence: control character sequence
* mode. Interpret the control sequence and
* save the corresponding control character
* as the result. */
retval = get_control_kbinput(*kbinput);
else {
/* If we're in the middle of a byte
* sequence, reset the byte sequence counter
* and save the character we got as the
* result. */
byte_digits = 0;
retval = *kbinput;
}
}
break;
}
}
/* If we have a result and it's an extended keypad value (i.e, a
* value outside of byte range), set func_key to TRUE. */
if (retval != ERR)
*func_key = !is_byte(retval);
#ifdef DEBUG
fprintf(stderr, "parse_kbinput(): kbinput = %d, meta_key = %d, func_key = %d, escapes = %d, byte_digits = %d, retval = %d\n", *kbinput, (int)*meta_key, (int)*func_key, escapes, byte_digits, retval);
#endif
/* Return the result. */
return retval;
}
/* Translate escape sequences, most of which correspond to extended
* keypad values, into their corresponding key values. These sequences
* are generated when the keypad doesn't support the needed keys. If
* the escape sequence is recognized but we want to ignore it, return
* ERR and set ignore_seq to TRUE; if it's unrecognized, return ERR and
* set ignore_seq to FALSE. Assume that Escape has already been read
* in. */
int get_escape_seq_kbinput(const int *seq, size_t seq_len, bool
*ignore_seq)
{
int retval = ERR;
*ignore_seq = FALSE;
if (seq_len > 1) {
switch (seq[0]) {
case 'O':
switch (seq[1]) {
case '2':
if (seq_len >= 3) {
switch (seq[2]) {
case 'P': /* Esc O 2 P == F13 on
* xterm. */
retval = KEY_F(13);
break;
case 'Q': /* Esc O 2 Q == F14 on
* xterm. */
retval = KEY_F(14);
break;
case 'R': /* Esc O 2 R == F15 on
* xterm. */
retval = KEY_F(15);
break;
case 'S': /* Esc O 2 S == F16 on
* xterm. */
retval = KEY_F(16);
break;
}
}
break;
case 'A': /* Esc O A == Up on VT100/VT320/xterm. */
case 'B': /* Esc O B == Down on
* VT100/VT320/xterm. */
case 'C': /* Esc O C == Right on
* VT100/VT320/xterm. */
case 'D': /* Esc O D == Left on
* VT100/VT320/xterm. */
retval = get_escape_seq_abcd(seq[1]);
break;
case 'E': /* Esc O E == Center (5) on numeric keypad
* with NumLock off on xterm. */
*ignore_seq = TRUE;
break;
case 'F': /* Esc O F == End on xterm. */
retval = NANO_END_KEY;
break;
case 'H': /* Esc O H == Home on xterm. */
retval = NANO_HOME_KEY;
break;
case 'M': /* Esc O M == Enter on numeric keypad with
* NumLock off on VT100/VT220/VT320/xterm/
* Eterm. */
retval = NANO_ENTER_KEY;
break;
case 'P': /* Esc O P == F1 on VT100/VT220/VT320/Mach
* console. */
retval = KEY_F(1);
break;
case 'Q': /* Esc O Q == F2 on VT100/VT220/VT320/Mach
* console. */
retval = KEY_F(2);
break;
case 'R': /* Esc O R == F3 on VT100/VT220/VT320/Mach
* console. */
retval = KEY_F(3);
break;
case 'S': /* Esc O S == F4 on VT100/VT220/VT320/Mach
* console. */
retval = KEY_F(4);
break;
case 'T': /* Esc O T == F5 on Mach console. */
retval = KEY_F(5);
break;
case 'U': /* Esc O U == F6 on Mach console. */
retval = KEY_F(6);
break;
case 'V': /* Esc O V == F7 on Mach console. */
retval = KEY_F(7);
break;
case 'W': /* Esc O W == F8 on Mach console. */
retval = KEY_F(8);
break;
case 'X': /* Esc O X == F9 on Mach console. */
retval = KEY_F(9);
break;
case 'Y': /* Esc O Y == F10 on Mach console. */
retval = KEY_F(10);
break;
case 'a': /* Esc O a == Ctrl-Up on rxvt. */
case 'b': /* Esc O b == Ctrl-Down on rxvt. */
case 'c': /* Esc O c == Ctrl-Right on rxvt. */
case 'd': /* Esc O d == Ctrl-Left on rxvt. */
retval = get_escape_seq_abcd(seq[1]);
break;
case 'j': /* Esc O j == '*' on numeric keypad with
* NumLock off on VT100/VT220/VT320/xterm/
* rxvt. */
retval = '*';
break;
case 'k': /* Esc O k == '+' on numeric keypad with
* NumLock off on VT100/VT220/VT320/xterm/
* rxvt. */
retval = '+';
break;
case 'l': /* Esc O l == ',' on numeric keypad with
* NumLock off on VT100/VT220/VT320/xterm/
* rxvt. */
retval = '+';
break;
case 'm': /* Esc O m == '-' on numeric keypad with
* NumLock off on VT100/VT220/VT320/xterm/
* rxvt. */
retval = '-';
break;
case 'n': /* Esc O n == Delete (.) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* xterm/rxvt. */
retval = NANO_DELETE_KEY;
break;
case 'o': /* Esc O o == '/' on numeric keypad with
* NumLock off on VT100/VT220/VT320/xterm/
* rxvt. */
retval = '/';
break;
case 'p': /* Esc O p == Insert (0) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt. */
retval = NANO_INSERTFILE_KEY;
break;
case 'q': /* Esc O q == End (1) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt. */
retval = NANO_END_KEY;
break;
case 'r': /* Esc O r == Down (2) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt. */
retval = NANO_NEXTLINE_KEY;
break;
case 's': /* Esc O s == PageDown (3) on numeric
* keypad with NumLock off on VT100/VT220/
* VT320/rxvt. */
retval = NANO_NEXTPAGE_KEY;
break;
case 't': /* Esc O t == Left (4) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt. */
retval = NANO_BACK_KEY;
break;
case 'u': /* Esc O u == Center (5) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt/Eterm. */
*ignore_seq = TRUE;
break;
case 'v': /* Esc O v == Right (6) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt. */
retval = NANO_FORWARD_KEY;
break;
case 'w': /* Esc O w == Home (7) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt. */
retval = NANO_HOME_KEY;
break;
case 'x': /* Esc O x == Up (8) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt. */
retval = NANO_PREVLINE_KEY;
break;
case 'y': /* Esc O y == PageUp (9) on numeric keypad
* with NumLock off on VT100/VT220/VT320/
* rxvt. */
retval = NANO_PREVPAGE_KEY;
break;
}
break;
case 'o':
switch (seq[1]) {
case 'a': /* Esc o a == Ctrl-Up on Eterm. */
case 'b': /* Esc o b == Ctrl-Down on Eterm. */
case 'c': /* Esc o c == Ctrl-Right on Eterm. */
case 'd': /* Esc o d == Ctrl-Left on Eterm. */
retval = get_escape_seq_abcd(seq[1]);
break;
}
break;
case '[':
switch (seq[1]) {
case '1':
if (seq_len >= 3) {
switch (seq[2]) {
case '1': /* Esc [ 1 1 ~ == F1 on rxvt/
* Eterm. */
retval = KEY_F(1);
break;
case '2': /* Esc [ 1 2 ~ == F2 on rxvt/
* Eterm. */
retval = KEY_F(2);
break;
case '3': /* Esc [ 1 3 ~ == F3 on rxvt/
* Eterm. */
retval = KEY_F(3);
break;
case '4': /* Esc [ 1 4 ~ == F4 on rxvt/
* Eterm. */
retval = KEY_F(4);
break;
case '5': /* Esc [ 1 5 ~ == F5 on xterm/
* rxvt/Eterm. */
retval = KEY_F(5);
break;
case '7': /* Esc [ 1 7 ~ == F6 on
* VT220/VT320/Linux console/
* xterm/rxvt/Eterm. */
retval = KEY_F(6);
break;
case '8': /* Esc [ 1 8 ~ == F7 on
* VT220/VT320/Linux console/
* xterm/rxvt/Eterm. */
retval = KEY_F(7);
break;
case '9': /* Esc [ 1 9 ~ == F8 on
* VT220/VT320/Linux console/
* xterm/rxvt/Eterm. */
retval = KEY_F(8);
break;
case ';':
if (seq_len >= 4) {
switch (seq[3]) {
case '2':
if (seq_len >= 5) {
switch (seq[4]) {
case 'A': /* Esc [ 1 ; 2 A == Shift-Up on
* xterm. */
case 'B': /* Esc [ 1 ; 2 B == Shift-Down on
* xterm. */
case 'C': /* Esc [ 1 ; 2 C == Shift-Right on
* xterm. */
case 'D': /* Esc [ 1 ; 2 D == Shift-Left on
* xterm. */
retval = get_escape_seq_abcd(seq[4]);
break;
}
}
break;
case '5':
if (seq_len >= 5) {
switch (seq[4]) {
case 'A': /* Esc [ 1 ; 5 A == Ctrl-Up on
* xterm. */
case 'B': /* Esc [ 1 ; 5 B == Ctrl-Down on
* xterm. */
case 'C': /* Esc [ 1 ; 5 C == Ctrl-Right on
* xterm. */
case 'D': /* Esc [ 1 ; 5 D == Ctrl-Left on
* xterm. */
retval = get_escape_seq_abcd(seq[4]);
break;
}
}
break;
}
}
break;
default: /* Esc [ 1 ~ == Home on
* VT320/Linux console. */
retval = NANO_HOME_KEY;
break;
}
}
break;
case '2':
if (seq_len >= 3) {
switch (seq[2]) {
case '0': /* Esc [ 2 0 ~ == F9 on
* VT220/VT320/Linux console/
* xterm/rxvt/Eterm. */
retval = KEY_F(9);
break;
case '1': /* Esc [ 2 1 ~ == F10 on
* VT220/VT320/Linux console/
* xterm/rxvt/Eterm. */
retval = KEY_F(10);
break;
case '3': /* Esc [ 2 3 ~ == F11 on
* VT220/VT320/Linux console/
* xterm/rxvt/Eterm. */
retval = KEY_F(11);
break;
case '4': /* Esc [ 2 4 ~ == F12 on
* VT220/VT320/Linux console/
* xterm/rxvt/Eterm. */
retval = KEY_F(12);
break;
case '5': /* Esc [ 2 5 ~ == F13 on
* VT220/VT320/Linux console/
* rxvt/Eterm. */
retval = KEY_F(13);
break;
case '6': /* Esc [ 2 6 ~ == F14 on
* VT220/VT320/Linux console/
* rxvt/Eterm. */
retval = KEY_F(14);
break;
case '8': /* Esc [ 2 8 ~ == F15 on
* VT220/VT320/Linux console/
* rxvt/Eterm. */
retval = KEY_F(15);
break;
case '9': /* Esc [ 2 9 ~ == F16 on
* VT220/VT320/Linux console/
* rxvt/Eterm. */
retval = KEY_F(16);
break;
default: /* Esc [ 2 ~ == Insert on
* VT220/VT320/Linux console/
* xterm. */
retval = NANO_INSERTFILE_KEY;
break;
}
}
break;
case '3': /* Esc [ 3 ~ == Delete on VT220/VT320/
* Linux console/xterm. */
retval = NANO_DELETE_KEY;
break;
case '4': /* Esc [ 4 ~ == End on VT220/VT320/Linux
* console/xterm. */
retval = NANO_END_KEY;
break;
case '5': /* Esc [ 5 ~ == PageUp on VT220/VT320/
* Linux console/xterm; Esc [ 5 ^ ==
* PageUp on Eterm. */
retval = NANO_PREVPAGE_KEY;
break;
case '6': /* Esc [ 6 ~ == PageDown on VT220/VT320/
* Linux console/xterm; Esc [ 6 ^ ==
* PageDown on Eterm. */
retval = NANO_NEXTPAGE_KEY;
break;
case '7': /* Esc [ 7 ~ == Home on rxvt. */
retval = NANO_HOME_KEY;
break;
case '8': /* Esc [ 8 ~ == End on rxvt. */
retval = NANO_END_KEY;
break;
case '9': /* Esc [ 9 == Delete on Mach console. */
retval = NANO_DELETE_KEY;
break;
