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bdd478bbd0
fish-shell/src/input_common.rs
Johannes Altmanninger bdd478bbd0 Disable focus reporting on non-tmux again for now 
We sometimes leak ^[[I and ^[[O focus reporting events when run from VSCode's
"Run python file" button in the top right corner. To reproduce I installed
the ms-python extension set the VSCode default shell to fish and repeatedly
ran a script that does "time.sleep(1)". I believe VSCode synthesizes keys
and triggers a race condition.

We can probably fix this but I'm not sure when I'll get to it (given how
relatively unimportant this feature is).

So let's go back to the old behavior of only enabling focus reporting in tmux.

I believe that tmux is affected by the same VSCode issue (also on 3.7.1 I
think) but I haven't been able to get tmux to emit focus reporting sequences
yet.  Still, keep it to not regress cursor shape (#4788).  So far this is
the only motivation for focus reporting and I believe it is only relevant
for terminals that can split windows (though there are a bunch that do).

Closes #10448
2024-04-18 10:38:15 +02:00

1229 lines
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use libc::STDOUT_FILENO;
use crate::common::{
fish_reserved_codepoint, is_windows_subsystem_for_linux, read_blocked, shell_modes, ScopeGuard,
ScopeGuarding,
};
use crate::env::{EnvStack, Environment};
use crate::fd_readable_set::FdReadableSet;
use crate::flog::FLOG;
use crate::global_safety::RelaxedAtomicBool;
use crate::input::KeyNameStyle;
use crate::key::{
self, alt, canonicalize_control_char, canonicalize_keyed_control_char, function_key, shift,
Key, Modifiers,
};
use crate::reader::{reader_current_data, reader_test_and_clear_interrupted};
use crate::threads::{iothread_port, iothread_service_main, MainThread};
use crate::universal_notifier::default_notifier;
use crate::wchar::{encode_byte_to_char, prelude::*};
use crate::wutil::encoding::{mbrtowc, mbstate_t, zero_mbstate};
use crate::wutil::{fish_wcstol, write_to_fd};
use std::cell::RefCell;
use std::collections::VecDeque;
use std::os::fd::RawFd;
use std::ptr;
use std::sync::atomic::{AtomicUsize, Ordering};
// The range of key codes for inputrc-style keyboard functions.
pub const R_END_INPUT_FUNCTIONS: usize = (ReadlineCmd::ReverseRepeatJump as usize) + 1;
/// Hackish: the input style, which describes how char events (only) are applied to the command
/// line. Note this is set only after applying bindings; it is not set from readb().
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub enum CharInputStyle {
// Insert characters normally.
Normal,
// Insert characters only if the cursor is not at the beginning. Otherwise, discard them.
NotFirst,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[repr(u8)]
pub enum ReadlineCmd {
BeginningOfLine,
EndOfLine,
ForwardChar,
BackwardChar,
BackwardCharPassive,
ForwardSingleChar,
ForwardCharPassive,
ForwardWord,
BackwardWord,
ForwardBigword,
BackwardBigword,
NextdOrForwardWord,
PrevdOrBackwardWord,
HistorySearchBackward,
HistorySearchForward,
HistoryPrefixSearchBackward,
HistoryPrefixSearchForward,
HistoryPager,
HistoryPagerDelete,
DeleteChar,
BackwardDeleteChar,
KillLine,
Yank,
YankPop,
Complete,
CompleteAndSearch,
PagerToggleSearch,
BeginningOfHistory,
EndOfHistory,
BackwardKillLine,
KillWholeLine,
KillInnerLine,
KillWord,
KillBigword,
BackwardKillWord,
BackwardKillPathComponent,
BackwardKillBigword,
HistoryTokenSearchBackward,
HistoryTokenSearchForward,
SelfInsert,
SelfInsertNotFirst,
TransposeChars,
TransposeWords,
UpcaseWord,
DowncaseWord,
CapitalizeWord,
TogglecaseChar,
TogglecaseSelection,
Execute,
BeginningOfBuffer,
EndOfBuffer,
RepaintMode,
Repaint,
ForceRepaint,
UpLine,
DownLine,
SuppressAutosuggestion,
AcceptAutosuggestion,
BeginSelection,
SwapSelectionStartStop,
EndSelection,
KillSelection,
InsertLineUnder,
InsertLineOver,
ForwardJump,
BackwardJump,
ForwardJumpTill,
BackwardJumpTill,
FuncAnd,
FuncOr,
ExpandAbbr,
ExpandAbbrBacktrack,
DeleteOrExit,
Exit,
CancelCommandline,
Cancel,
Undo,
Redo,
BeginUndoGroup,
EndUndoGroup,
RepeatJump,
DisableMouseTracking,
FocusIn,
FocusOut,
// ncurses uses the obvious name
ClearScreenAndRepaint,
// NOTE: This one has to be last.
ReverseRepeatJump,
}
/// Represents an event on the character input stream.
