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winit/src/platform_impl/linux/x11/event_processor.rs
Kirill Chibisov 3fb93b4f83 Deprecate window creation with stale event loop 
Creating window when event loop is not running generally doesn't work,
since a bunch of events and sync OS requests can't be processed. This
is also an issue on e.g. Android, since window can't be created outside
event loop easily.

Thus deprecate the window creation when event loop is not running,
as well as other resource creation to running event loop.

Given that all the examples use the bad pattern of creating the window
when event loop is not running and also most example existence is
questionable, since they show single thing and the majority of their
code is window/event loop initialization, they wore merged into
a single example 'window.rs' example that showcases very simple
application using winit.

Fixes #3399.
2024-02-21 14:44:29 +04:00

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use std::cell::{Cell, RefCell};
use std::collections::HashMap;
use std::os::raw::{c_char, c_int, c_long, c_ulong};
use std::slice;
use std::sync::{Arc, Mutex};
use x11_dl::xinput2::{
self, XIDeviceEvent, XIEnterEvent, XIFocusInEvent, XIFocusOutEvent, XIHierarchyEvent,
XILeaveEvent, XIModifierState, XIRawEvent,
};
use x11_dl::xlib::{
self, Display as XDisplay, Window as XWindow, XAnyEvent, XClientMessageEvent, XConfigureEvent,
XDestroyWindowEvent, XEvent, XExposeEvent, XKeyEvent, XMapEvent, XPropertyEvent,
XReparentEvent, XSelectionEvent, XVisibilityEvent, XkbAnyEvent,
};
use x11rb::protocol::xinput;
use x11rb::protocol::xproto::{self, ConnectionExt as _, ModMask};
use x11rb::x11_utils::ExtensionInformation;
use x11rb::x11_utils::Serialize;
use xkbcommon_dl::xkb_mod_mask_t;
use crate::dpi::{PhysicalPosition, PhysicalSize};
use crate::event::{
DeviceEvent, ElementState, Event, Ime, MouseScrollDelta, RawKeyEvent, Touch, TouchPhase,
WindowEvent,
};
use crate::event::{InnerSizeWriter, MouseButton};
use crate::event_loop::ActiveEventLoop as RootAEL;
use crate::keyboard::ModifiersState;
use crate::platform_impl::common::xkb::{self, XkbState};
use crate::platform_impl::platform::common::xkb::Context;
use crate::platform_impl::platform::x11::ime::{ImeEvent, ImeEventReceiver, ImeRequest};
use crate::platform_impl::platform::x11::ActiveEventLoop;
use crate::platform_impl::platform::ActiveEventLoop as PlatformActiveEventLoop;
use crate::platform_impl::x11::{
atoms::*, mkdid, mkwid, util, CookieResultExt, Device, DeviceId, DeviceInfo, Dnd, DndState,
GenericEventCookie, ImeReceiver, ScrollOrientation, UnownedWindow, WindowId,
};
/// The X11 documentation states: "Keycodes lie in the inclusive range `[8, 255]`".
const KEYCODE_OFFSET: u8 = 8;
pub struct EventProcessor {
pub dnd: Dnd,
pub ime_receiver: ImeReceiver,
pub ime_event_receiver: ImeEventReceiver,
pub randr_event_offset: u8,
pub devices: RefCell<HashMap<DeviceId, Device>>,
pub xi2ext: ExtensionInformation,
pub xkbext: ExtensionInformation,
pub target: RootAEL,
pub xkb_context: Context,
// Number of touch events currently in progress
pub num_touch: u32,
// This is the last pressed key that is repeatable (if it hasn't been
// released).
//
// Used to detect key repeats.
pub held_key_press: Option<u32>,
pub first_touch: Option<u64>,
// Currently focused window belonging to this process
pub active_window: Option<xproto::Window>,
/// Latest modifiers we've sent for the user to trigger change in event.
pub modifiers: Cell<ModifiersState>,
pub is_composing: bool,
}
impl EventProcessor {
pub fn process_event<T: 'static, F>(&mut self, xev: &mut XEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
self.process_xevent(xev, &mut callback);
let window_target = Self::window_target_mut(&mut self.target);
// Handle IME requests.
while let Ok(request) = self.ime_receiver.try_recv() {
let ime = match window_target.ime.as_mut() {
Some(ime) => ime,
None => continue,
};
let ime = ime.get_mut();
match request {
ImeRequest::Position(window_id, x, y) => {
ime.send_xim_spot(window_id, x, y);
}
ImeRequest::Allow(window_id, allowed) => {
ime.set_ime_allowed(window_id, allowed);
}
}
}
// Drain IME events.
while let Ok((window, event)) = self.ime_event_receiver.try_recv() {
let window_id = mkwid(window as xproto::Window);
let event = match event {
ImeEvent::Enabled => WindowEvent::Ime(Ime::Enabled),
ImeEvent::Start => {
self.is_composing = true;
WindowEvent::Ime(Ime::Preedit("".to_owned(), None))
}
ImeEvent::Update(text, position) if self.is_composing => {
WindowEvent::Ime(Ime::Preedit(text, Some((position, position))))
}
ImeEvent::End => {
self.is_composing = false;
// Issue empty preedit on `Done`.
WindowEvent::Ime(Ime::Preedit(String::new(), None))
}
ImeEvent::Disabled => {
self.is_composing = false;
WindowEvent::Ime(Ime::Disabled)
}
_ => continue,
};
callback(&self.target, Event::WindowEvent { window_id, event });
}
}
/// XFilterEvent tells us when an event has been discarded by the input method.