case '@': /* Esc [ @ == Insert on Mach console. */
retval = NANO_INSERTFILE_KEY;
break;
case 'A': /* Esc [ A == Up on ANSI/VT220/Linux
* console/FreeBSD console/Mach console/
* rxvt/Eterm. */
case 'B': /* Esc [ B == Down on ANSI/VT220/Linux
* console/FreeBSD console/Mach console/
* rxvt/Eterm. */
case 'C': /* Esc [ C == Right on ANSI/VT220/Linux
* console/FreeBSD console/Mach console/
* rxvt/Eterm. */
case 'D': /* Esc [ D == Left on ANSI/VT220/Linux
* console/FreeBSD console/Mach console/
* rxvt/Eterm. */
retval = get_escape_seq_abcd(seq[1]);
break;
case 'E': /* Esc [ E == Center (5) on numeric keypad
* with NumLock off on FreeBSD console. */
*ignore_seq = TRUE;
break;
case 'F': /* Esc [ F == End on FreeBSD
* console/Eterm. */
retval = NANO_END_KEY;
break;
case 'G': /* Esc [ G == PageDown on FreeBSD
* console. */
retval = NANO_NEXTPAGE_KEY;
break;
case 'H': /* Esc [ H == Home on ANSI/VT220/FreeBSD
* console/Mach console/Eterm. */
retval = NANO_HOME_KEY;
break;
case 'I': /* Esc [ I == PageUp on FreeBSD
* console. */
retval = NANO_PREVPAGE_KEY;
break;
case 'L': /* Esc [ L == Insert on ANSI/FreeBSD
* console. */
retval = NANO_INSERTFILE_KEY;
break;
case 'M': /* Esc [ M == F1 on FreeBSD console. */
retval = KEY_F(1);
break;
case 'N': /* Esc [ N == F2 on FreeBSD console. */
retval = KEY_F(2);
break;
case 'O':
if (seq_len >= 3) {
switch (seq[2]) {
case 'P': /* Esc [ O P == F1 on
* xterm. */
retval = KEY_F(1);
break;
case 'Q': /* Esc [ O Q == F2 on
* xterm. */
retval = KEY_F(2);
break;
case 'R': /* Esc [ O R == F3 on
* xterm. */
retval = KEY_F(3);
break;
case 'S': /* Esc [ O S == F4 on
* xterm. */
retval = KEY_F(4);
break;
}
} else {
/* Esc [ O == F3 on FreeBSD console. */
retval = KEY_F(3);
}
break;
case 'P': /* Esc [ P == F4 on FreeBSD console. */
retval = KEY_F(4);
break;
case 'Q': /* Esc [ Q == F5 on FreeBSD console. */
retval = KEY_F(5);
break;
case 'R': /* Esc [ R == F6 on FreeBSD console. */
retval = KEY_F(6);
break;
case 'S': /* Esc [ S == F7 on FreeBSD console. */
retval = KEY_F(7);
break;
case 'T': /* Esc [ T == F8 on FreeBSD console. */
retval = KEY_F(8);
break;
case 'U': /* Esc [ U == PageDown on Mach console. */
retval = NANO_NEXTPAGE_KEY;
break;
case 'V': /* Esc [ V == PageUp on Mach console. */
retval = NANO_PREVPAGE_KEY;
break;
case 'W': /* Esc [ W == F11 on FreeBSD console. */
retval = KEY_F(11);
break;
case 'X': /* Esc [ X == F12 on FreeBSD console. */
retval = KEY_F(12);
break;
case 'Y': /* Esc [ Y == End on Mach console. */
retval = NANO_END_KEY;
break;
case 'Z': /* Esc [ Z == F14 on FreeBSD console. */
retval = KEY_F(14);
break;
case 'a': /* Esc [ a == Shift-Up on rxvt/Eterm. */
case 'b': /* Esc [ b == Shift-Down on rxvt/Eterm. */
case 'c': /* Esc [ c == Shift-Right on rxvt/
* Eterm. */
case 'd': /* Esc [ d == Shift-Left on rxvt/Eterm. */
retval = get_escape_seq_abcd(seq[1]);
break;
case '[':
if (seq_len >= 3) {
switch (seq[2]) {
case 'A': /* Esc [ [ A == F1 on Linux
* console. */
retval = KEY_F(1);
break;
case 'B': /* Esc [ [ B == F2 on Linux
* console. */
retval = KEY_F(2);
break;
case 'C': /* Esc [ [ C == F3 on Linux
* console. */
retval = KEY_F(3);
break;
case 'D': /* Esc [ [ D == F4 on Linux
* console. */
retval = KEY_F(4);
break;
case 'E': /* Esc [ [ E == F5 on Linux
* console. */
retval = KEY_F(5);
break;
}
}
break;
}
break;
}
}
#ifdef DEBUG
fprintf(stderr, "get_escape_seq_kbinput(): retval = %d, ignore_seq = %d\n", retval, (int)*ignore_seq);
#endif
return retval;
}
/* Return the equivalent arrow key value for the case-insensitive
* letters A (up), B (down), C (right), and D (left). These are common
* to many escape sequences. */
int get_escape_seq_abcd(int kbinput)
{
switch (tolower(kbinput)) {
case 'a':
return NANO_PREVLINE_KEY;
case 'b':
return NANO_NEXTLINE_KEY;
case 'c':
return NANO_FORWARD_KEY;
case 'd':
return NANO_BACK_KEY;
default:
return ERR;
}
}
/* Translate a byte sequence: turn a three-digit decimal number from
* 000 to 255 into its corresponding byte value. */
int get_byte_kbinput(int kbinput
#ifndef NANO_SMALL
, bool reset
#endif
)
{
static int byte_digits = 0, byte = 0;
int retval = ERR;
#ifndef NANO_SMALL
if (reset) {
byte_digits = 0;
byte = 0;
return ERR;
}
#endif
/* Increment the byte digit counter. */
byte_digits++;
switch (byte_digits) {
case 1:
/* One digit: reset the byte sequence holder and add the
* digit we got to the 100's position of the byte sequence
* holder. */
byte = 0;
if ('0' <= kbinput && kbinput <= '2')
byte += (kbinput - '0') * 100;
else
/* If the character we got isn't a decimal digit, or if
* it is and it would put the byte sequence out of byte
* range, save it as the result. */
retval = kbinput;
break;
case 2:
/* Two digits: add the digit we got to the 10's position of
* the byte sequence holder. */
if (('0' <= kbinput && kbinput <= '5') || (byte < 200 &&
'6' <= kbinput && kbinput <= '9'))
byte += (kbinput - '0') * 10;
else
/* If the character we got isn't a decimal digit, or if
* it is and it would put the byte sequence out of byte
* range, save it as the result. */
retval = kbinput;
break;
case 3:
/* Three digits: add the digit we got to the 1's position of
* the byte sequence holder, and save the corresponding word
* value as the result. */
if (('0' <= kbinput && kbinput <= '5') || (byte < 250 &&
'6' <= kbinput && kbinput <= '9')) {
byte += (kbinput - '0');
retval = byte;
} else
/* If the character we got isn't a decimal digit, or if
* it is and it would put the word sequence out of word
* range, save it as the result. */
retval = kbinput;
break;
default:
/* More than three digits: save the character we got as the
* result. */
retval = kbinput;
break;
}
/* If we have a result, reset the byte digit counter and the byte
* sequence holder. */
if (retval != ERR) {
byte_digits = 0;
byte = 0;
}
#ifdef DEBUG
fprintf(stderr, "get_byte_kbinput(): kbinput = %d, byte_digits = %d, byte = %d, retval = %d\n", kbinput, byte_digits, byte, retval);
#endif
return retval;
}
/* Translate a word sequence: turn a four-digit hexadecimal number from
* 0000 to ffff (case-insensitive) into its corresponding word value. */
int get_word_kbinput(int kbinput
#ifndef NANO_SMALL
, bool reset
#endif
)
{
static int word_digits = 0, word = 0;
int retval = ERR;
#ifndef NANO_SMALL
if (reset) {
word_digits = 0;
word = 0;
return ERR;
}
#endif
/* Increment the word digit counter. */
word_digits++;
switch (word_digits) {
case 1:
/* One digit: reset the word sequence holder and add the
* digit we got to the 4096's position of the word sequence
* holder. */
word = 0;
if ('0' <= kbinput && kbinput <= '9')
word += (kbinput - '0') * 4096;
else if ('a' <= tolower(kbinput) && tolower(kbinput) <= 'f')
word += (tolower(kbinput) + 10 - 'a') * 4096;
else
/* If the character we got isn't a hexadecimal digit, or
* if it is and it would put the word sequence out of
* word range, save it as the result. */
retval = kbinput;
break;
case 2:
/* Two digits: add the digit we got to the 256's position of
* the word sequence holder. */
if ('0' <= kbinput && kbinput <= '9')
word += (kbinput - '0') * 256;
else if ('a' <= tolower(kbinput) && tolower(kbinput) <= 'f')
word += (tolower(kbinput) + 10 - 'a') * 256;
else
/* If the character we got isn't a hexadecimal digit, or
* if it is and it would put the word sequence out of
* word range, save it as the result. */
retval = kbinput;
break;
case 3:
/* Three digits: add the digit we got to the 16's position
* of the word sequence holder. */
if ('0' <= kbinput && kbinput <= '9')
word += (kbinput - '0') * 16;
else if ('a' <= tolower(kbinput) && tolower(kbinput) <= 'f')
word += (tolower(kbinput) + 10 - 'a') * 16;
else
/* If the character we got isn't a hexadecimal digit, or
* if it is and it would put the word sequence out of
* word range, save it as the result. */
retval = kbinput;
break;
case 4:
/* Four digits: add the digit we got to the 1's position of
* the word sequence holder, and save the corresponding word
* value as the result. */
if ('0' <= kbinput && kbinput <= '9') {
word += (kbinput - '0');
retval = word;
} else if ('a' <= tolower(kbinput) &&
tolower(kbinput) <= 'f') {
word += (tolower(kbinput) + 10 - 'a');
retval = word;
} else
/* If the character we got isn't a hexadecimal digit, or
* if it is and it would put the word sequence out of
* word range, save it as the result. */
retval = kbinput;
break;
default:
/* More than four digits: save the character we got as the
* result. */
retval = kbinput;
break;
}
/* If we have a result, reset the word digit counter and the word
* sequence holder. */
if (retval != ERR) {
word_digits = 0;
word = 0;
}
#ifdef DEBUG
fprintf(stderr, "get_word_kbinput(): kbinput = %d, word_digits = %d, word = %d, retval = %d\n", kbinput, word_digits, word, retval);
#endif
return retval;
}
/* Translate a control character sequence: turn an ASCII non-control
* character into its corresponding control character. */
int get_control_kbinput(int kbinput)
{
int retval;
/* Ctrl-2 (Ctrl-Space, Ctrl-@, Ctrl-`) */
if (kbinput == '2' || kbinput == ' ' || kbinput == '@' ||
kbinput == '`')
retval = NANO_CONTROL_SPACE;
/* Ctrl-3 (Ctrl-[, Esc) to Ctrl-7 (Ctrl-_) */
else if ('3' <= kbinput && kbinput <= '7')
retval = kbinput - 24;
/* Ctrl-8 (Ctrl-?) */
else if (kbinput == '8' || kbinput == '?')