#[derive(Debug, Clone)]
pub enum CharEventType {
/// A character was entered.
Char(Key),
/// A readline event.
Readline(ReadlineCmd),
/// A shell command.
Command(WString),
/// end-of-file was reached.
Eof,
/// An event was handled internally, or an interrupt was received. Check to see if the reader
/// loop should exit.
CheckExit,
}
#[derive(Debug, Clone)]
pub struct ReadlineCmdEvent {
pub cmd: ReadlineCmd,
/// The sequence of characters in the input mapping which generated this event.
/// Note that the generic self-insert case does not have any characters, so this would be empty.
/// This is also empty for invalid Unicode code points, which produce multiple characters.
pub seq: WString,
}
#[derive(Debug, Clone)]
pub struct KeyEvent {
// The key.
pub key: Key,
// The style to use when inserting characters into the command line.
pub input_style: CharInputStyle,
/// The sequence of characters in the input mapping which generated this event.
/// Note that the generic self-insert case does not have any characters, so this would be empty.
/// This is also empty for invalid Unicode code points, which produce multiple characters.
pub seq: WString,
}
#[derive(Debug, Clone)]
pub enum CharEvent {
/// A character was entered.
Key(KeyEvent),
/// A readline event.
Readline(ReadlineCmdEvent),
/// A shell command.
Command(WString),
/// end-of-file was reached.
Eof,
/// An event was handled internally, or an interrupt was received. Check to see if the reader
/// loop should exit.
CheckExit,
}
impl CharEvent {
pub fn is_char(&self) -> bool {
matches!(self, CharEvent::Key(_))
}
pub fn is_eof(&self) -> bool {
matches!(self, CharEvent::Eof)
}
pub fn is_check_exit(&self) -> bool {
matches!(self, CharEvent::CheckExit)
}
pub fn is_readline(&self) -> bool {
matches!(self, CharEvent::Readline(_))
}
pub fn is_readline_or_command(&self) -> bool {
matches!(self, CharEvent::Readline(_) | CharEvent::Command(_))
}
pub fn get_char(&self) -> char {
let CharEvent::Key(kevt) = self else {
panic!("Not a char type");
};
kevt.key.codepoint
}
pub fn get_key(&self) -> Option<&KeyEvent> {
match self {
CharEvent::Key(kevt) => Some(kevt),
_ => None,
}
}
pub fn get_readline(&self) -> ReadlineCmd {
let CharEvent::Readline(c) = self else {
panic!("Not a readline type");
};
c.cmd
}
pub fn get_command(&self) -> Option<&wstr> {
match self {
CharEvent::Command(c) => Some(c),
_ => None,
}
}
pub fn from_char(c: char) -> CharEvent {
Self::from_key(Key::from_raw(c))
}
pub fn from_key(key: Key) -> CharEvent {
Self::from_key_seq(key, WString::new())
}
pub fn from_key_seq(key: Key, seq: WString) -> CharEvent {
CharEvent::Key(KeyEvent {
key,
input_style: CharInputStyle::Normal,
seq,
})
}
pub fn from_char_seq(c: char, seq: WString) -> CharEvent {
CharEvent::Key(KeyEvent {
key: Key::from_raw(c),
input_style: CharInputStyle::Normal,
seq,
})
}
pub fn from_readline(cmd: ReadlineCmd) -> CharEvent {
Self::from_readline_seq(cmd, WString::new())
}
pub fn from_readline_seq(cmd: ReadlineCmd, seq: WString) -> CharEvent {
CharEvent::Readline(ReadlineCmdEvent { cmd, seq })
}
pub fn from_check_exit() -> CharEvent {
CharEvent::CheckExit
}
}
/// Time in milliseconds to wait for another byte to be available for reading
/// after \x1B is read before assuming that escape key was pressed, and not an
/// escape sequence.
pub(crate) static WAIT_ON_ESCAPE_MS: AtomicUsize = AtomicUsize::new(0);
const WAIT_ON_SEQUENCE_KEY_INFINITE: usize = usize::MAX;
static WAIT_ON_SEQUENCE_KEY_MS: AtomicUsize = AtomicUsize::new(WAIT_ON_SEQUENCE_KEY_INFINITE);
/// Internal function used by readch to read one byte.
/// This calls select() on three fds: input (e.g. stdin), the ioport notifier fd (for main thread
/// requests), and the uvar notifier. This returns either the byte which was read, or one of the
/// special values below.
enum ReadbResult {
// A byte was successfully read.
Byte(u8),
// The in fd has been closed.
Eof,
// select() was interrupted by a signal.
Interrupted,
// Our uvar notifier reported a change (either through poll() or its fd).
UvarNotified,
// Our ioport reported a change, so service main thread requests.