/// Specifically, this involves all of the KeyPress events in compose/pre-edit sequences,
/// along with an extra copy of the KeyRelease events. This also prevents backspace and
/// arrow keys from being detected twice.
fn filter_event(&mut self, xev: &mut XEvent) -> bool {
let wt = Self::window_target(&self.target);
unsafe {
(wt.xconn.xlib.XFilterEvent)(xev, {
let xev: &XAnyEvent = xev.as_ref();
xev.window
}) == xlib::True
}
}
fn process_xevent<T: 'static, F>(&mut self, xev: &mut XEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
if self.filter_event(xev) {
return;
}
let event_type = xev.get_type();
match event_type {
xlib::ClientMessage => self.client_message(xev.as_ref(), &mut callback),
xlib::SelectionNotify => self.selection_notify(xev.as_ref(), &mut callback),
xlib::ConfigureNotify => self.configure_notify(xev.as_ref(), &mut callback),
xlib::ReparentNotify => self.reparent_notify(xev.as_ref()),
xlib::MapNotify => self.map_notify(xev.as_ref(), &mut callback),
xlib::DestroyNotify => self.destroy_notify(xev.as_ref(), &mut callback),
xlib::PropertyNotify => self.property_notify(xev.as_ref(), &mut callback),
xlib::VisibilityNotify => self.visibility_notify(xev.as_ref(), &mut callback),
xlib::Expose => self.expose(xev.as_ref(), &mut callback),
// Note that in compose/pre-edit sequences, we'll always receive KeyRelease events.
ty @ xlib::KeyPress | ty @ xlib::KeyRelease => {
let state = if ty == xlib::KeyPress {
ElementState::Pressed
} else {
ElementState::Released
};
self.xinput_key_input(xev.as_mut(), state, &mut callback);
}
xlib::GenericEvent => {
let wt = Self::window_target(&self.target);
let xev = match GenericEventCookie::from_event(&wt.xconn, *xev) {
Some(xev) if xev.cookie.extension as u8 == self.xi2ext.major_opcode => {
xev.cookie
}
_ => return,
};
match xev.evtype {
ty @ xinput2::XI_ButtonPress | ty @ xinput2::XI_ButtonRelease => {
let state = if ty == xinput2::XI_ButtonPress {
ElementState::Pressed
} else {
ElementState::Released
};
let xev: &XIDeviceEvent = unsafe { &*(xev.data as *const _) };
self.update_mods_from_xinput2_event(&xev.mods, &xev.group, &mut callback);
self.xinput2_button_input(xev, state, &mut callback);
}
xinput2::XI_Motion => {
let xev: &XIDeviceEvent = unsafe { &*(xev.data as *const _) };
self.update_mods_from_xinput2_event(&xev.mods, &xev.group, &mut callback);
self.xinput2_mouse_motion(xev, &mut callback);
}
xinput2::XI_Enter => {
let xev: &XIEnterEvent = unsafe { &*(xev.data as *const _) };
self.xinput2_mouse_enter(xev, &mut callback);
}
xinput2::XI_Leave => {
let xev: &XILeaveEvent = unsafe { &*(xev.data as *const _) };
self.update_mods_from_xinput2_event(&xev.mods, &xev.group, &mut callback);
self.xinput2_mouse_left(xev, &mut callback);
}
xinput2::XI_FocusIn => {
let xev: &XIFocusInEvent = unsafe { &*(xev.data as *const _) };
self.xinput2_focused(xev, &mut callback);
}
xinput2::XI_FocusOut => {
let xev: &XIFocusOutEvent = unsafe { &*(xev.data as *const _) };
self.xinput2_unfocused(xev, &mut callback);
}
xinput2::XI_TouchBegin | xinput2::XI_TouchUpdate | xinput2::XI_TouchEnd => {
let phase = match xev.evtype {
xinput2::XI_TouchBegin => TouchPhase::Started,
xinput2::XI_TouchUpdate => TouchPhase::Moved,
xinput2::XI_TouchEnd => TouchPhase::Ended,
_ => unreachable!(),
};
let xev: &XIDeviceEvent = unsafe { &*(xev.data as *const _) };
self.xinput2_touch(xev, phase, &mut callback);
}
xinput2::XI_RawButtonPress | xinput2::XI_RawButtonRelease => {
let state = match xev.evtype {
xinput2::XI_RawButtonPress => ElementState::Pressed,
xinput2::XI_RawButtonRelease => ElementState::Released,
_ => unreachable!(),
};
let xev: &XIRawEvent = unsafe { &*(xev.data as *const _) };
self.xinput2_raw_button_input(xev, state, &mut callback);
}
xinput2::XI_RawMotion => {
let xev: &XIRawEvent = unsafe { &*(xev.data as *const _) };
self.xinput2_raw_mouse_motion(xev, &mut callback);
}
xinput2::XI_RawKeyPress | xinput2::XI_RawKeyRelease => {
let state = match xev.evtype {
xinput2::XI_RawKeyPress => ElementState::Pressed,
xinput2::XI_RawKeyRelease => ElementState::Released,
_ => unreachable!(),
};
let xev: &xinput2::XIRawEvent = unsafe { &*(xev.data as *const _) };
self.xinput2_raw_key_input(xev, state, &mut callback);
}
xinput2::XI_HierarchyChanged => {
let xev: &XIHierarchyEvent = unsafe { &*(xev.data as *const _) };
self.xinput2_hierarchy_changed(xev, &mut callback);
}
_ => {}
}
}
_ => {
if event_type == self.xkbext.first_event as _ {
let xev: &XkbAnyEvent = unsafe { &*(xev as *const _ as *const XkbAnyEvent) };
self.xkb_event(xev, &mut callback);
}
if event_type == self.randr_event_offset as c_int {
self.process_dpi_change(&mut callback);
}
}
}
}
pub fn poll(&self) -> bool {
let window_target = Self::window_target(&self.target);
let result = unsafe { (window_target.xconn.xlib.XPending)(window_target.xconn.display) };
result != 0
}
pub unsafe fn poll_one_event(&mut self, event_ptr: *mut XEvent) -> bool {
let window_target = Self::window_target(&self.target);
// This function is used to poll and remove a single event
// from the Xlib event queue in a non-blocking, atomic way.