retval = NANO_CONTROL_8;
/* Ctrl-A to Ctrl-_ */
else if ('A' <= kbinput && kbinput <= '_')
retval = kbinput - 64;
/* Ctrl-a to Ctrl-~ */
else if ('a' <= kbinput && kbinput <= '~')
retval = kbinput - 96;
else
retval = kbinput;
#ifdef DEBUG
fprintf(stderr, "get_control_kbinput(): kbinput = %d, retval = %d\n", kbinput, retval);
#endif
return retval;
}
/* Put the output-formatted characters in output back into the default
* keystroke buffer, so that they can be parsed and displayed as output
* again. */
void unparse_kbinput(char *output, size_t output_len)
{
int *input;
size_t i;
if (output_len == 0)
return;
input = (int *)nmalloc(output_len * sizeof(int));
for (i = 0; i < output_len; i++)
input[i] = (int)output[i];
unget_input(input, output_len);
free(input);
}
/* Read in a stream of characters verbatim, and return the length of the
* string in kbinput_len. Assume nodelay(win) is FALSE. */
int *get_verbatim_kbinput(WINDOW *win, size_t *kbinput_len)
{
int *retval;
/* Turn off flow control characters if necessary so that we can type
* them in verbatim, and turn the keypad off so that we don't get
* extended keypad values. */
if (ISSET(PRESERVE))
disable_flow_control();
keypad(win, FALSE);
/* Read in a stream of characters and interpret it if possible. */
retval = parse_verbatim_kbinput(win, kbinput_len);
/* Turn flow control characters back on if necessary and turn the
* keypad back on now that we're done. */
if (ISSET(PRESERVE))
enable_flow_control();
keypad(win, TRUE);
return retval;
}
/* Read in a stream of all available characters, and return the length
* of the string in kbinput_len. Translate the first few characters of
* the input into the corresponding word value if possible. After that,
* leave the input as-is. */
int *parse_verbatim_kbinput(WINDOW *win, size_t *kbinput_len)
{
int *kbinput, word, *retval;
/* Read in the first keystroke. */
while ((kbinput = get_input(win, 1)) == NULL);
/* Check whether the first keystroke is a hexadecimal digit. */
word = get_word_kbinput(*kbinput
#ifndef NANO_SMALL
, FALSE
#endif
);
/* If the first keystroke isn't a hexadecimal digit, put back the
* first keystroke. */
if (word != ERR)
unget_input(kbinput, 1);
/* Otherwise, read in keystrokes until we have a complete word
* sequence, and put back the corresponding word value. */
else {
char *word_mb;
int word_mb_len, *seq, i;
while (word == ERR) {
while ((kbinput = get_input(win, 1)) == NULL);
word = get_word_kbinput(*kbinput
#ifndef NANO_SMALL
, FALSE
#endif
);
}
/* Put back the multibyte equivalent of the word value. */
word_mb = make_mbchar(word, &word_mb_len);
seq = (int *)nmalloc(word_mb_len * sizeof(int));
for (i = 0; i < word_mb_len; i++)
seq[i] = (unsigned char)word_mb[i];
unget_input(seq, word_mb_len);
free(seq);
free(word_mb);
}
/* Get the complete sequence, and save the characters in it as the
* result. */
*kbinput_len = get_buffer_len();
retval = get_input(NULL, *kbinput_len);
return retval;
}
#ifndef DISABLE_MOUSE
/* Check for a mouse event, and if one's taken place, save the
* coordinates where it took place in mouse_x and mouse_y. After that,
* assuming allow_shortcuts is FALSE, if the shortcut list on the
* bottom two lines of the screen is visible and the mouse event took
* place on it, figure out which shortcut was clicked and put back the
* equivalent keystroke(s). Return FALSE if no keystrokes were
* put back, or TRUE if at least one was. Assume that KEY_MOUSE has
* already been read in. */
bool get_mouseinput(int *mouse_x, int *mouse_y, bool allow_shortcuts)
{
MEVENT mevent;
*mouse_x = -1;
*mouse_y = -1;
/* First, get the actual mouse event. */
if (getmouse(&mevent) == ERR)
return FALSE;
/* Save the screen coordinates where the mouse event took place. */
*mouse_x = mevent.x;
*mouse_y = mevent.y;
/* If we're allowing shortcuts, the current shortcut list is being
* displayed on the last two lines of the screen, and the mouse
* event took place inside it, we need to figure out which shortcut
* was clicked and put back the equivalent keystroke(s) for it. */
if (allow_shortcuts && !ISSET(NO_HELP) && wenclose(bottomwin,
*mouse_y, *mouse_x)) {
int i, j;
size_t currslen;
/* The number of shortcuts in the current shortcut list. */
const shortcut *s = currshortcut;
/* The actual shortcut we clicked on, starting at the first
* one in the current shortcut list. */
/* Get the shortcut lists' length. */
if (currshortcut == main_list)
currslen = MAIN_VISIBLE;
else {
currslen = length_of_list(currshortcut);
/* We don't show any more shortcuts than the main list
* does. */
if (currslen > MAIN_VISIBLE)
currslen = MAIN_VISIBLE;
}
/* Calculate the width of each shortcut in the list (it's the
* same for all of them). */
if (currslen < 2)
i = COLS / 6;
else
i = COLS / ((currslen / 2) + (currslen % 2));
/* Calculate the y-coordinate relative to the beginning of
* bottomwin. */
j = *mouse_y - ((2 - no_more_space()) + 1) - editwinrows;
/* If we're on the statusbar, beyond the end of the shortcut
* list, or beyond the end of a shortcut on the right side of
* the screen, don't do anything. */
if (j < 0 || (*mouse_x / i) >= currslen)
return FALSE;
j = (*mouse_x / i) * 2 + j;
if (j >= currslen)
return FALSE;
/* Go through the shortcut list to determine which shortcut was
* clicked. */
for (; j > 0; j--)
s = s->next;
/* And put back the equivalent key. Assume that each shortcut
* has, at the very least, an equivalent control key, an
* equivalent primary meta key sequence, or both. */
if (s->ctrlval != NANO_NO_KEY) {
unget_kbinput(s->ctrlval, FALSE, FALSE);
return TRUE;
} else if (s->metaval != NANO_NO_KEY) {
unget_kbinput(s->metaval, TRUE, FALSE);
return TRUE;
}
}
return FALSE;
}
#endif /* !DISABLE_MOUSE */
const shortcut *get_shortcut(const shortcut *s_list, int *kbinput, bool
*meta_key, bool *func_key)
{
const shortcut *s = s_list;
size_t slen = length_of_list(s_list);
#ifdef DEBUG
fprintf(stderr, "get_shortcut(): kbinput = %d, meta_key = %d, func_key = %d\n", *kbinput, (int)*meta_key, (int)*func_key);
#endif
/* Check for shortcuts. */
for (; slen > 0; slen--) {
/* We've found a shortcut if:
*
* 1. The key exists.
* 2. The key is a control key in the shortcut list.
* 3. meta_key is TRUE and the key is the primary or
* miscellaneous meta sequence in the shortcut list.
* 4. func_key is TRUE and the key is a function key in the
* shortcut list. */
if (*kbinput != NANO_NO_KEY && (*kbinput == s->ctrlval ||
(*meta_key == TRUE && (*kbinput == s->metaval ||
*kbinput == s->miscval)) || (*func_key == TRUE &&
*kbinput == s->funcval))) {
break;
}
s = s->next;
}
/* Translate the shortcut to either its control key or its meta key
* equivalent. Assume that the shortcut has an equivalent control
* key, an equivalent primary meta key sequence, or both. */
if (slen > 0) {
if (s->ctrlval != NANO_NO_KEY) {
*meta_key = FALSE;
*func_key = FALSE;
*kbinput = s->ctrlval;
return s;
} else if (s->metaval != NANO_NO_KEY) {
*meta_key = TRUE;
*func_key = FALSE;
*kbinput = s->metaval;
return s;
}
}
return NULL;
}
#ifndef NANO_SMALL
const toggle *get_toggle(int kbinput, bool meta_key)
{
const toggle *t = toggles;
#ifdef DEBUG
fprintf(stderr, "get_toggle(): kbinput = %d, meta_key = %d\n", kbinput, (int)meta_key);
#endif
/* Check for toggles. */
for (; t != NULL; t = t->next) {
/* We've found a toggle if meta_key is TRUE and the key is in
* the meta key toggle list. */
if (meta_key && kbinput == t->val)
break;
}
return t;
}
#endif /* !NANO_SMALL */
int do_statusbar_input(bool *meta_key, bool *func_key, bool *s_or_t,
bool *ran_func, bool *finished, bool allow_funcs)
{
int input;
/* The character we read in. */
static int *kbinput = NULL;
/* The input buffer. */
static size_t kbinput_len = 0;
/* The length of the input buffer. */
const shortcut *s;
bool have_shortcut;
*s_or_t = FALSE;
*ran_func = FALSE;
*finished = FALSE;
/* Read in a character. */
input = get_kbinput(bottomwin, meta_key, func_key);
#ifndef DISABLE_MOUSE
/* If we got a mouse click and it was on a shortcut, read in the
* shortcut character. */
if (allow_funcs && *func_key == TRUE && input == KEY_MOUSE) {
if (do_mouse())
input = get_kbinput(bottomwin, meta_key, func_key);
else
input = ERR;
}
#endif
/* Check for a shortcut in the current list. */
s = get_shortcut(currshortcut, &input, meta_key, func_key);
/* If we got a shortcut from the current list, or a "universal"
* statusbar prompt shortcut, set have_shortcut to TRUE. */
have_shortcut = (s != NULL || input == NANO_REFRESH_KEY ||
input == NANO_HOME_KEY || input == NANO_END_KEY ||
input == NANO_FORWARD_KEY || input == NANO_BACK_KEY ||
input == NANO_BACKSPACE_KEY || input == NANO_DELETE_KEY ||
input == NANO_CUT_KEY ||
#ifndef NANO_SMALL
input == NANO_NEXTWORD_KEY ||
#endif
(*meta_key == TRUE && (
#ifndef NANO_SMALL
input == NANO_PREVWORD_KEY ||
#endif
input == NANO_VERBATIM_KEY)));
/* Set s_or_t to TRUE if we got a shortcut. */
*s_or_t = have_shortcut;
if (allow_funcs) {
/* If we got a character, and it isn't a shortcut or toggle,
* it's a normal text character. Display the warning if we're
* in view mode, or add the character to the input buffer if
* we're not. */
if (input != ERR && *s_or_t == FALSE) {
/* If we're using restricted mode, the filename isn't blank,
* and we're at the "Write File" prompt, disable text
* input. */
if (!ISSET(RESTRICTED) || filename[0] == '\0' ||
currshortcut != writefile_list) {
kbinput_len++;
kbinput = (int *)nrealloc(kbinput, kbinput_len *
sizeof(int));
kbinput[kbinput_len - 1] = input;
}
}
/* If we got a shortcut, or if there aren't any other characters
* waiting after the one we read in, we need to display all the
* characters in the input buffer if it isn't empty. */
if (*s_or_t == TRUE || get_buffer_len() == 0) {
if (kbinput != NULL) {
/* Display all the characters in the input buffer at
* once, filtering out control characters. */
char *output = charalloc(kbinput_len + 1);
size_t i;
bool got_enter;
/* Whether we got the Enter key. */
for (i = 0; i < kbinput_len; i++)
output[i] = (char)kbinput[i];
output[i] = '\0';
do_statusbar_output(output, kbinput_len, &got_enter,
FALSE);
free(output);
/* Empty the input buffer. */
kbinput_len = 0;
free(kbinput);
kbinput = NULL;
}
}
if (have_shortcut) {
switch (input) {
/* Handle the "universal" statusbar prompt shortcuts. */
case NANO_REFRESH_KEY:
total_refresh();
break;
case NANO_HOME_KEY:
do_statusbar_home();
break;
case NANO_END_KEY:
do_statusbar_end();
break;
case NANO_FORWARD_KEY:
do_statusbar_right();
break;
case NANO_BACK_KEY:
do_statusbar_left();
break;
case NANO_BACKSPACE_KEY:
/* If we're using restricted mode, the filename
* isn't blank, and we're at the "Write File"
* prompt, disable Backspace. */
if (!ISSET(RESTRICTED) || filename[0] == '\0' ||
currshortcut != writefile_list)
do_statusbar_backspace();
break;
case NANO_DELETE_KEY:
/* If we're using restricted mode, the filename
* isn't blank, and we're at the "Write File"
* prompt, disable Delete. */
if (!ISSET(RESTRICTED) || filename[0] == '\0' ||
currshortcut != writefile_list)
do_statusbar_delete();
break;
case NANO_CUT_KEY:
/* If we're using restricted mode, the filename
* isn't blank, and we're at the "Write File"
* prompt, disable Cut. */
if (!ISSET(RESTRICTED) || filename[0] == '\0' ||
currshortcut != writefile_list)
do_statusbar_cut_text();
break;
#ifndef NANO_SMALL
case NANO_NEXTWORD_KEY:
do_statusbar_next_word();
break;
case NANO_PREVWORD_KEY:
if (*meta_key == TRUE)
do_statusbar_prev_word();
break;
#endif
case NANO_VERBATIM_KEY:
if (*meta_key == TRUE) {
/* If we're using restricted mode, the filename
* isn't blank, and we're at the "Write File"
* prompt, disable verbatim input. */
if (!ISSET(RESTRICTED) || filename[0] == '\0' ||
currshortcut != writefile_list) {
bool got_enter;
/* Whether we got the Enter key. */
do_statusbar_verbatim_input(&got_enter);
/* If we got the Enter key, set input to the
* key value for Enter, and set finished to
* TRUE to indicate that we're done. */
if (got_enter) {
input = NANO_ENTER_KEY;
*finished = TRUE;
}
}
break;
}
/* Handle the normal statusbar prompt shortcuts, setting
* ran_func to TRUE if we try to run their associated
* functions and setting finished to TRUE to indicate
* that we're done after trying to run their associated
* functions. */
default:
if (s->func != NULL) {
*ran_func = TRUE;
if (!ISSET(VIEW_MODE) || s->viewok)
s->func();
}
*finished = TRUE;
}
}
}
return input;
}
#ifndef DISABLE_MOUSE