IOPortNotified,
NothingToRead,
}
fn readb(in_fd: RawFd, blocking: bool) -> ReadbResult {
assert!(in_fd >= 0, "Invalid in fd");
let mut fdset = FdReadableSet::new();
loop {
fdset.clear();
fdset.add(in_fd);
// Add the completion ioport.
let ioport_fd = iothread_port();
fdset.add(ioport_fd);
// Get the uvar notifier fd (possibly none).
let notifier = default_notifier();
let notifier_fd = notifier.notification_fd();
if let Some(notifier_fd) = notifier.notification_fd() {
fdset.add(notifier_fd);
}
// Here's where we call select().
let select_res = fdset.check_readable(if blocking {
FdReadableSet::kNoTimeout
} else {
0
});
if select_res < 0 {
let err = errno::errno().0;
if err == libc::EINTR || err == libc::EAGAIN {
// A signal.
return ReadbResult::Interrupted;
} else {
// Some fd was invalid, so probably the tty has been closed.
return ReadbResult::Eof;
}
}
if blocking {
// select() did not return an error, so we may have a readable fd.
// The priority order is: uvars, stdin, ioport.
// Check to see if we want a universal variable barrier.
if let Some(notifier_fd) = notifier_fd {
if fdset.test(notifier_fd) && notifier.notification_fd_became_readable(notifier_fd)
{
return ReadbResult::UvarNotified;
}
}
}
// Check stdin.
if fdset.test(in_fd) {
let mut arr: [u8; 1] = [0];
if read_blocked(in_fd, &mut arr) != Ok(1) {
// The terminal has been closed.
return ReadbResult::Eof;
}
// The common path is to return a u8.
return ReadbResult::Byte(arr[0]);
}
if !blocking {
return ReadbResult::NothingToRead;
}
// Check for iothread completions only if there is no data to be read from the stdin.
// This gives priority to the foreground.
if fdset.test(ioport_fd) {
return ReadbResult::IOPortNotified;
}
}
}
// Update the wait_on_escape_ms value in response to the fish_escape_delay_ms user variable being
// set.
pub fn update_wait_on_escape_ms(vars: &EnvStack) {
let fish_escape_delay_ms = vars.get_unless_empty(L!("fish_escape_delay_ms"));
let Some(fish_escape_delay_ms) = fish_escape_delay_ms else {
WAIT_ON_ESCAPE_MS.store(0, Ordering::Relaxed);
return;
};
let fish_escape_delay_ms = fish_escape_delay_ms.as_string();
match fish_wcstol(&fish_escape_delay_ms) {
Ok(val) if (10..5000).contains(&val) => {
WAIT_ON_ESCAPE_MS.store(val.try_into().unwrap(), Ordering::Relaxed);
}
_ => {
eprintln!(
concat!(
"ignoring fish_escape_delay_ms: value '{}' ",
"is not an integer or is < 10 or >= 5000 ms"
),
fish_escape_delay_ms
)
}
}
}
// Update the wait_on_sequence_key_ms value in response to the fish_sequence_key_delay_ms user
// variable being set.
pub fn update_wait_on_sequence_key_ms(vars: &EnvStack) {
let sequence_key_time_ms = vars.get_unless_empty(L!("fish_sequence_key_delay_ms"));
let Some(sequence_key_time_ms) = sequence_key_time_ms else {
WAIT_ON_SEQUENCE_KEY_MS.store(WAIT_ON_SEQUENCE_KEY_INFINITE, Ordering::Relaxed);
return;
};
let sequence_key_time_ms = sequence_key_time_ms.as_string();
match fish_wcstol(&sequence_key_time_ms) {
Ok(val) if (10..5000).contains(&val) => {
WAIT_ON_SEQUENCE_KEY_MS.store(val.try_into().unwrap(), Ordering::Relaxed);
}
_ => {
eprintln!(
concat!(
"ignoring fish_sequence_key_delay_ms: value '{}' ",
"is not an integer or is < 10 or >= 5000 ms"
),
sequence_key_time_ms
)
}
}
}
pub static TERMINAL_PROTOCOLS: MainThread<RefCell<Option<TerminalProtocols>>> =
MainThread::new(RefCell::new(None));
pub fn terminal_protocols_enable() {
assert!(TERMINAL_PROTOCOLS.get().borrow().is_none());
TERMINAL_PROTOCOLS
.get()
.replace(Some(TerminalProtocols::new()));
}
pub fn terminal_protocols_disable() {
assert!(TERMINAL_PROTOCOLS.get().borrow().is_some());
TERMINAL_PROTOCOLS.get().replace(None);
}
pub fn terminal_protocols_enable_scoped() -> impl ScopeGuarding<Target = ()> {
terminal_protocols_enable();
ScopeGuard::new((), |()| terminal_protocols_disable())
}
pub fn terminal_protocols_disable_scoped() -> impl ScopeGuarding<Target = ()> {
terminal_protocols_disable();
ScopeGuard::new((), |()| {
// If a child is stopped, this will already be enabled.