// XCheckIfEvent is non-blocking and removes events from queue.
// XNextEvent can't be used because it blocks while holding the
// global Xlib mutex.
// XPeekEvent does not remove events from the queue.
unsafe extern "C" fn predicate(
_display: *mut XDisplay,
_event: *mut XEvent,
_arg: *mut c_char,
) -> c_int {
// This predicate always returns "true" (1) to accept all events
1
}
let result = unsafe {
(window_target.xconn.xlib.XCheckIfEvent)(
window_target.xconn.display,
event_ptr,
Some(predicate),
std::ptr::null_mut(),
)
};
result != 0
}
pub fn init_device(&self, device: xinput::DeviceId) {
let window_target = Self::window_target(&self.target);
let mut devices = self.devices.borrow_mut();
if let Some(info) = DeviceInfo::get(&window_target.xconn, device as _) {
for info in info.iter() {
devices.insert(DeviceId(info.deviceid as _), Device::new(info));
}
}
}
pub fn with_window<F, Ret>(&self, window_id: xproto::Window, callback: F) -> Option<Ret>
where
F: Fn(&Arc<UnownedWindow>) -> Ret,
{
let mut deleted = false;
let window_id = WindowId(window_id as _);
let window_target = Self::window_target(&self.target);
let result = window_target
.windows
.borrow()
.get(&window_id)
.and_then(|window| {
let arc = window.upgrade();
deleted = arc.is_none();
arc
})
.map(|window| callback(&window));
if deleted {
// Garbage collection
window_target.windows.borrow_mut().remove(&window_id);
}
result
}
// NOTE: we avoid `self` to not borrow the entire `self` as not mut.
/// Get the platform window target.
pub fn window_target(window_target: &RootAEL) -> &ActiveEventLoop {
match &window_target.p {
PlatformActiveEventLoop::X(target) => target,
#[cfg(wayland_platform)]
_ => unreachable!(),
}
}
/// Get the platform window target.
pub fn window_target_mut(window_target: &mut RootAEL) -> &mut ActiveEventLoop {
match &mut window_target.p {
PlatformActiveEventLoop::X(target) => target,
#[cfg(wayland_platform)]
_ => unreachable!(),
}
}
fn client_message<T: 'static, F>(&mut self, xev: &XClientMessageEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let atoms = wt.xconn.atoms();
let window = xev.window as xproto::Window;
let window_id = mkwid(window);
if xev.data.get_long(0) as xproto::Atom == wt.wm_delete_window {
let event = Event::WindowEvent {
window_id,
event: WindowEvent::CloseRequested,
};
callback(&self.target, event);
return;
}
if xev.data.get_long(0) as xproto::Atom == wt.net_wm_ping {
let client_msg = xproto::ClientMessageEvent {
response_type: xproto::CLIENT_MESSAGE_EVENT,
format: xev.format as _,
sequence: xev.serial as _,
window: wt.root,
type_: xev.message_type as _,
data: xproto::ClientMessageData::from({
let [a, b, c, d, e]: [c_long; 5] = xev.data.as_longs().try_into().unwrap();
[a as u32, b as u32, c as u32, d as u32, e as u32]
}),
};
wt.xconn
.xcb_connection()
.send_event(
false,
wt.root,
xproto::EventMask::SUBSTRUCTURE_NOTIFY
| xproto::EventMask::SUBSTRUCTURE_REDIRECT,
client_msg.serialize(),
)
.expect_then_ignore_error("Failed to send `ClientMessage` event.");
return;
}
if xev.message_type == atoms[XdndEnter] as c_ulong {
let source_window = xev.data.get_long(0) as xproto::Window;
let flags = xev.data.get_long(1);
let version = flags >> 24;
self.dnd.version = Some(version);
let has_more_types = flags - (flags & (c_long::max_value() - 1)) == 1;
if !has_more_types {
let type_list = vec![
xev.data.get_long(2) as xproto::Atom,
xev.data.get_long(3) as xproto::Atom,
xev.data.get_long(4) as xproto::Atom,
];
self.dnd.type_list = Some(type_list);
} else if let Ok(more_types) = unsafe { self.dnd.get_type_list(source_window) } {
self.dnd.type_list = Some(more_types);
}
return;
}
if xev.message_type == atoms[XdndPosition] as c_ulong {
// This event occurs every time the mouse moves while a file's being dragged
// over our window. We emit HoveredFile in response; while the macOS backend
// does that upon a drag entering, XDND doesn't have access to the actual drop
// data until this event. For parity with other platforms, we only emit
// `HoveredFile` the first time, though if winit's API is later extended to
// supply position updates with `HoveredFile` or another event, implementing
// that here would be trivial.
let source_window = xev.data.get_long(0) as xproto::Window;
// Equivalent to `(x << shift) | y`
// where `shift = mem::size_of::<c_short>() * 8`
// Note that coordinates are in "desktop space", not "window space"
// (in X11 parlance, they're root window coordinates)
//let packed_coordinates = xev.data.get_long(2);
//let shift = mem::size_of::<libc::c_short>() * 8;
//let x = packed_coordinates >> shift;
//let y = packed_coordinates & !(x << shift);
// By our own state flow, `version` should never be `None` at this point.
let version = self.dnd.version.unwrap_or(5);
// Action is specified in versions 2 and up, though we don't need it anyway.