bool do_statusbar_mouse(void)
{
/* FIXME: If we clicked on a location in the statusbar, the cursor
* should move to the location we clicked on. This functionality
* should be in this function. */
int mouse_x, mouse_y;
return get_mouseinput(&mouse_x, &mouse_y, TRUE);
}
#endif
void do_statusbar_home(void)
{
#ifndef NANO_SMALL
if (ISSET(SMART_HOME)) {
size_t statusbar_x_save = statusbar_x;
statusbar_x = indent_length(answer);
if (statusbar_x == statusbar_x_save ||
statusbar_x == strlen(answer))
statusbar_x = 0;
} else
#endif
statusbar_x = 0;
}
void do_statusbar_end(void)
{
statusbar_x = strlen(answer);
}
void do_statusbar_right(void)
{
if (statusbar_x < strlen(answer))
statusbar_x = move_mbright(answer, statusbar_x);
}
void do_statusbar_left(void)
{
if (statusbar_x > 0)
statusbar_x = move_mbleft(answer, statusbar_x);
}
void do_statusbar_backspace(void)
{
if (statusbar_x > 0) {
do_statusbar_left();
do_statusbar_delete();
}
}
void do_statusbar_delete(void)
{
if (answer[statusbar_x] != '\0') {
int char_buf_len = parse_mbchar(answer + statusbar_x, NULL,
NULL, NULL);
size_t line_len = strlen(answer + statusbar_x);
assert(statusbar_x < strlen(answer));
charmove(answer + statusbar_x, answer + statusbar_x +
char_buf_len, strlen(answer) - statusbar_x -
char_buf_len + 1);
null_at(&answer, statusbar_x + line_len - char_buf_len);
}
}
void do_statusbar_cut_text(void)
{
assert(answer != NULL);
#ifndef NANO_SMALL
if (ISSET(CUT_TO_END))
null_at(&answer, statusbar_x);
else {
#endif
null_at(&answer, 0);
statusbar_x = 0;
#ifndef NANO_SMALL
}
#endif
}
#ifndef NANO_SMALL
void do_statusbar_next_word(void)
{
char *char_mb;
int char_mb_len;
assert(answer != NULL);
char_mb = charalloc(mb_cur_max());
/* Move forward until we find the character after the last letter of
* the current word. */
while (answer[statusbar_x] != '\0') {
char_mb_len = parse_mbchar(answer + statusbar_x, char_mb, NULL,
NULL);
/* If we've found it, stop moving forward through the current
* line. */
if (!is_alnum_mbchar(char_mb))
break;
statusbar_x += char_mb_len;
}
/* Move forward until we find the first letter of the next word. */
if (answer[statusbar_x] != '\0')
statusbar_x += char_mb_len;
while (answer[statusbar_x] != '\0') {
char_mb_len = parse_mbchar(answer + statusbar_x, char_mb, NULL,
NULL);
/* If we've found it, stop moving forward through the current
* line. */
if (is_alnum_mbchar(char_mb))
break;
statusbar_x += char_mb_len;
}
free(char_mb);
}
void do_statusbar_prev_word(void)
{
char *char_mb;
int char_mb_len;
bool begin_line = FALSE;
assert(answer != NULL);
char_mb = charalloc(mb_cur_max());
/* Move backward until we find the character before the first letter
* of the current word. */
while (!begin_line) {
char_mb_len = parse_mbchar(answer + statusbar_x, char_mb, NULL,
NULL);
/* If we've found it, stop moving backward through the current
* line. */
if (!is_alnum_mbchar(char_mb))
break;
if (statusbar_x == 0)
begin_line = TRUE;
else
statusbar_x = move_mbleft(answer, statusbar_x);
}
/* Move backward until we find the last letter of the previous
* word. */
if (statusbar_x == 0)
begin_line = TRUE;
else
statusbar_x = move_mbleft(answer, statusbar_x);
while (!begin_line) {
char_mb_len = parse_mbchar(answer + statusbar_x, char_mb, NULL,
NULL);
/* If we've found it, stop moving backward through the current
* line. */
if (is_alnum_mbchar(char_mb))
break;
if (statusbar_x == 0)
begin_line = TRUE;
else
statusbar_x = move_mbleft(answer, statusbar_x);
}
/* If we've found it, move backward until we find the character
* before the first letter of the previous word. */
if (!begin_line) {
if (statusbar_x == 0)
begin_line = TRUE;
else
statusbar_x = move_mbleft(answer, statusbar_x);
while (!begin_line) {
char_mb_len = parse_mbchar(answer + statusbar_x, char_mb,
NULL, NULL);
/* If we've found it, stop moving backward through the
* current line. */
if (!is_alnum_mbchar(char_mb))
break;
if (statusbar_x == 0)
begin_line = TRUE;
else
statusbar_x = move_mbleft(answer, statusbar_x);
}
/* If we've found it, move forward to the first letter of the
* previous word. */
if (!begin_line)
statusbar_x += char_mb_len;
}
free(char_mb);
}
#endif
void do_statusbar_verbatim_input(bool *got_enter)
{
int *kbinput;
size_t kbinput_len, i;
char *output;
*got_enter = FALSE;
/* Read in all the verbatim characters. */
kbinput = get_verbatim_kbinput(bottomwin, &kbinput_len);
/* Display all the verbatim characters at once, not filtering out
* control characters. */
output = charalloc(kbinput_len + 1);
for (i = 0; i < kbinput_len; i++)
output[i] = (char)kbinput[i];
output[i] = '\0';
do_statusbar_output(output, kbinput_len, got_enter, TRUE);
free(output);
}
void do_statusbar_output(char *output, size_t output_len, bool
*got_enter, bool allow_cntrls)
{
size_t answer_len, i = 0;
char *char_buf = charalloc(mb_cur_max());
int char_buf_len;
assert(answer != NULL);
answer_len = strlen(answer);
*got_enter = FALSE;
while (i < output_len) {
/* If allow_cntrls is FALSE, filter out nulls and newlines,
* since they're control characters. */
if (allow_cntrls) {
/* Null to newline, if needed. */
if (output[i] == '\0')
output[i] = '\n';
/* Newline to Enter, if needed. */
else if (output[i] == '\n') {
/* Set got_enter to TRUE to indicate that we got the
* Enter key, put back the rest of the characters in
* output so that they can be parsed and output again,
* and get out. */
*got_enter = TRUE;
unparse_kbinput(output + i, output_len - i);
return;
}
}
/* Interpret the next multibyte character. If it's an invalid
* multibyte character, interpret it as though it's a byte
* character. */
char_buf_len = parse_mbchar(output + i, char_buf, NULL, NULL);
i += char_buf_len;
/* If allow_cntrls is FALSE, filter out a control character. */
if (!allow_cntrls && is_cntrl_mbchar(output + i - char_buf_len))
continue;
/* More dangerousness fun =) */
answer = charealloc(answer, answer_len + (char_buf_len * 2));
assert(statusbar_x <= answer_len);
charmove(&answer[statusbar_x + char_buf_len],
&answer[statusbar_x], answer_len - statusbar_x +
char_buf_len);
charcpy(&answer[statusbar_x], char_buf, char_buf_len);
answer_len += char_buf_len;
do_statusbar_right();
}
free(char_buf);
}
/* Return the placewewant associated with current_x, i.e, the zero-based
* column position of the cursor. The value will be no smaller than
* current_x. */
size_t xplustabs(void)
{
return strnlenpt(current->data, current_x);
}
/* actual_x() gives the index in str of the character displayed at
* column xplus. That is, actual_x() is the largest value such that
* strnlenpt(str, actual_x(str, xplus)) <= xplus. */
size_t actual_x(const char *str, size_t xplus)
{
size_t i = 0;
/* The position in str, returned. */
size_t length = 0;
/* The screen display width to str[i]. */
assert(str != NULL);
while (*str != '\0') {
int str_len = parse_mbchar(str, NULL, NULL, &length);
if (length > xplus)
break;
i += str_len;
str += str_len;
}
return i;
}
/* A strlen() with tabs factored in, similar to xplustabs(). How many
* columns wide are the first size characters of str? */
size_t strnlenpt(const char *str, size_t size)
{
size_t length = 0;
/* The screen display width to str[i]. */
if (size == 0)
return 0;
assert(str != NULL);
while (*str != '\0') {
int str_len = parse_mbchar(str, NULL, NULL, &length);
str += str_len;
if (size <= str_len)
break;
size -= str_len;
}
return length;
}
/* How many columns wide is buf? */
size_t strlenpt(const char *buf)
{
return strnlenpt(buf, (size_t)-1);
}
void blank_titlebar(void)
{
mvwaddstr(topwin, 0, 0, hblank);
}
void blank_topbar(void)
{
if (!ISSET(MORE_SPACE))
mvwaddstr(topwin, 1, 0, hblank);
}
void blank_edit(void)
{
int i;
for (i = 0; i < editwinrows; i++)
mvwaddstr(edit, i, 0, hblank);
}
void blank_statusbar(void)
{
mvwaddstr(bottomwin, 0, 0, hblank);
}
void blank_bottombars(void)
{
if (!ISSET(NO_HELP)) {
mvwaddstr(bottomwin, 1, 0, hblank);
mvwaddstr(bottomwin, 2, 0, hblank);
}
}
void check_statusblank(void)
{
if (statusblank > 1)
statusblank--;
else if (statusblank == 1 && !ISSET(CONSTUPDATE)) {
statusblank = 0;
blank_statusbar();
wnoutrefresh(bottomwin);
reset_cursor();
wrefresh(edit);
}
}
/* Convert buf into a string that can be displayed on screen. The
* caller wants to display buf starting with column start_col, and
* extending for at most len columns. start_col is zero-based. len is
* one-based, so len == 0 means you get "" returned. The returned
* string is dynamically allocated, and should be freed. If dollars is
* TRUE, the caller might put "$" at the beginning or end of the line if
* it's too long. */
char *display_string(const char *buf, size_t start_col, size_t len, bool
dollars)
{
size_t start_index;
/* Index in buf of the first character shown. */
size_t column;
/* Screen column that start_index corresponds to. */
size_t alloc_len;
/* The length of memory allocated for converted. */
char *converted;
/* The string we return. */
size_t index;
/* Current position in converted. */
char *buf_mb = charalloc(mb_cur_max());
int buf_mb_len;
bool bad_char;
/* If dollars is TRUE, make room for the "$" at the end of the
* line. */
if (dollars && len > 0 && strlenpt(buf) > start_col + len)
len--;
if (len == 0)
return mallocstrcpy(NULL, "");
start_index = actual_x(buf, start_col);
column = strnlenpt(buf, start_index);
assert(column <= start_col);
/* Allocate enough space for the entire line. It should contain
* (len + 2) multibyte characters at most. */
alloc_len = mb_cur_max() * (len + 2);
converted = charalloc(alloc_len + 1);
index = 0;
if (column < start_col || (dollars && column > 0 &&
buf[start_index] != '\t')) {
/* We don't display all of buf[start_index] since it starts to
* the left of the screen. */
buf_mb_len = parse_mbchar(buf + start_index, buf_mb, NULL,
NULL);
if (is_cntrl_mbchar(buf_mb)) {
if (column < start_col) {
char *ctrl_buf_mb = charalloc(mb_cur_max());
int ctrl_buf_mb_len, i;
ctrl_buf_mb = control_mbrep(buf_mb, ctrl_buf_mb,
&ctrl_buf_mb_len);
for (i = 0; i < ctrl_buf_mb_len; i++)
converted[index++] = ctrl_buf_mb[i];
start_col += mbwidth(ctrl_buf_mb);
free(ctrl_buf_mb);
start_index += buf_mb_len;
}
}
#ifdef NANO_WIDE
else if (mbwidth(buf_mb) > 1) {
converted[index++] = ' ';
start_col++;
start_index += buf_mb_len;
}
#endif
}
while (index < alloc_len - 1 && buf[start_index] != '\0') {
buf_mb_len = parse_mbchar(buf + start_index, buf_mb, &bad_char,
NULL);
if (*buf_mb == '\t') {
#if !defined(NANO_SMALL) && defined(ENABLE_NANORC)
if (ISSET(WHITESPACE_DISPLAY)) {
int i;
for (i = 0; i < whitespace_len[0]; i++)
converted[index++] = whitespace[i];
} else
#endif
converted[index++] = ' ';
start_col++;
while (start_col % tabsize != 0) {
converted[index++] = ' ';
start_col++;
}
/* If buf contains a control character, interpret it. If it
* contains an invalid multibyte control character, interpret
* that character as though it's a normal control character. */
} else if (is_cntrl_mbchar(buf_mb)) {
char *ctrl_buf_mb = charalloc(mb_cur_max());
int ctrl_buf_mb_len, i;
converted[index++] = '^';
start_col++;
ctrl_buf_mb = control_mbrep(buf_mb, ctrl_buf_mb,
&ctrl_buf_mb_len);
for (i = 0; i < ctrl_buf_mb_len; i++)
converted[index++] = ctrl_buf_mb[i];
start_col += mbwidth(ctrl_buf_mb);
free(ctrl_buf_mb);
} else if (*buf_mb == ' ') {
#if !defined(NANO_SMALL) && defined(ENABLE_NANORC)
if (ISSET(WHITESPACE_DISPLAY)) {
int i;
for (i = whitespace_len[0]; i < whitespace_len[0] +
whitespace_len[1]; i++)
converted[index++] = whitespace[i];
} else
#endif
converted[index++] = ' ';
start_col++;
} else {
int i;
#ifdef NANO_WIDE
/* If buf contains an invalid multibyte non-control
* character, interpret that character as though it's a
* normal non-control character. */
if (!ISSET(NO_UTF8) && bad_char) {
char *bad_buf_mb;
int bad_buf_mb_len;
bad_buf_mb = make_mbchar((unsigned char)*buf_mb,
&bad_buf_mb_len);
for (i = 0; i < bad_buf_mb_len; i++)
converted[index++] = bad_buf_mb[i];
start_col += mbwidth(bad_buf_mb);
free(bad_buf_mb);
} else {
#endif
for (i = 0; i < buf_mb_len; i++)
converted[index++] = buf[start_index + i];
start_col += mbwidth(buf_mb);
#ifdef NANO_WIDE
}
#endif
}
start_index += buf_mb_len;
}
if (index < alloc_len - 1)
converted[index] = '\0';
/* Make sure converted takes up no more than len columns. */
index = actual_x(converted, len);
null_at(&converted, index);
return converted;
}
/* Repaint the statusbar when getting a character in nanogetstr(). buf
* should be no longer than max(0, COLS - 4).