if TERMINAL_PROTOCOLS.get().borrow().is_none() {
terminal_protocols_enable();
reader_current_data().unwrap().save_screen_state();
}
})
}
pub struct TerminalProtocols {
focus_events: bool,
}
impl TerminalProtocols {
fn new() -> Self {
terminal_protocols_enable_impl();
Self {
focus_events: false,
}
}
}
impl Drop for TerminalProtocols {
fn drop(&mut self) {
terminal_protocols_disable_impl();
if self.focus_events {
let _ = write_to_fd("\x1b[?1004l".as_bytes(), STDOUT_FILENO);
}
}
}
fn terminal_protocols_enable_impl() {
let sequences = concat!(
"\x1b[?2004h", // Bracketed paste
"\x1b[>4;1m", // XTerm's modifyOtherKeys
"\x1b[>5u", // CSI u with kitty progressive enhancement
"\x1b=", // set application keypad mode, so the keypad keys send unique codes
);
FLOG!(
term_protocols,
format!(
"Enabling extended keys and bracketed paste: {:?}",
sequences
)
);
let _ = write_to_fd(sequences.as_bytes(), STDOUT_FILENO);
}
fn terminal_protocols_disable_impl() {
let sequences = concat!(
"\x1b[?2004l",
"\x1b[>4;0m",
"\x1b[<1u", // Konsole breaks unless we pass an explicit number of entries to pop.
"\x1b>",
);
FLOG!(
term_protocols,
format!(
"Disabling extended keys and bracketed paste: {:?}",
sequences
)
);
let _ = write_to_fd(sequences.as_bytes(), STDOUT_FILENO);
}
pub(crate) static IS_TMUX: RelaxedAtomicBool = RelaxedAtomicBool::new(false);
pub(crate) fn focus_events_enable_ifn() {
if !IS_TMUX.load() {
return;
}
let mut term_protocols = TERMINAL_PROTOCOLS.get().borrow_mut();
let Some(term_protocols) = term_protocols.as_mut() else {
panic!()
};
if !term_protocols.focus_events {
term_protocols.focus_events = true;
let _ = write_to_fd("\x1b[?1004h".as_bytes(), STDOUT_FILENO);
reader_current_data().unwrap().save_screen_state();
}
}
fn parse_mask(mask: u32) -> Modifiers {
Modifiers {
ctrl: (mask & 4) != 0,
alt: (mask & 2) != 0,
shift: (mask & 1) != 0,
}
}
/// A trait which knows how to produce a stream of input events.
/// Note this is conceptually a "base class" with override points.
pub trait InputEventQueuer {
/// \return the next event in the queue, or none if the queue is empty.
fn try_pop(&mut self) -> Option<CharEvent> {
self.get_queue_mut().pop_front()
}
/// Function used by input_readch to read bytes from stdin until enough bytes have been read to
/// convert them to a wchar_t. Conversion is done using mbrtowc. If a character has previously
/// been read and then 'unread' using \c input_common_unreadch, that character is returned.
fn readch(&mut self) -> CharEvent {
let mut state = zero_mbstate();
loop {
// Do we have something enqueued already?
// Note this may be initially true, or it may become true through calls to
// iothread_service_main() or env_universal_barrier() below.
if let Some(mevt) = self.try_pop() {
return mevt;
}
// We are going to block; but first allow any override to inject events.
self.prepare_to_select();
if let Some(mevt) = self.try_pop() {
return mevt;
}
let rr = readb(self.get_in_fd(), /*blocking=*/ true);
match rr {
ReadbResult::Eof => {
return CharEvent::Eof;
}
ReadbResult::Interrupted => {
self.select_interrupted();
}
ReadbResult::UvarNotified => {
self.uvar_change_notified();
}
ReadbResult::IOPortNotified => {
iothread_service_main(reader_current_data().unwrap());
}
ReadbResult::Byte(read_byte) => {
let mut have_escape_prefix = false;
let mut buffer = vec![read_byte];
let key_with_escape = if read_byte == 0x1b {
self.parse_escape_sequence(&mut buffer, &mut have_escape_prefix)
} else {
canonicalize_control_char(read_byte)
};
if self.paste_is_buffering() {
if read_byte != 0x1b {
self.paste_push_char(read_byte);
}
continue;
}
let mut seq = WString::new();
let mut key = key_with_escape;
if key == Some(Key::from_raw(key::Invalid)) {
continue;
}
let mut consumed = 0;
for i in 0..buffer.len() {
self.parse_codepoint(
&mut state,
&mut key,
&mut seq,
&buffer,
i,
&mut consumed,
&mut have_escape_prefix,
);
}
return if let Some(key) = key {
CharEvent::from_key_seq(key, seq)
} else {
self.insert_front(seq.chars().skip(1).map(CharEvent::from_char));
let Some(c) = seq.chars().next() else {
continue;
};
CharEvent::from_key_seq(Key::from_raw(c), seq)
};
}
ReadbResult::NothingToRead => unreachable!(),
}
}
}
fn try_readb(&mut self, buffer: &mut Vec<u8>) -> Option<u8> {
let ReadbResult::Byte(next) = readb(self.get_in_fd(), /*blocking=*/ false) else {
return None;
};
buffer.push(next);
Some(next)
}
fn parse_escape_sequence(
&mut self,
buffer: &mut Vec<u8>,
have_escape_prefix: &mut bool,
) -> Option<Key> {
let Some(next) = self.try_readb(buffer) else {
if !self.paste_is_buffering() {
return Some(Key::from_raw(key::Escape));
}
return None;
};
if next == b'[' {
// potential CSI
return Some(self.parse_csi(buffer).unwrap_or(alt('[')));
}
if next == b'O' {
// potential SS3
return Some(self.parse_ss3(buffer).unwrap_or(alt('O')));
}
match canonicalize_control_char(next) {
Some(mut key) => {
key.modifiers.alt = true;
Some(key)
}
None => {
*have_escape_prefix = true;
None
}
}
}
fn parse_codepoint(
&mut self,
state: &mut mbstate_t,
out_key: &mut Option<Key>,
out_seq: &mut WString,
buffer: &[u8],
i: usize,
consumed: &mut usize,
have_escape_prefix: &mut bool,
) {
let mut res: char = '\0';
let read_byte = buffer[i];
if crate::libc::MB_CUR_MAX() == 1 {
// single-byte locale, all values are legal
// FIXME: this looks wrong, this falsely assumes that
// the single-byte locale is compatible with Unicode upper-ASCII.