//let action = xev.data.get_long(4);
let accepted = if let Some(ref type_list) = self.dnd.type_list {
type_list.contains(&atoms[TextUriList])
} else {
false
};
if !accepted {
unsafe {
self.dnd
.send_status(window, source_window, DndState::Rejected)
.expect("Failed to send `XdndStatus` message.");
}
self.dnd.reset();
return;
}
self.dnd.source_window = Some(source_window);
if self.dnd.result.is_none() {
let time = if version >= 1 {
xev.data.get_long(3) as xproto::Timestamp
} else {
// In version 0, time isn't specified
x11rb::CURRENT_TIME
};
// Log this timestamp.
wt.xconn.set_timestamp(time);
// This results in the `SelectionNotify` event below
unsafe {
self.dnd.convert_selection(window, time);
}
}
unsafe {
self.dnd
.send_status(window, source_window, DndState::Accepted)
.expect("Failed to send `XdndStatus` message.");
}
return;
}
if xev.message_type == atoms[XdndDrop] as c_ulong {
let (source_window, state) = if let Some(source_window) = self.dnd.source_window {
if let Some(Ok(ref path_list)) = self.dnd.result {
for path in path_list {
let event = Event::WindowEvent {
window_id,
event: WindowEvent::DroppedFile(path.clone()),
};
callback(&self.target, event);
}
}
(source_window, DndState::Accepted)
} else {
// `source_window` won't be part of our DND state if we already rejected the drop in our
// `XdndPosition` handler.
let source_window = xev.data.get_long(0) as xproto::Window;
(source_window, DndState::Rejected)
};
unsafe {
self.dnd
.send_finished(window, source_window, state)
.expect("Failed to send `XdndFinished` message.");
}
self.dnd.reset();
return;
}
if xev.message_type == atoms[XdndLeave] as c_ulong {
self.dnd.reset();
let event = Event::WindowEvent {
window_id,
event: WindowEvent::HoveredFileCancelled,
};
callback(&self.target, event);
}
}
fn selection_notify<T: 'static, F>(&mut self, xev: &XSelectionEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let atoms = wt.xconn.atoms();
let window = xev.requestor as xproto::Window;
let window_id = mkwid(window);
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
if xev.property != atoms[XdndSelection] as c_ulong {
return;
}
// This is where we receive data from drag and drop
self.dnd.result = None;
if let Ok(mut data) = unsafe { self.dnd.read_data(window) } {
let parse_result = self.dnd.parse_data(&mut data);
if let Ok(ref path_list) = parse_result {
for path in path_list {
let event = Event::WindowEvent {
window_id,
event: WindowEvent::HoveredFile(path.clone()),
};
callback(&self.target, event);
}
}
self.dnd.result = Some(parse_result);
}
}
fn configure_notify<T: 'static, F>(&self, xev: &XConfigureEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let xwindow = xev.window as xproto::Window;
let window_id = mkwid(xwindow);
let window = match self.with_window(xwindow, Arc::clone) {
Some(window) => window,
None => return,
};
// So apparently...
// `XSendEvent` (synthetic `ConfigureNotify`) -> position relative to root
// `XConfigureNotify` (real `ConfigureNotify`) -> position relative to parent
// https://tronche.com/gui/x/icccm/sec-4.html#s-4.1.5
// We don't want to send `Moved` when this is false, since then every `Resized`
// (whether the window moved or not) is accompanied by an extraneous `Moved` event
// that has a position relative to the parent window.
let is_synthetic = xev.send_event == xlib::True;
// These are both in physical space.
let new_inner_size = (xev.width as u32, xev.height as u32);
let new_inner_position = (xev.x, xev.y);
let (mut resized, moved) = {
let mut shared_state_lock = window.shared_state_lock();
let resized = util::maybe_change(&mut shared_state_lock.size, new_inner_size);
let moved = if is_synthetic {
util::maybe_change(&mut shared_state_lock.inner_position, new_inner_position)
} else {
// Detect when frame extents change.
// Since this isn't synthetic, as per the notes above, this position is relative to the
// parent window.
let rel_parent = new_inner_position;
if util::maybe_change(&mut shared_state_lock.inner_position_rel_parent, rel_parent)
{
// This ensures we process the next `Moved`.
shared_state_lock.inner_position = None;
// Extra insurance against stale frame extents.
shared_state_lock.frame_extents = None;
}
false
};
(resized, moved)
};
let position = window.shared_state_lock().position;
let new_outer_position = if let (Some(position), false) = (position, moved) {
position
} else {
let mut shared_state_lock = window.shared_state_lock();
// We need to convert client area position to window position.
let frame_extents = shared_state_lock
.frame_extents
.as_ref()
.cloned()
.unwrap_or_else(|| {
let frame_extents = wt.xconn.get_frame_extents_heuristic(xwindow, wt.root);
shared_state_lock.frame_extents = Some(frame_extents.clone());
frame_extents
});
let outer =
frame_extents.inner_pos_to_outer(new_inner_position.0, new_inner_position.1);
shared_state_lock.position = Some(outer);
// Unlock shared state to prevent deadlock in callback below
drop(shared_state_lock);
if moved {
callback(
&self.target,
Event::WindowEvent {
window_id,
event: WindowEvent::Moved(outer.into()),
},
);
}
outer
};
if is_synthetic {
let mut shared_state_lock = window.shared_state_lock();
// If we don't use the existing adjusted value when available, then the user can screw up the
// resizing by dragging across monitors *without* dropping the window.