*
* Note that we must turn on A_REVERSE here, since do_help() turns it
* off! */
void nanoget_repaint(const char *buf, const char *inputbuf, size_t x)
{
size_t x_real = strnlenpt(inputbuf, x);
int wid = COLS - strlenpt(buf) - 2;
assert(x <= strlen(inputbuf));
wattron(bottomwin, A_REVERSE);
blank_statusbar();
mvwaddstr(bottomwin, 0, 0, buf);
waddch(bottomwin, ':');
if (COLS > 1)
waddch(bottomwin, x_real < wid ? ' ' : '$');
if (COLS > 2) {
size_t page_start = x_real - x_real % wid;
char *expanded = display_string(inputbuf, page_start, wid,
FALSE);
assert(wid > 0);
assert(strlenpt(expanded) <= wid);
waddstr(bottomwin, expanded);
free(expanded);
wmove(bottomwin, 0, COLS - wid + x_real - page_start);
} else
wmove(bottomwin, 0, COLS - 1);
wattroff(bottomwin, A_REVERSE);
}
/* Get the input from the keyboard; this should only be called from
* statusq(). */
int nanogetstr(bool allow_tabs, const char *buf, const char *curranswer,
#ifndef NANO_SMALL
filestruct *history_list,
#endif
const shortcut *s
#ifndef DISABLE_TABCOMP
, bool *list
#endif
)
{
int kbinput;
bool meta_key, func_key, s_or_t, ran_func, finished;
size_t curranswer_len = strlen(curranswer);
#ifndef DISABLE_TABCOMP
bool tabbed = FALSE;
/* Whether we've pressed Tab more than once consecutively. */
#endif
#ifndef NANO_SMALL
char *history = NULL;
/* The current history string. */
char *magichistory = NULL;
/* The temporary string typed at the bottom of the history, if
* any. */
#endif
answer = mallocstrcpy(answer, curranswer);
/* Only put statusbar_x at the end of the string if it's
* uninitialized, if it would be past the end of curranswer, or if
* resetstatuspos is TRUE. Otherwise, leave it alone. This is so
* the cursor position stays at the same place if a prompt-changing
* toggle is pressed. */
if (statusbar_x == (size_t)-1 || statusbar_x > curranswer_len ||
resetstatuspos)
statusbar_x = curranswer_len;
currshortcut = s;
nanoget_repaint(buf, answer, statusbar_x);
/* Refresh the edit window and the statusbar before getting
* input. */
wnoutrefresh(edit);
wrefresh(bottomwin);
/* If we're using restricted mode, we aren't allowed to change the
* name of a file once it has one because that would allow writing
* to files not specified on the command line. In this case,
* disable all keys that would change the text if the filename isn't
* blank and we're at the "Write File" prompt. */
while ((kbinput = do_statusbar_input(&meta_key, &func_key,
&s_or_t, &ran_func, &finished, TRUE)) != NANO_CANCEL_KEY &&
kbinput != NANO_ENTER_KEY) {
assert(statusbar_x <= strlen(answer));
#ifndef DISABLE_TABCOMP
if (kbinput != NANO_TAB_KEY)
tabbed = FALSE;
#endif
switch (kbinput) {
case NANO_TAB_KEY:
#ifndef DISABLE_TABCOMP
if (allow_tabs)
answer = input_tab(answer, &statusbar_x, &tabbed,
list);
#endif
break;
case NANO_PREVLINE_KEY:
#ifndef NANO_SMALL
if (history_list != NULL) {
/* If we're scrolling up at the bottom of the
* history list, answer isn't blank, and
* magichistory isn't set, save answer in
* magichistory. */
if (history_list->next == NULL &&
answer[0] != '\0' && magichistory == NULL)
magichistory = mallocstrcpy(NULL, answer);
/* Get the older search from the history list and
* save it in answer. If there is no older search,
* don't do anything. */
if ((history =
get_history_older(&history_list)) != NULL) {
answer = mallocstrcpy(answer, history);
statusbar_x = strlen(answer);
}
/* This key has a shortcut list entry when it's used
* to move to an older search, which means that
* finished has been set to TRUE. Set it back to
* FALSE here, so that we aren't kicked out of the
* statusbar prompt. */
finished = FALSE;
}
#endif
break;
case NANO_NEXTLINE_KEY:
#ifndef NANO_SMALL
if (history_list != NULL) {
/* Get the newer search from the history list and
* save it in answer. If there is no newer search,
* don't do anything. */
if ((history =
get_history_newer(&history_list)) != NULL) {
answer = mallocstrcpy(answer, history);
statusbar_x = strlen(answer);
}
/* If, after scrolling down, we're at the bottom of
* the history list, answer is blank, and
* magichistory is set, save magichistory in
* answer. */
if (history_list->next == NULL &&
answer[0] == '\0' && magichistory != NULL) {
answer = mallocstrcpy(answer, magichistory);
statusbar_x = strlen(answer);
}
}
#endif
break;
}
/* If we have a shortcut with an associated function, break out
* if we're finished after running or trying to run the
* function. */
if (finished)
break;
nanoget_repaint(buf, answer, statusbar_x);
wrefresh(bottomwin);
}
#ifndef NANO_SMALL
/* Free msgichistory if we need to. */
if (magichistory != NULL)
free(magichistory);
#endif
/* We finished putting in an answer or ran a normal shortcut's
* associated function, so reset statusbar_x. */
if (kbinput == NANO_CANCEL_KEY || kbinput == NANO_ENTER_KEY ||
ran_func)
statusbar_x = (size_t)-1;
return kbinput;
}
/* Ask a question on the statusbar. Answer will be stored in answer
* global. Returns -1 on aborted enter, -2 on a blank string, and 0
* otherwise, the valid shortcut key caught. curranswer is any editable
* text that we want to put up by default.
*
* The allow_tabs parameter indicates whether we should allow tabs to be
* interpreted. */
int statusq(bool allow_tabs, const shortcut *s, const char *curranswer,
#ifndef NANO_SMALL
filestruct *history_list,
#endif
const char *msg, ...)
{
va_list ap;
char *foo = charalloc(((COLS - 4) * mb_cur_max()) + 1);
int retval;
#ifndef DISABLE_TABCOMP
bool list = FALSE;
#endif
bottombars(s);
va_start(ap, msg);
vsnprintf(foo, (COLS - 4) * mb_cur_max(), msg, ap);
va_end(ap);
null_at(&foo, actual_x(foo, COLS - 4));
retval = nanogetstr(allow_tabs, foo, curranswer,
#ifndef NANO_SMALL
history_list,
#endif
s
#ifndef DISABLE_TABCOMP
, &list
#endif
);
free(foo);
resetstatuspos = FALSE;
switch (retval) {
case NANO_CANCEL_KEY:
retval = -1;
resetstatuspos = TRUE;
break;
case NANO_ENTER_KEY:
retval = (answer[0] == '\0') ? -2 : 0;
resetstatuspos = TRUE;
break;
}
blank_statusbar();
#ifdef DEBUG
fprintf(stderr, "answer = \"%s\"\n", answer);
#endif
#ifndef DISABLE_TABCOMP
/* If we've done tab completion, there might be a list of
* filename matches on the edit window at this point. Make sure
* that they're cleared off. */
if (list)
edit_refresh();
#endif
return retval;
}
void statusq_abort(void)
{
resetstatuspos = TRUE;
}
void titlebar(const char *path)
{
int space;
/* The space we have available for display. */
size_t verlen = strlenpt(VERMSG) + 1;
/* The length of the version message in columns. */
const char *prefix;
/* "File:", "Dir:", or "New Buffer". Goes before filename. */
size_t prefixlen;
/* The length of the prefix in columns, plus one. */
const char *state;
/* "Modified", "View", or spaces the length of "Modified".
* Tells the state of this buffer. */
size_t statelen = 0;
/* The length of the state in columns, plus one. */
char *exppath = NULL;
/* The file name, expanded for display. */
bool newfie = FALSE;
/* Do we say "New Buffer"? */
bool dots = FALSE;
/* Do we put an ellipsis before the path? */
assert(path != NULL || filename != NULL);
assert(COLS >= 0);
wattron(topwin, A_REVERSE);
blank_titlebar();
if (COLS <= 5 || COLS - 5 < verlen)
space = 0;
else {
space = COLS - 5 - verlen;
/* Reserve 2/3 of the screen plus one column for after the
* version message. */
if (space < COLS - (COLS / 3) + 1)
space = COLS - (COLS / 3) + 1;
}
if (COLS > 4) {
/* The version message should only take up 1/3 of the screen
* minus one column. */
mvwaddnstr(topwin, 0, 2, VERMSG, (COLS / 3) - 3);
waddstr(topwin, " ");
}
if (ISSET(MODIFIED))
state = _("Modified");
else if (ISSET(VIEW_MODE))
state = _("View");
else {
if (space > 0)
statelen = strnlenpt(_("Modified"), space - 1) + 1;
state = &hblank[COLS - statelen];
}
statelen = strnlenpt(state, COLS);
/* We need a space before state. */
if ((ISSET(MODIFIED) || ISSET(VIEW_MODE)) && statelen < COLS)
statelen++;
assert(space >= 0);
if (space == 0 || statelen >= space)
goto the_end;
#ifndef DISABLE_BROWSER
if (path != NULL)
prefix = _("DIR:");
else
#endif
if (filename[0] == '\0') {
prefix = _("New Buffer");
newfie = TRUE;
} else
prefix = _("File:");
assert(statelen < space);
prefixlen = strnlenpt(prefix, space - statelen);
/* If newfie is FALSE, we need a space after prefix. */
if (!newfie && prefixlen + statelen < space)
prefixlen++;
if (path == NULL)
path = filename;
if (space >= prefixlen + statelen)
space -= prefixlen + statelen;
else
space = 0;
/* space is now the room we have for the file name. */
if (!newfie) {
size_t lenpt = strlenpt(path), start_col;
dots = (lenpt > space);
if (dots) {
start_col = lenpt - space + 3;
space -= 3;
} else
start_col = 0;
exppath = display_string(path, start_col, space, FALSE);
}
if (!dots) {
size_t exppathlen = newfie ? 0 : strlenpt(exppath);
/* The length of the expanded filename. */
/* There is room for the whole filename, so we center it. */
waddnstr(topwin, hblank, (space - exppathlen) / 3);
waddnstr(topwin, prefix, actual_x(prefix, prefixlen));
if (!newfie) {
assert(strlenpt(prefix) + 1 == prefixlen);
waddch(topwin, ' ');
waddstr(topwin, exppath);
}
} else {
/* We will say something like "File: ...ename". */
waddnstr(topwin, prefix, actual_x(prefix, prefixlen));
if (space <= -3 || newfie)
goto the_end;
waddch(topwin, ' ');
waddnstr(topwin, "...", space + 3);
if (space <= 0)
goto the_end;
waddstr(topwin, exppath);
}
the_end:
free(exppath);
if (COLS <= 1 || statelen >= COLS - 1)
mvwaddnstr(topwin, 0, 0, state, actual_x(state, COLS));
else {
assert(COLS - statelen - 2 >= 0);
mvwaddch(topwin, 0, COLS - statelen - 2, ' ');
mvwaddnstr(topwin, 0, COLS - statelen - 1, state,
actual_x(state, statelen));
}
wattroff(topwin, A_REVERSE);
wnoutrefresh(topwin);
reset_cursor();
wrefresh(edit);
}
/* If modified is not already set, set it and update titlebar. */
void set_modified(void)
{
if (!ISSET(MODIFIED)) {
SET(MODIFIED);
titlebar(NULL);
}
}
void statusbar(const char *msg, ...)