res = read_byte.into();
out_seq.push(res);
return;
}
let mut codepoint = u32::from(res);
let sz = unsafe {
mbrtowc(
std::ptr::addr_of_mut!(codepoint).cast(),
std::ptr::addr_of!(read_byte).cast(),
1,
state,
)
} as isize;
match sz {
-1 => {
FLOG!(reader, "Illegal input");
*consumed += 1;
self.push_front(CharEvent::from_check_exit());
return;
}
-2 => {
// Sequence not yet complete.
return;
}
0 => {
// Actual nul char.
*consumed += 1;
out_seq.push('\0');
return;
}
_ => (),
}
if let Some(res) = char::from_u32(codepoint) {
// Sequence complete.
if !fish_reserved_codepoint(res) {
if *have_escape_prefix && i != 0 {
*have_escape_prefix = false;
*out_key = Some(alt(res));
}
*consumed += 1;
out_seq.push(res);
return;
}
}
for &b in &buffer[*consumed..i] {
out_seq.push(encode_byte_to_char(b));
*consumed += 1;
}
}
fn parse_csi(&mut self, buffer: &mut Vec<u8>) -> Option<Key> {
let mut next_char = |zelf: &mut Self| zelf.try_readb(buffer).unwrap_or(0xff);
let mut params = [[0_u32; 16]; 4];
let mut c = next_char(self);
let private_mode;
if matches!(c, b'?' | b'<' | b'=' | b'>') {
// private mode
private_mode = Some(c);
c = next_char(self);
} else {
private_mode = None;
}
let mut count = 0;
let mut subcount = 0;
while count < 16 && c >= 0x30 && c <= 0x3f {
if c.is_ascii_digit() {
params[count][subcount] = params[count][subcount] * 10 + u32::from(c - b'0');
} else if c == b':' && subcount < 3 {
subcount += 1;
} else if c == b';' {
count += 1;
subcount = 0;
} else {
return None;
}
c = next_char(self);
}
if c != b'$' && !(0x40..=0x7e).contains(&c) {
return None;
}
let masked_key = |mut codepoint, shifted_codepoint| {
let mask = params[1][0].saturating_sub(1);
let mut modifiers = parse_mask(mask);
if let Some(shifted_codepoint) = shifted_codepoint {
if shifted_codepoint != '\0' && modifiers.shift {
modifiers.shift = false;
codepoint = shifted_codepoint;
}
}
Key {
modifiers,
codepoint,
}
};
let key = match c {
b'$' => {
if private_mode == Some(b'?') && next_char(self) == b'y' {
// DECRPM
return None;
}
match params[0][0] {
23 | 24 => shift(
char::from_u32(u32::from(function_key(11)) + params[0][0] - 23).unwrap(), // rxvt style
),
_ => return None,
}
}
b'A' | b'a' => masked_key(key::Up, None),
b'B' | b'b' => masked_key(key::Down, None),
b'C' | b'c' => masked_key(key::Right, None),
b'D' | b'd' => masked_key(key::Left, None),
b'E' => masked_key('5', None), // Numeric keypad
b'F' => masked_key(key::End, None), // PC/xterm style
b'H' => masked_key(key::Home, None), // PC/xterm style
b'M' | b'm' => {
self.disable_mouse_tracking();
let sgr = private_mode == Some(b'<');
if !sgr && c == b'm' {
return None;
}
// Extended (SGR/1006) mouse reporting mode, with semicolon-separated parameters
// for button code, Px, and Py, ending with 'M' for button press or 'm' for
// button release.