let (width, height) = shared_state_lock
.dpi_adjusted
.unwrap_or((xev.width as u32, xev.height as u32));
let last_scale_factor = shared_state_lock.last_monitor.scale_factor;
let new_scale_factor = {
let window_rect = util::AaRect::new(new_outer_position, new_inner_size);
let monitor = wt
.xconn
.get_monitor_for_window(Some(window_rect))
.expect("Failed to find monitor for window");
if monitor.is_dummy() {
// Avoid updating monitor using a dummy monitor handle
last_scale_factor
} else {
shared_state_lock.last_monitor = monitor.clone();
monitor.scale_factor
}
};
if last_scale_factor != new_scale_factor {
let (new_width, new_height) = window.adjust_for_dpi(
last_scale_factor,
new_scale_factor,
width,
height,
&shared_state_lock,
);
let old_inner_size = PhysicalSize::new(width, height);
let new_inner_size = PhysicalSize::new(new_width, new_height);
// Unlock shared state to prevent deadlock in callback below
drop(shared_state_lock);
let inner_size = Arc::new(Mutex::new(new_inner_size));
callback(
&self.target,
Event::WindowEvent {
window_id,
event: WindowEvent::ScaleFactorChanged {
scale_factor: new_scale_factor,
inner_size_writer: InnerSizeWriter::new(Arc::downgrade(&inner_size)),
},
},
);
let new_inner_size = *inner_size.lock().unwrap();
drop(inner_size);
if new_inner_size != old_inner_size {
window.request_inner_size_physical(new_inner_size.width, new_inner_size.height);
window.shared_state_lock().dpi_adjusted = Some(new_inner_size.into());
// if the DPI factor changed, force a resize event to ensure the logical
// size is computed with the right DPI factor
resized = true;
}
}
}
// NOTE: Ensure that the lock is dropped before handling the resized and
// sending the event back to user.
let hittest = {
let mut shared_state_lock = window.shared_state_lock();
let hittest = shared_state_lock.cursor_hittest;
// This is a hack to ensure that the DPI adjusted resize is actually
// applied on all WMs. KWin doesn't need this, but Xfwm does. The hack
// should not be run on other WMs, since tiling WMs constrain the window
// size, making the resize fail. This would cause an endless stream of
// XResizeWindow requests, making Xorg, the winit client, and the WM
// consume 100% of CPU.
if let Some(adjusted_size) = shared_state_lock.dpi_adjusted {
if new_inner_size == adjusted_size || !util::wm_name_is_one_of(&["Xfwm4"]) {
// When this finally happens, the event will not be synthetic.
shared_state_lock.dpi_adjusted = None;
} else {
// Unlock shared state to prevent deadlock in callback below
drop(shared_state_lock);
window.request_inner_size_physical(adjusted_size.0, adjusted_size.1);
}
}
hittest
};
// Reload hittest.
if hittest.unwrap_or(false) {
let _ = window.set_cursor_hittest(true);
}
if resized {
callback(
&self.target,
Event::WindowEvent {
window_id,
event: WindowEvent::Resized(new_inner_size.into()),
},
);
}
}
/// This is generally a reliable way to detect when the window manager's been
/// replaced, though this event is only fired by reparenting window managers
/// (which is almost all of them). Failing to correctly update WM info doesn't
/// really have much impact, since on the WMs affected (xmonad, dwm, etc.) the only
/// effect is that we waste some time trying to query unsupported properties.
fn reparent_notify(&self, xev: &XReparentEvent) {
let wt = Self::window_target(&self.target);
wt.xconn.update_cached_wm_info(wt.root);
self.with_window(xev.window as xproto::Window, |window| {
window.invalidate_cached_frame_extents();
});
}
fn map_notify<T: 'static, F>(&self, xev: &XMapEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let window = xev.window as xproto::Window;
let window_id = mkwid(window);
// NOTE: Re-issue the focus state when mapping the window.
//
// The purpose of it is to deliver initial focused state of the newly created
// window, given that we can't rely on `CreateNotify`, due to it being not
// sent.
let focus = self
.with_window(window, |window| window.has_focus())
.unwrap_or_default();
let event = Event::WindowEvent {
window_id,
event: WindowEvent::Focused(focus),
};
callback(&self.target, event);
}
fn destroy_notify<T: 'static, F>(&self, xev: &XDestroyWindowEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let window = xev.window as xproto::Window;
let window_id = mkwid(window);
// In the event that the window's been destroyed without being dropped first, we
// cleanup again here.
wt.windows.borrow_mut().remove(&WindowId(window as _));
// Since all XIM stuff needs to happen from the same thread, we destroy the input
// context here instead of when dropping the window.
if let Some(ime) = wt.ime.as_ref() {
ime.borrow_mut()
.remove_context(window as XWindow)
.expect("Failed to destroy input context");
}
callback(
&self.target,
Event::WindowEvent {
window_id,
event: WindowEvent::Destroyed,
},
);
}
fn property_notify<T: 'static, F>(&mut self, xev: &XPropertyEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let atoms = wt.x_connection().atoms();
let atom = xev.atom as xproto::Atom;
if atom == xproto::Atom::from(xproto::AtomEnum::RESOURCE_MANAGER)
|| atom == atoms[_XSETTINGS_SETTINGS]
{
self.process_dpi_change(&mut callback);
}
}
fn visibility_notify<T: 'static, F>(&self, xev: &XVisibilityEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let xwindow = xev.window as xproto::Window;
let event = Event::WindowEvent {
window_id: mkwid(xwindow),
event: WindowEvent::Occluded(xev.state == xlib::VisibilityFullyObscured),
};
callback(&self.target, event);
self.with_window(xwindow, |window| {
window.visibility_notify();
});
}
fn expose<T: 'static, F>(&self, xev: &XExposeEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
// Multiple Expose events may be received for subareas of a window.