{
va_list ap;
va_start(ap, msg);
/* Curses mode is turned off. If we use wmove() now, it will muck
* up the terminal settings. So we just use vfprintf(). */
if (curses_ended) {
vfprintf(stderr, msg, ap);
va_end(ap);
return;
}
/* Blank out the line. */
blank_statusbar();
if (COLS >= 4) {
char *bar, *foo;
size_t start_x = 0, foo_len;
#if !defined(NANO_SMALL) && defined(ENABLE_NANORC)
bool old_whitespace = ISSET(WHITESPACE_DISPLAY);
UNSET(WHITESPACE_DISPLAY);
#endif
bar = charalloc(mb_cur_max() * (COLS - 3));
vsnprintf(bar, mb_cur_max() * (COLS - 3), msg, ap);
va_end(ap);
foo = display_string(bar, 0, COLS - 4, FALSE);
#if !defined(NANO_SMALL) && defined(ENABLE_NANORC)
if (old_whitespace)
SET(WHITESPACE_DISPLAY);
#endif
free(bar);
foo_len = strlenpt(foo);
start_x = (COLS - foo_len - 4) / 2;
wmove(bottomwin, 0, start_x);
wattron(bottomwin, A_REVERSE);
waddstr(bottomwin, "[ ");
waddstr(bottomwin, foo);
free(foo);
waddstr(bottomwin, " ]");
wattroff(bottomwin, A_REVERSE);
wnoutrefresh(bottomwin);
reset_cursor();
wrefresh(edit);
/* Leave the cursor at its position in the edit window, not
* in the statusbar. */
}
SET(DISABLE_CURPOS);
statusblank = 26;
}
void bottombars(const shortcut *s)
{
size_t i, colwidth, slen;
if (ISSET(NO_HELP))
return;
if (s == main_list) {
slen = MAIN_VISIBLE;
assert(slen <= length_of_list(s));
} else {
slen = length_of_list(s);
/* Don't show any more shortcuts than the main list does. */
if (slen > MAIN_VISIBLE)
slen = MAIN_VISIBLE;
}
/* There will be this many characters per column. We need at least
* 3 to display anything properly. */
colwidth = COLS / ((slen / 2) + (slen % 2));
blank_bottombars();
for (i = 0; i < slen; i++, s = s->next) {
const char *keystr;
char foo[4] = "";
/* Yucky sentinel values that we can't handle a better way. */
if (s->ctrlval == NANO_CONTROL_SPACE)
strcpy(foo, "^ ");
else if (s->ctrlval == NANO_CONTROL_8)
strcpy(foo, "^?");
/* Normal values. Assume that the shortcut has an equivalent
* control key, meta key sequence, or both. */
else if (s->ctrlval != NANO_NO_KEY)
sprintf(foo, "^%c", s->ctrlval + 64);
else if (s->metaval != NANO_NO_KEY)
sprintf(foo, "M-%c", toupper(s->metaval));
keystr = foo;
wmove(bottomwin, 1 + i % 2, (i / 2) * colwidth);
onekey(keystr, s->desc, colwidth);
}
wnoutrefresh(bottomwin);
reset_cursor();
wrefresh(edit);
}
/* Write a shortcut key to the help area at the bottom of the window.
* keystroke is e.g. "^G" and desc is e.g. "Get Help". We are careful
* to write at most len characters, even if len is very small and
* keystroke and desc are long. Note that waddnstr(,,(size_t)-1) adds
* the whole string! We do not bother padding the entry with blanks. */
void onekey(const char *keystroke, const char *desc, size_t len)
{
size_t keystroke_len = strlenpt(keystroke) + 1;
assert(keystroke != NULL && desc != NULL);
wattron(bottomwin, A_REVERSE);
waddnstr(bottomwin, keystroke, actual_x(keystroke, len));
wattroff(bottomwin, A_REVERSE);
if (len > keystroke_len)
len -= keystroke_len;
else
len = 0;
if (len > 0) {
waddch(bottomwin, ' ');
waddnstr(bottomwin, desc, actual_x(desc, len));
}
}
/* And so start the display update routines. */
#ifndef NDEBUG
int check_linenumbers(const filestruct *fileptr)
{
int check_line = 0;
const filestruct *filetmp;
for (filetmp = edittop; filetmp != fileptr; filetmp = filetmp->next)
check_line++;
return check_line;
}
#endif
/* nano scrolls horizontally within a line in chunks. This function
* returns the column number of the first character displayed in the
* window when the cursor is at the given column. Note that
* 0 <= column - get_page_start(column) < COLS. */
size_t get_page_start(size_t column)
{
assert(COLS > 0);
if (column == 0 || column < COLS - 1)
return 0;
else if (COLS > 9)
return column - 7 - (column - 7) % (COLS - 8);
else if (COLS > 2)
return column - (COLS - 2);
else
return column - (COLS - 1);
/* The parentheses are necessary to avoid overflow. */
}
/* Resets current_y, based on the position of current, and puts the
* cursor in the edit window at (current_y, current_x). */
void reset_cursor(void)
{
/* If we haven't opened any files yet, put the cursor in the top
* left corner of the edit window and get out. */
if (edittop == NULL || current == NULL) {
wmove(edit, 0, 0);
return;
}
current_y = current->lineno - edittop->lineno;
if (current_y < editwinrows) {
size_t x = xplustabs();
wmove(edit, current_y, x - get_page_start(x));
}
}
/* edit_add() takes care of the job of actually painting a line into the
* edit window. fileptr is the line to be painted, at row yval of the
* window. converted is the actual string to be written to the window,
* with tabs and control characters replaced by strings of regular
* characters. start is the column number of the first character of
* this page. That is, the first character of converted corresponds to
* character number actual_x(fileptr->data, start) of the line. */
void edit_add(const filestruct *fileptr, const char *converted, int
yval, size_t start)
{
#if !defined(NANO_SMALL) || defined(ENABLE_COLOR)
size_t startpos = actual_x(fileptr->data, start);
/* The position in fileptr->data of the leftmost character
* that displays at least partially on the window. */
size_t endpos = actual_x(fileptr->data, start + COLS - 1) + 1;
/* The position in fileptr->data of the first character that is
* completely off the window to the right.
*
* Note that endpos might be beyond the null terminator of the
* string. */
#endif
assert(fileptr != NULL && converted != NULL);
assert(strlenpt(converted) <= COLS);
/* Just paint the string in any case (we'll add color or reverse on
* just the text that needs it). */
mvwaddstr(edit, yval, 0, converted);
#ifdef ENABLE_COLOR
if (colorstrings != NULL && !ISSET(NO_COLOR_SYNTAX)) {
const colortype *tmpcolor = colorstrings;
for (; tmpcolor != NULL; tmpcolor = tmpcolor->next) {
int x_start;
/* Starting column for mvwaddnstr. Zero-based. */
int paintlen;
/* Number of chars to paint on this line. There are COLS
* characters on a whole line. */
size_t index;
/* Index in converted where we paint. */
regmatch_t startmatch; /* match position for start_regexp */
regmatch_t endmatch; /* match position for end_regexp */
if (tmpcolor->bright)
wattron(edit, A_BOLD);
wattron(edit, COLOR_PAIR(tmpcolor->pairnum));
/* Two notes about regexec(). Return value 0 means there is
* a match. Also, rm_eo is the first non-matching character
* after the match. */
/* First case, tmpcolor is a single-line expression. */
if (tmpcolor->end == NULL) {
size_t k = 0;
/* We increment k by rm_eo, to move past the end of the
* last match. Even though two matches may overlap, we
* want to ignore them, so that we can highlight
* C-strings correctly. */
while (k < endpos) {
/* Note the fifth parameter to regexec(). It says
* not to match the beginning-of-line character
* unless k is 0. If regexec() returns REG_NOMATCH,
* there are no more matches in the line. */
if (regexec(&tmpcolor->start, &fileptr->data[k], 1,
&startmatch, (k == 0) ? 0 :
REG_NOTBOL) == REG_NOMATCH)
break;
/* Translate the match to the beginning of the
* line. */
startmatch.rm_so += k;
startmatch.rm_eo += k;
if (startmatch.rm_so == startmatch.rm_eo) {
startmatch.rm_eo++;
statusbar(
_("Refusing zero-length regex match"));
} else if (startmatch.rm_so < endpos &&
startmatch.rm_eo > startpos) {
if (startmatch.rm_so <= startpos)
x_start = 0;
else
x_start = strnlenpt(fileptr->data,
startmatch.rm_so) - start;
index = actual_x(converted, x_start);
paintlen = actual_x(converted + index,
strnlenpt(fileptr->data,
startmatch.rm_eo) - start - x_start);
assert(0 <= x_start && 0 <= paintlen);
mvwaddnstr(edit, yval, x_start,
converted + index, paintlen);
}
k = startmatch.rm_eo;
}
} else {
/* This is a multi-line regexp. There are two steps.
* First, we have to see if the beginning of the line is
* colored by a start on an earlier line, and an end on
* this line or later.