if sgr {
return None;
}
// Generic X10 or modified VT200 sequence. It doesn't matter which, they're both 6
// chars (although in mode 1005, the characters may be unicode and not necessarily
// just one byte long) reporting the button that was clicked and its location.
let _ = next_char(self);
let _ = next_char(self);
let _ = next_char(self);
return None;
}
b't' => {
self.disable_mouse_tracking();
// VT200 button released in mouse highlighting mode at valid text location. 5 chars.
let _ = next_char(self);
let _ = next_char(self);
return None;
}
b'T' => {
self.disable_mouse_tracking();
// VT200 button released in mouse highlighting mode past end-of-line. 9 characters.
for _ in 0..7 {
let _ = next_char(self);
}
return None;
}
b'P' => masked_key(function_key(1), None),
b'Q' => masked_key(function_key(2), None),
b'R' => masked_key(function_key(3), None),
b'S' => masked_key(function_key(4), None),
b'~' => match params[0][0] {
1 => masked_key(key::Home, None), // VT220/tmux style
2 => masked_key(key::Insert, None),
3 => masked_key(key::Delete, None),
4 => masked_key(key::End, None), // VT220/tmux style
5 => masked_key(key::PageUp, None),
6 => masked_key(key::PageDown, None),
7 => masked_key(key::Home, None), // rxvt style
8 => masked_key(key::End, None), // rxvt style
11..=15 => masked_key(
char::from_u32(u32::from(function_key(1)) + params[0][0] - 11).unwrap(),
None,
),
17..=21 => masked_key(
char::from_u32(u32::from(function_key(6)) + params[0][0] - 17).unwrap(),
None,
),
23 | 24 => masked_key(
char::from_u32(u32::from(function_key(11)) + params[0][0] - 23).unwrap(),
None,
),
25 | 26 => {
shift(char::from_u32(u32::from(function_key(3)) + params[0][0] - 25).unwrap())
} // rxvt style
28 | 29 => {
shift(char::from_u32(u32::from(function_key(5)) + params[0][0] - 28).unwrap())
} // rxvt style
31 | 32 => {
shift(char::from_u32(u32::from(function_key(7)) + params[0][0] - 31).unwrap())
} // rxvt style
33 | 34 => {
shift(char::from_u32(u32::from(function_key(9)) + params[0][0] - 33).unwrap())
} // rxvt style
200 => {
self.paste_start_buffering();
return Some(Key::from_raw(key::Invalid));
}
201 => {
self.paste_commit();
return Some(Key::from_raw(key::Invalid));
}
_ => return None,
},
b'u' => {
// Treat numpad keys the same as their non-numpad counterparts. Could add a numpad modifier here.
let key = match params[0][0] {
57399 => '0',
57400 => '1',
57401 => '2',
57402 => '3',
57403 => '4',
57404 => '5',
57405 => '6',
57406 => '7',
57407 => '8',
57408 => '9',
57409 => '.',
57410 => '/',
57411 => '*',
57412 => '-',
57413 => '+',
57414 => key::Enter,
57415 => '=',
57417 => key::Left,
57418 => key::Right,
57419 => key::Up,
57420 => key::Down,
57421 => key::PageUp,
57422 => key::PageDown,
57423 => key::Home,
57424 => key::End,
57425 => key::Insert,
57426 => key::Delete,
cp => canonicalize_keyed_control_char(char::from_u32(cp).unwrap()),
};
masked_key(
key,
Some(canonicalize_keyed_control_char(
char::from_u32(params[0][1]).unwrap(),
)),
)
}
b'Z' => shift(key::Tab),
b'I' => {
self.push_front(CharEvent::from_readline(ReadlineCmd::FocusIn));
return Some(Key::from_raw(key::Invalid));
}
b'O' => {
self.push_front(CharEvent::from_readline(ReadlineCmd::FocusOut));
return Some(Key::from_raw(key::Invalid));
}
_ => return None,
};
Some(key)
}
fn disable_mouse_tracking(&mut self) {
// fish recognizes but does not actually support mouse reporting. We never turn it on, and
// it's only ever enabled if a program we spawned enabled it and crashed or forgot to turn
// it off before exiting. We turn it off here to avoid wasting resources.
//
// Since this is only called when we detect an incoming mouse reporting payload, we know the
// terminal emulator supports mouse reporting, so no terminfo checks.
FLOG!(reader, "Disabling mouse tracking");
// We shouldn't directly manipulate stdout from here, so we ask the reader to do it.