// We issue `RedrawRequested` only for the last event of such a series.
if xev.count == 0 {
let window = xev.window as xproto::Window;
let window_id = mkwid(window);
let event = Event::WindowEvent {
window_id,
event: WindowEvent::RedrawRequested,
};
callback(&self.target, event);
}
}
fn xinput_key_input<T: 'static, F>(
&mut self,
xev: &mut XKeyEvent,
state: ElementState,
mut callback: F,
) where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
let window = match self.active_window {
Some(window) => window,
None => return,
};
let window_id = mkwid(window);
let device_id = mkdid(util::VIRTUAL_CORE_KEYBOARD);
let keycode = xev.keycode as _;
// Update state to track key repeats and determine whether this key was a repeat.
//
// Note, when a key is held before focusing on this window the first
// (non-synthetic) event will not be flagged as a repeat (also note that the
// synthetic press event that is generated before this when the window gains focus
// will also not be flagged as a repeat).
//
// Only keys that can repeat should change the held_key_press state since a
// continuously held repeatable key may continue repeating after the press of a
// non-repeatable key.
let key_repeats = self
.xkb_context
.keymap_mut()
.map(|k| k.key_repeats(keycode))
.unwrap_or(false);
let repeat = if key_repeats {
let is_latest_held = self.held_key_press == Some(keycode);
if state == ElementState::Pressed {
self.held_key_press = Some(keycode);
is_latest_held
} else {
// Check that the released key is the latest repeatable key that has been
// pressed, since repeats will continue for the latest key press if a
// different previously pressed key is released.
if is_latest_held {
self.held_key_press = None;
}
false
}
} else {
false
};
// Always update the modifiers.
self.udpate_mods_from_core_event(xev.state as u16, &mut callback);
if keycode != 0 && !self.is_composing {
if let Some(mut key_processor) = self.xkb_context.key_context() {
let event = key_processor.process_key_event(keycode, state, repeat);
let event = Event::WindowEvent {
window_id,
event: WindowEvent::KeyboardInput {
device_id,
event,
is_synthetic: false,
},
};
callback(&self.target, event);
}
return;
}
let wt = Self::window_target(&self.target);
if let Some(ic) = wt
.ime
.as_ref()
.and_then(|ime| ime.borrow().get_context(window as XWindow))
{
let written = wt.xconn.lookup_utf8(ic, xev);
if !written.is_empty() {
let event = Event::WindowEvent {
window_id,
event: WindowEvent::Ime(Ime::Preedit(String::new(), None)),
};
callback(&self.target, event);
let event = Event::WindowEvent {
window_id,
event: WindowEvent::Ime(Ime::Commit(written)),
};
self.is_composing = false;
callback(&self.target, event);
}
}
}
fn xinput2_button_input<T: 'static, F>(
&self,
event: &XIDeviceEvent,
state: ElementState,
mut callback: F,
) where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let window_id = mkwid(event.event as xproto::Window);
let device_id = mkdid(event.deviceid as xinput::DeviceId);
// Set the timestamp.
wt.xconn.set_timestamp(event.time as xproto::Timestamp);
// Deliver multi-touch events instead of emulated mouse events.
if (event.flags & xinput2::XIPointerEmulated) != 0 {
return;
}
let event = match event.detail as u32 {
xlib::Button1 => WindowEvent::MouseInput {
device_id,
state,
button: MouseButton::Left,
},
xlib::Button2 => WindowEvent::MouseInput {
device_id,
state,
button: MouseButton::Middle,
},
xlib::Button3 => WindowEvent::MouseInput {
device_id,
state,
button: MouseButton::Right,
},
// Suppress emulated scroll wheel clicks, since we handle the real motion events for those.
// In practice, even clicky scroll wheels appear to be reported by evdev (and XInput2 in
// turn) as axis motion, so we don't otherwise special-case these button presses.
4..=7 => WindowEvent::MouseWheel {
device_id,
delta: match event.detail {
4 => MouseScrollDelta::LineDelta(0.0, 1.0),
5 => MouseScrollDelta::LineDelta(0.0, -1.0),
6 => MouseScrollDelta::LineDelta(1.0, 0.0),
7 => MouseScrollDelta::LineDelta(-1.0, 0.0),
_ => unreachable!(),
},
phase: TouchPhase::Moved,
},
8 => WindowEvent::MouseInput {
device_id,
state,
button: MouseButton::Back,
},
9 => WindowEvent::MouseInput {
device_id,
state,
button: MouseButton::Forward,
},
x => WindowEvent::MouseInput {
device_id,
state,
button: MouseButton::Other(x as u16),
},
};
let event = Event::WindowEvent { window_id, event };
callback(&self.target, event);
}
fn xinput2_mouse_motion<T: 'static, F>(&self, event: &XIDeviceEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
// Set the timestamp.