*
* We find the first line before fileptr matching the
* start. If every match on that line is followed by an
* end, then go to step two. Otherwise, find the next
* line after start_line matching the end. If that line
* is not before fileptr, then paint the beginning of
* this line. */
const filestruct *start_line = fileptr->prev;
/* The first line before fileptr matching start. */
regoff_t start_col;
/* Where it starts in that line. */
const filestruct *end_line;
while (start_line != NULL &&
regexec(&tmpcolor->start, start_line->data, 1,
&startmatch, 0) == REG_NOMATCH) {
/* If there is an end on this line, there is no need
* to look for starts on earlier lines. */
if (regexec(tmpcolor->end, start_line->data, 0,
NULL, 0) == 0)
goto step_two;
start_line = start_line->prev;
}
/* No start found, so skip to the next step. */
if (start_line == NULL)
goto step_two;
/* Now start_line is the first line before fileptr
* containing a start match. Is there a start on this
* line not followed by an end on this line? */
start_col = 0;
while (TRUE) {
start_col += startmatch.rm_so;
startmatch.rm_eo -= startmatch.rm_so;
if (regexec(tmpcolor->end, start_line->data +
start_col + startmatch.rm_eo, 0, NULL,
(start_col + startmatch.rm_eo == 0) ? 0 :
REG_NOTBOL) == REG_NOMATCH)
/* No end found after this start. */
break;
start_col++;
if (regexec(&tmpcolor->start, start_line->data +
start_col, 1, &startmatch,
REG_NOTBOL) == REG_NOMATCH)
/* No later start on this line. */
goto step_two;
}
/* Indeed, there is a start not followed on this line by
* an end. */
/* We have already checked that there is no end before
* fileptr and after the start. Is there an end after
* the start at all? We don't paint unterminated
* starts. */
end_line = fileptr;
while (end_line != NULL &&
regexec(tmpcolor->end, end_line->data, 1,
&endmatch, 0) == REG_NOMATCH)
end_line = end_line->next;
/* No end found, or it is too early. */
if (end_line == NULL || (end_line == fileptr &&
endmatch.rm_eo <= startpos))
goto step_two;
/* Now paint the start of fileptr. */
if (end_line != fileptr)
/* If the start of fileptr is on a different line
* from the end, paintlen is -1, meaning that
* everything on the line gets painted. */
paintlen = -1;
else
/* Otherwise, paintlen is the expanded location of
* the end of the match minus the expanded location
* of the beginning of the page. */
paintlen = actual_x(converted,
strnlenpt(fileptr->data, endmatch.rm_eo) -
start);
mvwaddnstr(edit, yval, 0, converted, paintlen);
step_two:
/* Second step, we look for starts on this line. */
start_col = 0;
while (start_col < endpos) {
if (regexec(&tmpcolor->start,
fileptr->data + start_col, 1, &startmatch,
(start_col == 0) ? 0 :
REG_NOTBOL) == REG_NOMATCH ||
start_col + startmatch.rm_so >= endpos)
/* No more starts on this line. */
break;
/* Translate the match to be relative to the
* beginning of the line. */
startmatch.rm_so += start_col;
startmatch.rm_eo += start_col;
if (startmatch.rm_so <= startpos)
x_start = 0;
else
x_start = strnlenpt(fileptr->data,
startmatch.rm_so) - start;
index = actual_x(converted, x_start);
if (regexec(tmpcolor->end,
fileptr->data + startmatch.rm_eo, 1, &endmatch,
(startmatch.rm_eo == 0) ? 0 :
REG_NOTBOL) == 0) {
/* Translate the end match to be relative to the
* beginning of the line. */
endmatch.rm_so += startmatch.rm_eo;
endmatch.rm_eo += startmatch.rm_eo;
/* There is an end on this line. But does it
* appear on this page, and is the match more
* than zero characters long? */
if (endmatch.rm_eo > startpos &&
endmatch.rm_eo > startmatch.rm_so) {
paintlen = actual_x(converted + index,
strnlenpt(fileptr->data,
endmatch.rm_eo) - start - x_start);
assert(0 <= x_start && x_start < COLS);
mvwaddnstr(edit, yval, x_start,
converted + index, paintlen);
}
} else {
/* There is no end on this line. But we haven't
* yet looked for one on later lines. */
end_line = fileptr->next;
while (end_line != NULL &&
regexec(tmpcolor->end, end_line->data,
0, NULL, 0) == REG_NOMATCH)
end_line = end_line->next;
if (end_line != NULL) {
assert(0 <= x_start && x_start < COLS);
mvwaddnstr(edit, yval, x_start,
converted + index, -1);
/* We painted to the end of the line, so
* don't bother checking any more starts. */
break;
}
}
start_col = startmatch.rm_so + 1;
}
}
wattroff(edit, A_BOLD);
wattroff(edit, COLOR_PAIR(tmpcolor->pairnum));
}
}
#endif /* ENABLE_COLOR */
#ifndef NANO_SMALL
if (ISSET(MARK_ISSET)
&& (fileptr->lineno <= mark_beginbuf->lineno
|| fileptr->lineno <= current->lineno)
&& (fileptr->lineno >= mark_beginbuf->lineno
|| fileptr->lineno >= current->lineno)) {
/* fileptr is at least partially selected. */
const filestruct *top;
/* Either current or mark_beginbuf, whichever is first. */
size_t top_x;
/* current_x or mark_beginx, corresponding to top. */
const filestruct *bot;
size_t bot_x;
int x_start;
/* Starting column for mvwaddnstr. Zero-based. */
int paintlen;
/* Number of chars to paint on this line. There are COLS
* characters on a whole line. */
size_t index;
/* Index in converted where we paint. */
mark_order(&top, &top_x, &bot, &bot_x, NULL);
if (top->lineno < fileptr->lineno || top_x < startpos)
top_x = startpos;
if (bot->lineno > fileptr->lineno || bot_x > endpos)
bot_x = endpos;
/* The selected bit of fileptr is on this page. */
if (top_x < endpos && bot_x > startpos) {
assert(startpos <= top_x);
/* x_start is the expanded location of the beginning of the
* mark minus the beginning of the page. */
x_start = strnlenpt(fileptr->data, top_x) - start;
if (bot_x >= endpos)
/* If the end of the mark is off the page, paintlen is
* -1, meaning that everything on the line gets
* painted. */
paintlen = -1;
else
/* Otherwise, paintlen is the expanded location of the
* end of the mark minus the expanded location of the
* beginning of the mark. */
paintlen = strnlenpt(fileptr->data, bot_x) -
(x_start + start);
/* If x_start is before the beginning of the page, shift
* paintlen x_start characters to compensate, and put
* x_start at the beginning of the page. */
if (x_start < 0) {
paintlen += x_start;
x_start = 0;
}
assert(x_start >= 0 && x_start <= strlen(converted));
index = actual_x(converted, x_start);
if (paintlen > 0)
paintlen = actual_x(converted + index, paintlen);
wattron(edit, A_REVERSE);
mvwaddnstr(edit, yval, x_start, converted + index,
paintlen);
wattroff(edit, A_REVERSE);
}
}
#endif /* !NANO_SMALL */
}
/* Just update one line in the edit buffer. This is basically a wrapper
* for edit_add().
*
* If fileptr != current, then index is considered 0. The line will be
* displayed starting with fileptr->data[index]. Likely args are
* current_x or 0. */
void update_line(const filestruct *fileptr, size_t index)
{
int line;
/* The line in the edit window that we want to update. */
char *converted;
/* fileptr->data converted to have tabs and control characters
* expanded. */
size_t page_start;
assert(fileptr != NULL);
line = fileptr->lineno - edittop->lineno;
/* We assume the line numbers are valid. Is that really true? */
assert(line < 0 || line == check_linenumbers(fileptr));
if (line < 0 || line >= editwinrows)
return;
/* First, blank out the line. */
mvwaddstr(edit, line, 0, hblank);
/* Next, convert variables that index the line to their equivalent
* positions in the expanded line. */
index = (fileptr == current) ? strnlenpt(fileptr->data, index) : 0;
page_start = get_page_start(index);
/* Expand the line, replacing tabs with spaces, and control
* characters with their displayed forms. */
converted = display_string(fileptr->data, page_start, COLS, TRUE);
/* Paint the line. */
edit_add(fileptr, converted, line, page_start);
free(converted);
if (page_start > 0)
mvwaddch(edit, line, 0, '$');
if (strlenpt(fileptr->data) > page_start + COLS)
mvwaddch(edit, line, COLS - 1, '$');
}
/* Return a nonzero value if we need an update after moving
* horizontally. We need one if the mark is on or if old_pww and
* placewewant are on different pages. */
int need_horizontal_update(size_t old_pww)
{
return
#ifndef NANO_SMALL
ISSET(MARK_ISSET) ||
#endif
get_page_start(old_pww) != get_page_start(placewewant);
}
/* Return a nonzero value if we need an update after moving vertically.
* We need one if the mark is on or if old_pww and placewewant
* are on different pages. */
int need_vertical_update(size_t old_pww)
{
return
#ifndef NANO_SMALL
ISSET(MARK_ISSET) ||
#endif
get_page_start(old_pww) != get_page_start(placewewant);
}
/* Scroll the edit window in the given direction and the given number
* of lines, and draw new lines on the blank lines left after the
* scrolling. direction is the direction to scroll, either UP or DOWN,
* and nlines is the number of lines to scroll. Don't redraw the old
* topmost or bottommost line (where we assume current is) before
* scrolling or draw the new topmost or bottommost line after scrolling
* (where we assume current will be), since we don't know where we are
* on the page or whether we'll stay there. */
void edit_scroll(updown direction, int nlines)
{
filestruct *foo;
int i, scroll_rows = 0;
/* Scrolling less than one line or more than editwinrows lines is
* redundant, so don't allow it. */
if (nlines < 1 || nlines > editwinrows)
return;
/* Move the top line of the edit window up or down (depending on the
* value of direction) nlines lines. If there are fewer lines of
* text than that left, move it to the top or bottom line of the
* file (depending on the value of direction). Keep track of
* how many lines we moved in scroll_rows. */
for (i = nlines; i > 0; i--) {
if (direction == UP) {
if (edittop->prev == NULL)
break;
edittop = edittop->prev;
scroll_rows--;
} else {
if (edittop->next == NULL)
break;
edittop = edittop->next;
scroll_rows++;
}
}
/* Scroll the text on the screen up or down scroll_rows lines,
* depending on the value of direction. */
scrollok(edit, TRUE);
wscrl(edit, scroll_rows);
scrollok(edit, FALSE);
foo = edittop;
if (direction != UP) {
int slines = editwinrows - nlines;
for (; slines > 0 && foo != NULL; slines--)
foo = foo->next;
}
/* And draw new lines on the blank top or bottom lines of the edit
* window, depending on the value of direction. Don't draw the new
* topmost or new bottommost line. */
while (scroll_rows != 0 && foo != NULL) {
if (foo->next != NULL)
update_line(foo, 0);
if (direction == UP)
scroll_rows++;
else
scroll_rows--;
foo = foo->next;
}
}
/* Update any lines between old_current and current that need to be
* updated. */
void edit_redraw(const filestruct *old_current, size_t old_pww)
{
int do_refresh = need_vertical_update(0) ||
need_vertical_update(old_pww);
const filestruct *foo;
/* If either old_current or current is offscreen, refresh the screen
* and get out. */
if (old_current->lineno < edittop->lineno || old_current->lineno >=
edittop->lineno + editwinrows || current->lineno <
edittop->lineno || current->lineno >= edittop->lineno +
editwinrows) {
edit_refresh();
return;
}
/* Update old_current and current if we're not on the first page
* and/or we're not on the same page as before. If the mark is on,
* update all the lines between old_current and current too. */
foo = old_current;
while (foo != current) {
if (do_refresh)
update_line(foo, 0);
#ifndef NANO_SMALL
if (!ISSET(MARK_ISSET))
#endif
break;
if (foo->lineno > current->lineno)
foo = foo->prev;
else
foo = foo->next;
}
if (do_refresh)
update_line(current, current_x);
}
/* Refresh the screen without changing the position of lines. */
void edit_refresh(void)
{
if (current->lineno < edittop->lineno ||
current->lineno >= edittop->lineno + editwinrows)
/* Note that edit_update() changes edittop so that it's in range
* of current. Thus, when it then calls edit_refresh(), there
* is no danger of getting an infinite loop. */
edit_update(
#ifndef NANO_SMALL
ISSET(SMOOTHSCROLL) ? NONE :
#endif
CENTER);
else {
int nlines = 0;
const filestruct *foo = edittop;
#ifdef DEBUG
fprintf(stderr, "edit_refresh(): edittop->lineno = %d\n", edittop->lineno);
#endif
while (nlines < editwinrows) {
update_line(foo, foo == current ? current_x : 0);
nlines++;
if (foo->next == NULL)
break;
foo = foo->next;
}
while (nlines < editwinrows) {
mvwaddstr(edit, nlines, 0, hblank);
nlines++;
}
reset_cursor();
wrefresh(edit);
}
}
/* A nice generic routine to update the edit buffer. We keep current in
* the same place and move edittop to put it in range of current. */
void edit_update(topmidnone location)
{
filestruct *foo = current;
if (location != TOP) {
/* If location is CENTER, we move edittop up (editwinrows / 2)
* lines. This puts current at the center of the screen. If
* location is NONE, we move edittop up current_y lines if
* current_y is in range of the screen, 0 lines if current_y is
* less than 0, or (editwinrows - 1) lines if current_y is
* greater than (editwinrows - 1). This puts current at the
* same place on the screen as before, or at the top or bottom
* of the screen if edittop is beyond either. */
int goal;
if (location == CENTER)
goal = editwinrows / 2;
else {
goal = current_y;
/* Limit goal to (editwinrows - 1) lines maximum. */
if (goal > editwinrows - 1)
goal = editwinrows - 1;
}
for (; goal > 0 && foo->prev != NULL; goal--)
foo = foo->prev;
}
edittop = foo;
edit_refresh();
}
/* Ask a simple yes/no question, specified in msg, on the statusbar.
* Return 1 for Y, 0 for N, 2 for All (if all is TRUE when passed in)
* and -1 for abort (^C). */
int do_yesno(bool all, const char *msg)
{
int ok = -2, width = 16;
const char *yesstr; /* String of yes characters accepted. */
const char *nostr; /* Same for no. */
const char *allstr; /* And all, surprise! */
/* yesstr, nostr, and allstr are strings of any length. Each string
* consists of all single-byte characters accepted as valid
* characters for that value. The first value will be the one
* displayed in the shortcuts. Translators: if possible, specify
* both the shortcuts for your language and English. For example,
* in French: "OoYy" for "Oui". */
yesstr = _("Yy");
nostr = _("Nn");
allstr = _("Aa");
if (!ISSET(NO_HELP)) {
char shortstr[3]; /* Temp string for Y, N, A. */
if (COLS < 32)
width = COLS / 2;
/* Write the bottom of the screen. */
blank_bottombars();
sprintf(shortstr, " %c", yesstr[0]);
wmove(bottomwin, 1, 0);
onekey(shortstr, _("Yes"), width);
if (all) {
wmove(bottomwin, 1, width);
shortstr[1] = allstr[0];
onekey(shortstr, _("All"), width);
}
wmove(bottomwin, 2, 0);
shortstr[1] = nostr[0];
onekey(shortstr, _("No"), width);
wmove(bottomwin, 2, 16);
onekey("^C", _("Cancel"), width);
}
wattron(bottomwin, A_REVERSE);
blank_statusbar();
mvwaddnstr(bottomwin, 0, 0, msg, COLS - 1);
wattroff(bottomwin, A_REVERSE);
wrefresh(bottomwin);
do {
int kbinput;
bool meta_key, func_key;
#ifndef DISABLE_MOUSE
int mouse_x, mouse_y;
#endif
kbinput = get_kbinput(edit, &meta_key, &func_key);
if (kbinput == NANO_CANCEL_KEY)
ok = -1;
#ifndef DISABLE_MOUSE
else if (kbinput == KEY_MOUSE) {
get_mouseinput(&mouse_x, &mouse_y, FALSE);
if (mouse_x != -1 && mouse_y != -1 && !ISSET(NO_HELP) &&
wenclose(bottomwin, mouse_y, mouse_x) &&
mouse_x < (width * 2) && mouse_y >= editwinrows + 3) {
int x = mouse_x / width;
/* Did we click in the first column of shortcuts, or
* the second? */
int y = mouse_y - editwinrows - 3;
/* Did we click in the first row of shortcuts? */
assert(0 <= x && x <= 1 && 0 <= y && y <= 1);
/* x = 0 means they clicked Yes or No.