// writembs(outputter_t::stdoutput(), "\x1B[?1000l");
self.push_front(CharEvent::from_readline(ReadlineCmd::DisableMouseTracking));
}
fn parse_ss3(&mut self, buffer: &mut Vec<u8>) -> Option<Key> {
let mut raw_mask = 0;
let mut code = b'0';
loop {
raw_mask = raw_mask * 10 + u32::from(code - b'0');
code = self.try_readb(buffer).unwrap_or(0xff);
if !(b'0'..=b'9').contains(&code) {
break;
}
}
let modifiers = parse_mask(raw_mask.saturating_sub(1));
#[rustfmt::skip]
let key = match code {
b' ' => Key{modifiers, codepoint: key::Space},
b'A' | b'a' => Key{modifiers, codepoint: key::Up},
b'B' | b'b' => Key{modifiers, codepoint: key::Down},
b'C' | b'c' => Key{modifiers, codepoint: key::Right},
b'D' | b'd' => Key{modifiers, codepoint: key::Left},
b'F' => Key{modifiers, codepoint: key::End},
b'H' => Key{modifiers, codepoint: key::Home},
b'I' => Key{modifiers, codepoint: key::Tab},
b'M' => Key{modifiers, codepoint: key::Enter},
b'P' => Key{modifiers, codepoint: function_key(1)},
b'Q' => Key{modifiers, codepoint: function_key(2)},
b'R' => Key{modifiers, codepoint: function_key(3)},
b'S' => Key{modifiers, codepoint: function_key(4)},
b'X' => Key{modifiers, codepoint: '='},
b'j' => Key{modifiers, codepoint: '*'},
b'k' => Key{modifiers, codepoint: '+'},
b'l' => Key{modifiers, codepoint: ','},
b'm' => Key{modifiers, codepoint: '-'},
b'n' => Key{modifiers, codepoint: '.'},
b'o' => Key{modifiers, codepoint: '/'},
b'p' => Key{modifiers, codepoint: '0'},
b'q' => Key{modifiers, codepoint: '1'},
b'r' => Key{modifiers, codepoint: '2'},
b's' => Key{modifiers, codepoint: '3'},
b't' => Key{modifiers, codepoint: '4'},
b'u' => Key{modifiers, codepoint: '5'},
b'v' => Key{modifiers, codepoint: '6'},
b'w' => Key{modifiers, codepoint: '7'},
b'x' => Key{modifiers, codepoint: '8'},
b'y' => Key{modifiers, codepoint: '9'},
_ => return None,
};
Some(key)
}
fn readch_timed_esc(&mut self, style: &KeyNameStyle) -> Result<CharEvent, bool> {
let wait_ms = WAIT_ON_ESCAPE_MS.load(Ordering::Relaxed);
if wait_ms == 0 {
if *style == KeyNameStyle::Plain {
return self.readch_timed_sequence_key().ok_or(true);
}
return Err(false); // Not timed out
}
self.readch_timed(WAIT_ON_ESCAPE_MS.load(Ordering::Relaxed))
.ok_or(true) // Timed out
}
fn readch_timed_sequence_key(&mut self) -> Option<CharEvent> {
let wait_on_sequence_key_ms = WAIT_ON_SEQUENCE_KEY_MS.load(Ordering::Relaxed);
if wait_on_sequence_key_ms == WAIT_ON_SEQUENCE_KEY_INFINITE {
return Some(self.readch());
}
self.readch_timed(wait_on_sequence_key_ms)
}
/// Like readch(), except it will wait at most wait_time_ms milliseconds for a
/// character to be available for reading.
/// \return None on timeout, the event on success.
fn readch_timed(&mut self, wait_time_ms: usize) -> Option<CharEvent> {
if let Some(evt) = self.try_pop() {
return Some(evt);
}
focus_events_enable_ifn();
// We are not prepared to handle a signal immediately; we only want to know if we get input on
// our fd before the timeout. Use pselect to block all signals; we will handle signals
// before the next call to readch().
let mut sigs: libc::sigset_t = unsafe { std::mem::zeroed() };
unsafe { libc::sigfillset(&mut sigs) };
// pselect expects timeouts in nanoseconds.
const NSEC_PER_MSEC: u64 = 1000 * 1000;
const NSEC_PER_SEC: u64 = NSEC_PER_MSEC * 1000;
let wait_nsec: u64 = (wait_time_ms as u64) * NSEC_PER_MSEC;
let timeout = libc::timespec {
tv_sec: (wait_nsec / NSEC_PER_SEC).try_into().unwrap(),
tv_nsec: (wait_nsec % NSEC_PER_SEC).try_into().unwrap(),
};
// We have one fd of interest.
let mut fdset: libc::fd_set = unsafe { std::mem::zeroed() };
let in_fd = self.get_in_fd();
unsafe {
libc::FD_ZERO(&mut fdset);
libc::FD_SET(in_fd, &mut fdset);
};
let res = unsafe {
libc::pselect(
in_fd + 1,
&mut fdset,
ptr::null_mut(),
ptr::null_mut(),
&timeout,
&sigs,
)
};
// Prevent signal starvation on WSL causing the `torn_escapes.py` test to fail
if is_windows_subsystem_for_linux() {
// Merely querying the current thread's sigmask is sufficient to deliver a pending signal
let _ = unsafe { libc::pthread_sigmask(0, ptr::null(), &mut sigs) };
}
if res > 0 {
return Some(self.readch());
}
None
}
/// Return our queue. These are "abstract" methods to be implemented by concrete types.
fn get_queue(&self) -> &VecDeque<CharEvent>;
fn get_queue_mut(&mut self) -> &mut VecDeque<CharEvent>;
/// Return the fd corresponding to stdin.
fn get_in_fd(&self) -> RawFd;
// Support for "bracketed paste"
// The way it works is that we acknowledge our support by printing
// \e\[?2004h
// then the terminal will "bracket" every paste in
// \e\[200~ and \e\[201~
// Every character in between those two will be part of the paste and should not cause a binding to execute (like \n executing commands).