wt.xconn.set_timestamp(event.time as xproto::Timestamp);
let device_id = mkdid(event.deviceid as xinput::DeviceId);
let window = event.event as xproto::Window;
let window_id = mkwid(window);
let new_cursor_pos = (event.event_x, event.event_y);
let cursor_moved = self.with_window(window, |window| {
let mut shared_state_lock = window.shared_state_lock();
util::maybe_change(&mut shared_state_lock.cursor_pos, new_cursor_pos)
});
if cursor_moved == Some(true) {
let position = PhysicalPosition::new(event.event_x, event.event_y);
let event = Event::WindowEvent {
window_id,
event: WindowEvent::CursorMoved {
device_id,
position,
},
};
callback(&self.target, event);
} else if cursor_moved.is_none() {
return;
}
// More gymnastics, for self.devices
let mask = unsafe {
slice::from_raw_parts(event.valuators.mask, event.valuators.mask_len as usize)
};
let mut devices = self.devices.borrow_mut();
let physical_device = match devices.get_mut(&DeviceId(event.sourceid as xinput::DeviceId)) {
Some(device) => device,
None => return,
};
let mut events = Vec::new();
let mut value = event.valuators.values;
for i in 0..event.valuators.mask_len * 8 {
if !xinput2::XIMaskIsSet(mask, i) {
continue;
}
let x = unsafe { *value };
let event = if let Some(&mut (_, ref mut info)) = physical_device
.scroll_axes
.iter_mut()
.find(|&&mut (axis, _)| axis == i as _)
{
let delta = (x - info.position) / info.increment;
info.position = x;
// X11 vertical scroll coordinates are opposite to winit's
let delta = match info.orientation {
ScrollOrientation::Horizontal => {
MouseScrollDelta::LineDelta(-delta as f32, 0.0)
}
ScrollOrientation::Vertical => MouseScrollDelta::LineDelta(0.0, -delta as f32),
};
WindowEvent::MouseWheel {
device_id,
delta,
phase: TouchPhase::Moved,
}
} else {
WindowEvent::AxisMotion {
device_id,
axis: i as u32,
value: unsafe { *value },
}
};
events.push(Event::WindowEvent { window_id, event });
value = unsafe { value.offset(1) };
}
for event in events {
callback(&self.target, event);
}
}
fn xinput2_mouse_enter<T: 'static, F>(&self, event: &XIEnterEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
// Set the timestamp.
wt.xconn.set_timestamp(event.time as xproto::Timestamp);
let window = event.event as xproto::Window;
let window_id = mkwid(window);
let device_id = mkdid(event.deviceid as xinput::DeviceId);
if let Some(all_info) = DeviceInfo::get(&wt.xconn, super::ALL_DEVICES.into()) {
let mut devices = self.devices.borrow_mut();
for device_info in all_info.iter() {
if device_info.deviceid == event.sourceid
// This is needed for resetting to work correctly on i3, and
// presumably some other WMs. On those, `XI_Enter` doesn't include
// the physical device ID, so both `sourceid` and `deviceid` are
// the virtual device.
|| device_info.attachment == event.sourceid
{
let device_id = DeviceId(device_info.deviceid as _);
if let Some(device) = devices.get_mut(&device_id) {
device.reset_scroll_position(device_info);
}
}
}
}
if self.window_exists(window) {
let position = PhysicalPosition::new(event.event_x, event.event_y);
let event = Event::WindowEvent {
window_id,
event: WindowEvent::CursorEntered { device_id },
};
callback(&self.target, event);
let event = Event::WindowEvent {
window_id,
event: WindowEvent::CursorMoved {
device_id,
position,
},
};
callback(&self.target, event);
}
}
fn xinput2_mouse_left<T: 'static, F>(&self, event: &XILeaveEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let window = event.event as xproto::Window;
// Set the timestamp.
wt.xconn.set_timestamp(event.time as xproto::Timestamp);
// Leave, FocusIn, and FocusOut can be received by a window that's already
// been destroyed, which the user presumably doesn't want to deal with.
if self.window_exists(window) {
let event = Event::WindowEvent {
window_id: mkwid(window),
event: WindowEvent::CursorLeft {
device_id: mkdid(event.deviceid as xinput::DeviceId),
},
};
callback(&self.target, event);
}
}
fn xinput2_focused<T: 'static, F>(&mut self, xev: &XIFocusInEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let window = xev.event as xproto::Window;
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
if let Some(ime) = wt.ime.as_ref() {
ime.borrow_mut()
.focus(xev.event)
.expect("Failed to focus input context");
}
if self.active_window == Some(window) {
return;
}
self.active_window = Some(window);
wt.update_listen_device_events(true);
let window_id = mkwid(window);
let position = PhysicalPosition::new(xev.event_x, xev.event_y);
if let Some(window) = self.with_window(window, Arc::clone) {
window.shared_state_lock().has_focus = true;
}
let event = Event::WindowEvent {
window_id,
event: WindowEvent::Focused(true),
};
callback(&self.target, event);
// Issue key press events for all pressed keys
Self::handle_pressed_keys(
&self.target,
window_id,
ElementState::Pressed,
&mut self.xkb_context,
&mut callback,
);
if let Some(state) = self.xkb_context.state_mut() {
let mods = state.modifiers().into();
self.send_modifiers(mods, &mut callback);
}
// The deviceid for this event is for a keyboard instead of a pointer,
// so we have to do a little extra work.
let pointer_id = self
.devices
.borrow()
.get(&DeviceId(xev.deviceid as xinput::DeviceId))
.map(|device| device.attachment)
.unwrap_or(2);
let event = Event::WindowEvent {
window_id,
event: WindowEvent::CursorMoved {
device_id: mkdid(pointer_id as _),
position,
},
};
callback(&self.target, event);
}
fn xinput2_unfocused<T: 'static, F>(&mut self, xev: &XIFocusOutEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
let window = xev.event as xproto::Window;
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
if !self.window_exists(window) {
return;
}
if let Some(ime) = wt.ime.as_ref() {
ime.borrow_mut()
.unfocus(xev.event)
.expect("Failed to unfocus input context");
}
if self.active_window.take() == Some(window) {
let window_id = mkwid(window);
wt.update_listen_device_events(false);
self.send_modifiers(ModifiersState::empty(), &mut callback);
// Issue key release events for all pressed keys
Self::handle_pressed_keys(
&self.target,
window_id,
ElementState::Released,
&mut self.xkb_context,
&mut callback,
);
// Clear this so detecting key repeats is consistently handled when the
// window regains focus.
self.held_key_press = None;
if let Some(window) = self.with_window(window, Arc::clone) {
window.shared_state_lock().has_focus = false;
}
let event = Event::WindowEvent {
window_id,
event: WindowEvent::Focused(false),
};
callback(&self.target, event)
}
}
fn xinput2_touch<T: 'static, F>(
&mut self,
xev: &XIDeviceEvent,
phase: TouchPhase,
mut callback: F,
) where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
let window = xev.event as xproto::Window;
if self.window_exists(window) {
let window_id = mkwid(window);
let id = xev.detail as u64;
let location = PhysicalPosition::new(xev.event_x, xev.event_y);
// Mouse cursor position changes when touch events are received.
