use libc::STDOUT_FILENO; use crate::common::{ fish_reserved_codepoint, is_windows_subsystem_for_linux, read_blocked, shell_modes, WSL, }; use crate::env::{EnvStack, Environment}; use crate::fd_readable_set::FdReadableSet; use crate::flog::FLOG; use crate::global_safety::RelaxedAtomicBool; 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, 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::ops::ControlFlow; 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, 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. const WAIT_ON_ESCAPE_DEFAULT: usize = 30; static WAIT_ON_ESCAPE_MS: AtomicUsize = AtomicUsize::new(WAIT_ON_ESCAPE_DEFAULT); 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; } FLOG!(reader, "Read byte", arr[0]); // 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(WAIT_ON_ESCAPE_DEFAULT, 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 ) } } } static TERMINAL_PROTOCOLS: MainThread>> = MainThread::new(RefCell::new(None)); pub(crate) static IS_TMUX: RelaxedAtomicBool = RelaxedAtomicBool::new(false); pub fn terminal_protocols_enable_ifn() { let mut term_protocols = TERMINAL_PROTOCOLS.get().borrow_mut(); if term_protocols.is_some() { return; } *term_protocols = Some(TerminalProtocols::new()); } pub(crate) fn terminal_protocols_disable_ifn() { TERMINAL_PROTOCOLS.get().replace(None); } pub(crate) fn terminal_protocols_try_disable_ifn() { if let Ok(mut term_protocols) = TERMINAL_PROTOCOLS.get().try_borrow_mut() { *term_protocols = None; } } struct TerminalProtocols {} impl TerminalProtocols { fn new() -> Self { 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); if IS_TMUX.load() { let _ = write_to_fd("\x1b[?1004h".as_bytes(), STDOUT_FILENO); } reader_current_data().map(|data| data.save_screen_state()); Self {} } } impl Drop for TerminalProtocols { fn drop(&mut self) { 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); if IS_TMUX.load() { let _ = write_to_fd("\x1b[?1004l".as_bytes(), STDOUT_FILENO); } reader_current_data().map(|data| data.save_screen_state()); } } fn parse_mask(mask: u32) -> Modifiers { Modifiers { ctrl: (mask & 4) != 0, alt: (mask & 2) != 0, shift: (mask & 1) != 0, } } // A data type used by the input machinery. pub struct InputData { // The file descriptor from which we read input, often stdin. pub in_fd: RawFd, // Queue of unread characters. pub queue: VecDeque, // The current paste buffer, if any. pub paste_buffer: Option>, // The arguments to the most recently invoked input function. pub input_function_args: Vec, // The return status of the most recently invoked input function. pub function_status: bool, // Transient storage to avoid repeated allocations. pub event_storage: Vec, } impl InputData { /// Construct from the fd from which to read. pub fn new(in_fd: RawFd) -> Self { Self { in_fd, queue: VecDeque::new(), paste_buffer: None, input_function_args: Vec::new(), function_status: false, event_storage: Vec::new(), } } /// Enqueue a char event to the queue of unread characters that input_readch will return before /// actually reading from fd 0. pub fn queue_char(&mut self, ch: CharEvent) { self.queue.push_back(ch); } /// Sets the return status of the most recently executed input function. pub fn function_set_status(&mut self, status: bool) { self.function_status = status; } } /// 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 { self.get_input_data_mut().queue.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 { 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 => { self.ioport_notified(); } 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; let mut state = zero_mbstate(); let mut i = 0; let ok = loop { if i == buffer.len() { buffer.push(match readb(self.get_in_fd(), /*blocking=*/ true) { ReadbResult::Byte(b) => b, _ => 0, }); } match self.parse_codepoint( &mut state, &mut key, &mut seq, &buffer, i, &mut consumed, &mut have_escape_prefix, ) { ControlFlow::Continue(codepoint_complete) => { if codepoint_complete && i + 1 == buffer.len() { break true; } } ControlFlow::Break(()) => { break false; } } i += 1; }; if !ok { continue; } 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) -> Option { 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, have_escape_prefix: &mut bool, ) -> Option { 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, out_seq: &mut WString, buffer: &[u8], i: usize, consumed: &mut usize, have_escape_prefix: &mut bool, ) -> ControlFlow<(), 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 ControlFlow::Continue(true); } 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 ControlFlow::Break(()); } -2 => { // Sequence not yet complete. return ControlFlow::Continue(false); } 0 => { // Actual nul char. *consumed += 1; out_seq.push('\0'); return ControlFlow::Continue(true); } _ => (), } 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 ControlFlow::Continue(true); } } for &b in &buffer[*consumed..i] { out_seq.push(encode_byte_to_char(b)); *consumed += 1; } ControlFlow::Continue(true) } fn parse_csi(&mut self, buffer: &mut Vec) -> Option { 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) -> Option { 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) -> Option { self.readch_timed(WAIT_ON_ESCAPE_MS.load(Ordering::Relaxed)) } fn readch_timed_sequence_key(&mut self) -> Option { 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 { if let Some(evt) = self.try_pop() { return Some(evt); } terminal_protocols_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(WSL::V1) { // 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 the fd from which to read. fn get_in_fd(&self) -> RawFd { self.get_input_data().in_fd } /// Return the input data. This is to be implemented by the concrete type. fn get_input_data(&self) -> &InputData; fn get_input_data_mut(&mut self) -> &mut InputData; // 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) { self.get_input_data_mut().paste_buffer = Some(Vec::new()); } fn paste_is_buffering(&self) -> bool { self.get_input_data().paste_buffer.is_some() } fn paste_push_char(&mut self, b: u8) { self.get_input_data_mut() .paste_buffer .as_mut() .unwrap() .push(b) } fn paste_commit(&mut self) { self.get_input_data_mut().paste_buffer = None; } /// 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_input_data_mut().queue.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_input_data_mut().queue.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 = &mut self.get_input_data_mut().queue; 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 = 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 = 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(&mut self, evts: I) where I: IntoIterator, I::IntoIter: DoubleEndedIterator, { let queue = &mut self.get_input_data_mut().queue; 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 = &mut self.get_input_data_mut().queue; 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) {} /// Override point for when the ioport is ready. /// The default does nothing. fn ioport_notified(&mut self) {} /// Reset the function status. fn get_function_status(&self) -> bool { self.get_input_data().function_status } /// Return if we have any lookahead. fn has_lookahead(&self) -> bool { !self.get_input_data().queue.is_empty() } } /// A simple, concrete implementation of InputEventQueuer. pub struct InputEventQueue { data: InputData, } impl InputEventQueue { pub fn new(in_fd: RawFd) -> InputEventQueue { InputEventQueue { data: InputData::new(in_fd), } } } impl InputEventQueuer for InputEventQueue { fn get_input_data(&self) -> &InputData { &self.data } fn get_input_data_mut(&mut self) -> &mut InputData { &mut self.data } 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))); } } } }