//
// We enable it after every command and disable it before, see the terminal protocols logic.
//
// Support for this seems to be ubiquitous - emacs enables it unconditionally (!) since 25.1
// (though it only supports it since then, it seems to be the last term to gain support).
//
// See http://thejh.net/misc/website-terminal-copy-paste.
fn paste_start_buffering(&mut self);
fn paste_is_buffering(&self) -> bool;
fn paste_push_char(&mut self, _b: u8) {}
fn paste_commit(&mut self);
/// Enqueue a character or a readline function to the queue of unread characters that
/// readch will return before actually reading from fd 0.
fn push_back(&mut self, ch: CharEvent) {
self.get_queue_mut().push_back(ch);
}
/// Add a character or a readline function to the front of the queue of unread characters. This
/// will be the next character returned by readch.
fn push_front(&mut self, ch: CharEvent) {
self.get_queue_mut().push_front(ch);
}
/// Find the first sequence of non-char events, and promote them to the front.
fn promote_interruptions_to_front(&mut self) {
// Find the first sequence of non-char events.
// EOF is considered a char: we don't want to pull EOF in front of real chars.
let queue = self.get_queue_mut();
let is_char = |evt: &CharEvent| evt.is_char() || evt.is_eof();
// Find the index of the first non-char event.
// If there's none, we're done.
let Some(first): Option<usize> = queue.iter().position(|e| !is_char(e)) else {
return;
};
let last = queue
.range(first..)
.position(is_char)
.map_or(queue.len(), |x| x + first);
// Move the non-char events to the front, retaining their order.
let elems: Vec<CharEvent> = queue.drain(first..last).collect();
for elem in elems.into_iter().rev() {
queue.push_front(elem);
}
}
/// Add multiple readline events to the front of the queue of unread characters.
/// The order of the provided events is not changed, i.e. they are not inserted in reverse
/// order. That is, the first element in evts will be the first element returned.
fn insert_front<I>(&mut self, evts: I)
where
I: IntoIterator<Item = CharEvent>,
I::IntoIter: DoubleEndedIterator,
{
let queue = self.get_queue_mut();
let iter = evts.into_iter().rev();
queue.reserve(iter.size_hint().0);
for evt in iter {
queue.push_front(evt);
}
}
/// Forget all enqueued readline events in the front of the queue.
fn drop_leading_readline_events(&mut self) {
let queue = self.get_queue_mut();
while let Some(evt) = queue.front() {
if evt.is_readline_or_command() {
queue.pop_front();
} else {
break;
}
}
}
/// Override point for when we are about to (potentially) block in select(). The default does
/// nothing.
fn prepare_to_select(&mut self) {}
/// Called when select() is interrupted by a signal.
fn select_interrupted(&mut self);
/// Override point for when when select() is interrupted by the universal variable notifier.
/// The default does nothing.
fn uvar_change_notified(&mut self) {}
/// \return if we have any lookahead.
fn has_lookahead(&self) -> bool {
!self.get_queue().is_empty()
}
}
/// A simple, concrete implementation of InputEventQueuer.
pub struct InputEventQueue {
queue: VecDeque<CharEvent>,
in_fd: RawFd,
is_in_bracketed_paste: bool,
}
impl InputEventQueue {
pub fn new(in_fd: RawFd) -> InputEventQueue {
InputEventQueue {
queue: VecDeque::new(),
in_fd,
is_in_bracketed_paste: false,
}
}
}
impl InputEventQueuer for InputEventQueue {
fn get_queue(&self) -> &VecDeque<CharEvent> {
&self.queue
}
fn get_queue_mut(&mut self) -> &mut VecDeque<CharEvent> {
&mut self.queue
}
fn get_in_fd(&self) -> RawFd {
self.in_fd
}
fn select_interrupted(&mut self) {
if reader_test_and_clear_interrupted() != 0 {
let vintr = shell_modes().c_cc[libc::VINTR];
if vintr != 0 {
self.push_front(CharEvent::from_key(Key::from_single_byte(vintr)));
}
}
}
fn paste_start_buffering(&mut self) {
self.is_in_bracketed_paste = true;
}
fn paste_is_buffering(&self) -> bool {
self.is_in_bracketed_paste
}
fn paste_commit(&mut self) {
self.is_in_bracketed_paste = false;
}
}
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