* y = 0 means Yes or All. */
ok = -2 * x * y + x - y + 1;
if (ok == 2 && !all)
ok = -2;
}
}
#endif
/* Look for the kbinput in the yes, no and (optionally) all
* strings. */
else if (strchr(yesstr, kbinput) != NULL)
ok = 1;
else if (strchr(nostr, kbinput) != NULL)
ok = 0;
else if (all && strchr(allstr, kbinput) != NULL)
ok = 2;
} while (ok == -2);
return ok;
}
void total_update(void)
{
clearok(edit, TRUE);
wrefresh(edit);
}
void total_refresh(void)
{
total_update();
titlebar(NULL);
edit_refresh();
bottombars(currshortcut);
}
void display_main_list(void)
{
bottombars(main_list);
}
/* If constant is FALSE, the user typed Ctrl-C, so we unconditionally
* display the cursor position. Otherwise, we display it only if the
* character position changed and DISABLE_CURPOS is not set.
*
* If constant is TRUE and DISABLE_CURPOS is set, we unset it and update
* old_i and old_totsize. That way, we leave the current statusbar
* alone, but next time we will display. */
void do_cursorpos(bool constant)
{
char c;
filestruct *f;
size_t i = 0;
static size_t old_i = 0, old_totsize = (size_t)-1;
assert(current != NULL && fileage != NULL && totlines != 0);
if (old_totsize == (size_t)-1)
old_totsize = totsize;
c = current->data[current_x];
f = current->next;
current->data[current_x] = '\0';
current->next = NULL;
get_totals(fileage, current, NULL, &i);
current->data[current_x] = c;
current->next = f;
/* Check whether totsize is correct. Else there is a bug
* somewhere. */
assert(current != filebot || i == totsize);
if (constant && ISSET(DISABLE_CURPOS)) {
UNSET(DISABLE_CURPOS);
old_i = i;
old_totsize = totsize;
return;
}
/* If constant is FALSE, display the position on the statusbar
* unconditionally; otherwise, only display the position when the
* character values have changed. */
if (!constant || old_i != i || old_totsize != totsize) {
size_t xpt = xplustabs() + 1;
size_t cur_len = strlenpt(current->data) + 1;
int linepct = 100 * current->lineno / totlines;
int colpct = 100 * xpt / cur_len;
int bytepct = (totsize == 0) ? 0 : 100 * i / totsize;
statusbar(
_("line %ld/%ld (%d%%), col %lu/%lu (%d%%), char %lu/%ld (%d%%)"),
current->lineno, totlines, linepct,
(unsigned long)xpt, (unsigned long)cur_len, colpct,
(unsigned long)i, (unsigned long)totsize, bytepct);
UNSET(DISABLE_CURPOS);
}
old_i = i;
old_totsize = totsize;
}
void do_cursorpos_void(void)
{
do_cursorpos(FALSE);
}
#ifndef DISABLE_HELP
/* Calculate the next line of help_text, starting at ptr. */
size_t help_line_len(const char *ptr)
{
int help_cols = (COLS > 24) ? COLS - 8 : 24;
/* Try to break the line at (COLS - 8) columns if we have more than
* 24 columns, and at 24 columns otherwise. */
size_t retval = break_line(ptr, help_cols, TRUE);
size_t retval_save = retval;
/* Get the length of the entire line up to a null or a newline. */
while (*(ptr + retval) != '\0' && *(ptr + retval) != '\n')
retval += move_mbright(ptr + retval, 0);
/* If the entire line doesn't go more than 8 columns beyond where we
* tried to break it, we should display it as-is. Otherwise, we
* should display it only up to the break. */
if (strnlenpt(ptr, retval) > help_cols + 8)
retval = retval_save;
return retval;
}
/* Our dynamic, shortcut-list-compliant help function. */
void do_help(void)
{
int line = 0;
/* The line number in help_text of the first displayed help
* line. This variable is zero-based. */
bool no_more = FALSE;
/* no_more means the end of the help text is shown, so don't go
* down any more. */
int kbinput = ERR;
bool meta_key, func_key;
bool old_no_help = ISSET(NO_HELP);
#ifndef DISABLE_MOUSE
const shortcut *oldshortcut = currshortcut;
/* We will set currshortcut to allow clicking on the help
* screen's shortcut list. */
#endif
curs_set(0);
blank_edit();
wattroff(bottomwin, A_REVERSE);
blank_statusbar();
/* Set help_text as the string to display. */
help_init();
assert(help_text != NULL);
#ifndef DISABLE_MOUSE
/* Set currshortcut to allow clicking on the help screen's shortcut
* list, AFTER help_init(). */
currshortcut = help_list;
#endif
if (ISSET(NO_HELP)) {
/* Make sure that the help screen's shortcut list will actually
* be displayed. */
UNSET(NO_HELP);
window_init();
}
bottombars(help_list);
do {
int i;
int old_line = line;
/* We redisplay the help only if it moved. */
const char *ptr = help_text;
switch (kbinput) {
#ifndef DISABLE_MOUSE
case KEY_MOUSE:
{
int mouse_x, mouse_y;
get_mouseinput(&mouse_x, &mouse_y, TRUE);
}
break;
#endif
case NANO_PREVPAGE_KEY:
case NANO_PREVPAGE_FKEY:
if (line > 0) {
line -= editwinrows - 2;
if (line < 0)
line = 0;
}
break;
case NANO_NEXTPAGE_KEY:
case NANO_NEXTPAGE_FKEY:
if (!no_more)
line += editwinrows - 2;
break;
case NANO_PREVLINE_KEY:
if (line > 0)
line--;
break;
case NANO_NEXTLINE_KEY:
if (!no_more)
line++;
break;
}
if (kbinput == NANO_REFRESH_KEY)
total_update();
else {
if (line == old_line && kbinput != ERR)
goto skip_redisplay;
blank_edit();
}
/* Calculate where in the text we should be, based on the
* page. */
for (i = 0; i < line; i++) {
ptr += help_line_len(ptr);
if (*ptr == '\n')
ptr++;
}
for (i = 0; i < editwinrows && *ptr != '\0'; i++) {
size_t j = help_line_len(ptr);
mvwaddnstr(edit, i, 0, ptr, j);
ptr += j;
if (*ptr == '\n')
ptr++;
}
no_more = (*ptr == '\0');
skip_redisplay:
kbinput = get_kbinput(edit, &meta_key, &func_key);
} while (kbinput != NANO_EXIT_KEY && kbinput != NANO_EXIT_FKEY);
#ifndef DISABLE_MOUSE
currshortcut = oldshortcut;
#endif
if (old_no_help) {
blank_bottombars();
wrefresh(bottomwin);
SET(NO_HELP);
window_init();
} else
bottombars(currshortcut);
curs_set(1);
edit_refresh();
/* The help_init() at the beginning allocated help_text. Since
* help_text has now been written to the screen, we don't need it
* anymore. */
free(help_text);
help_text = NULL;
}
#endif /* !DISABLE_HELP */
/* Highlight the current word being replaced or spell checked. We
* expect word to have tabs and control characters expanded. */
void do_replace_highlight(bool highlight_flag, const char *word)
{
size_t y = xplustabs();
size_t word_len = strlenpt(word);
y = get_page_start(y) + COLS - y;
/* Now y is the number of columns that we can display on this
* line. */
assert(y > 0);
if (word_len > y)
y--;
reset_cursor();
if (highlight_flag)
wattron(edit, A_REVERSE);
#ifdef HAVE_REGEX_H
/* This is so we can show zero-length regexes. */
if (word_len == 0)
waddstr(edit, " ");
else
#endif
waddnstr(edit, word, actual_x(word, y));
if (word_len > y)
waddch(edit, '$');
if (highlight_flag)
wattroff(edit, A_REVERSE);
}
#ifdef DEBUG
/* Dump the passed-in file structure to stderr. */
void dump_buffer(const filestruct *inptr)
{
if (inptr == fileage)
fprintf(stderr, "Dumping file buffer to stderr...\n");
else if (inptr == cutbuffer)
fprintf(stderr, "Dumping cutbuffer to stderr...\n");
else
fprintf(stderr, "Dumping a buffer to stderr...\n");
while (inptr != NULL) {
fprintf(stderr, "(%d) %s\n", inptr->lineno, inptr->data);
inptr = inptr->next;
}
}
/* Dump the file structure to stderr in reverse. */
void dump_buffer_reverse(void)
{
const filestruct *fileptr = filebot;
while (fileptr != NULL) {
fprintf(stderr, "(%d) %s\n", fileptr->lineno, fileptr->data);
fileptr = fileptr->prev;
}
}
#endif /* DEBUG */
#ifdef NANO_EXTRA
#define CREDIT_LEN 53
#define XLCREDIT_LEN 8
/* Easter egg: Display credits. Assume nodelay(edit) is FALSE. */
void do_credits(void)
{
int crpos = 0, xlpos = 0;
const char *credits[CREDIT_LEN] = {
NULL, /* "The nano text editor" */
NULL, /* "version" */
VERSION,
"",
NULL, /* "Brought to you by:" */
"Chris Allegretta",
"Jordi Mallach",
"Adam Rogoyski",
"Rob Siemborski",
"Rocco Corsi",
"David Lawrence Ramsey",
"David Benbennick",
"Ken Tyler",
"Sven Guckes",
"Florian K<>nig",
"Pauli Virtanen",
"Daniele Medri",
"Clement Laforet",
"Tedi Heriyanto",
"Bill Soudan",
"Christian Weisgerber",
"Erik Andersen",
"Big Gaute",
"Joshua Jensen",
"Ryan Krebs",
"Albert Chin",
"",
NULL, /* "Special thanks to:" */
"Plattsburgh State University",
"Benet Laboratories",
"Amy Allegretta",
"Linda Young",
"Jeremy Robichaud",
"Richard Kolb II",
NULL, /* "The Free Software Foundation" */
"Linus Torvalds",
NULL, /* "For ncurses:" */
"Thomas Dickey",
"Pavel Curtis",
"Zeyd Ben-Halim",
"Eric S. Raymond",
NULL, /* "and anyone else we forgot..." */
NULL, /* "Thank you for using nano!" */
"",
"",
"",
"",
"(c) 1999-2005 Chris Allegretta",
"",
"",
"",
"",
"http://www.nano-editor.org/"
};
const char *xlcredits[XLCREDIT_LEN] = {
N_("The nano text editor"),
N_("version"),
N_("Brought to you by:"),
N_("Special thanks to:"),
N_("The Free Software Foundation"),
N_("For ncurses:"),
N_("and anyone else we forgot..."),
N_("Thank you for using nano!")
};
curs_set(0);
nodelay(edit, TRUE);
scrollok(edit, TRUE);
blank_titlebar();
blank_topbar();
blank_edit();
blank_statusbar();
blank_bottombars();
wrefresh(topwin);
wrefresh(edit);
wrefresh(bottomwin);
for (crpos = 0; crpos < CREDIT_LEN + editwinrows / 2; crpos++) {
if (wgetch(edit) != ERR)
break;
if (crpos < CREDIT_LEN) {
char *what;
size_t start_x;
/* Make sure every credit is a valid multibyte string, since
* we can't dynamically set the credits to their multibyte
* equivalents when we need to. Sigh... */
if (credits[crpos] == NULL) {
assert(0 <= xlpos && xlpos < XLCREDIT_LEN);
what = mallocstrcpy(NULL, _(xlcredits[xlpos]));
xlpos++;
} else
what = make_mbstring(credits[crpos]);
start_x = COLS / 2 - strlenpt(what) / 2 - 1;
mvwaddstr(edit, editwinrows - 1 - (editwinrows % 2),
start_x, what);
free(what);
}
napms(700);
scroll(edit);
wrefresh(edit);
if (wgetch(edit) != ERR)
break;
napms(700);
scroll(edit);
wrefresh(edit);
}
scrollok(edit, FALSE);
nodelay(edit, FALSE);
curs_set(1);
total_refresh();
}
#endif