// Only the first concurrently active touch ID moves the mouse cursor.
if is_first_touch(&mut self.first_touch, &mut self.num_touch, id, phase) {
let event = Event::WindowEvent {
window_id,
event: WindowEvent::CursorMoved {
device_id: mkdid(util::VIRTUAL_CORE_POINTER),
position: location.cast(),
},
};
callback(&self.target, event);
}
let event = Event::WindowEvent {
window_id,
event: WindowEvent::Touch(Touch {
device_id: mkdid(xev.deviceid as xinput::DeviceId),
phase,
location,
force: None, // TODO
id,
}),
};
callback(&self.target, event)
}
}
fn xinput2_raw_button_input<T: 'static, F>(
&self,
xev: &XIRawEvent,
state: ElementState,
mut callback: F,
) where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
if xev.flags & xinput2::XIPointerEmulated == 0 {
let event = Event::DeviceEvent {
device_id: mkdid(xev.deviceid as xinput::DeviceId),
event: DeviceEvent::Button {
state,
button: xev.detail as u32,
},
};
callback(&self.target, event);
}
}
fn xinput2_raw_mouse_motion<T: 'static, F>(&self, xev: &XIRawEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
let did = mkdid(xev.deviceid as xinput::DeviceId);
let mask =
unsafe { slice::from_raw_parts(xev.valuators.mask, xev.valuators.mask_len as usize) };
let mut value = xev.raw_values;
let mut mouse_delta = (0.0, 0.0);
let mut scroll_delta = (0.0, 0.0);
for i in 0..xev.valuators.mask_len * 8 {
if !xinput2::XIMaskIsSet(mask, i) {
continue;
}
let x = unsafe { *value };
// We assume that every XInput2 device with analog axes is a pointing device emitting
// relative coordinates.
match i {
0 => mouse_delta.0 = x,
1 => mouse_delta.1 = x,
2 => scroll_delta.0 = x as f32,
3 => scroll_delta.1 = x as f32,
_ => {}
}
let event = Event::DeviceEvent {
device_id: did,
event: DeviceEvent::Motion {
axis: i as u32,
value: x,
},
};
callback(&self.target, event);
value = unsafe { value.offset(1) };
}
if mouse_delta != (0.0, 0.0) {
let event = Event::DeviceEvent {
device_id: did,
event: DeviceEvent::MouseMotion { delta: mouse_delta },
};
callback(&self.target, event);
}
if scroll_delta != (0.0, 0.0) {
let event = Event::DeviceEvent {
device_id: did,
event: DeviceEvent::MouseWheel {
delta: MouseScrollDelta::LineDelta(scroll_delta.0, scroll_delta.1),
},
};
callback(&self.target, event);
}
}
fn xinput2_raw_key_input<T: 'static, F>(
&mut self,
xev: &XIRawEvent,
state: ElementState,
mut callback: F,
) where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
let device_id = mkdid(xev.sourceid as xinput::DeviceId);
let keycode = xev.detail as u32;
if keycode < KEYCODE_OFFSET as u32 {
return;
}
let physical_key = xkb::raw_keycode_to_physicalkey(keycode);
callback(
&self.target,
Event::DeviceEvent {
device_id,
event: DeviceEvent::Key(RawKeyEvent {
physical_key,
state,
}),
},
);
}
fn xinput2_hierarchy_changed<T: 'static, F>(&mut self, xev: &XIHierarchyEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
let infos = unsafe { slice::from_raw_parts(xev.info, xev.num_info as usize) };
for info in infos {
if 0 != info.flags & (xinput2::XISlaveAdded | xinput2::XIMasterAdded) {
self.init_device(info.deviceid as xinput::DeviceId);
callback(
&self.target,
Event::DeviceEvent {
device_id: mkdid(info.deviceid as xinput::DeviceId),
event: DeviceEvent::Added,
},
);
} else if 0 != info.flags & (xinput2::XISlaveRemoved | xinput2::XIMasterRemoved) {
callback(
&self.target,
Event::DeviceEvent {
device_id: mkdid(info.deviceid as xinput::DeviceId),
event: DeviceEvent::Removed,
},
);
let mut devices = self.devices.borrow_mut();
devices.remove(&DeviceId(info.deviceid as xinput::DeviceId));
}
}
}
fn xkb_event<T: 'static, F>(&mut self, xev: &XkbAnyEvent, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
match xev.xkb_type {
xlib::XkbNewKeyboardNotify => {
let xev = unsafe { &*(xev as *const _ as *const xlib::XkbNewKeyboardNotifyEvent) };
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
let keycodes_changed_flag = 0x1;
let geometry_changed_flag = 0x1 << 1;
let keycodes_changed = util::has_flag(xev.changed, keycodes_changed_flag);
let geometry_changed = util::has_flag(xev.changed, geometry_changed_flag);
if xev.device == self.xkb_context.core_keyboard_id
&& (keycodes_changed || geometry_changed)
{
let xcb = wt.xconn.xcb_connection().get_raw_xcb_connection();
self.xkb_context.set_keymap_from_x11(xcb);
if let Some(state) = self.xkb_context.state_mut() {
let mods = state.modifiers().into();
self.send_modifiers(mods, &mut callback);
}
}
}
xlib::XkbMapNotify => {
let xcb = wt.xconn.xcb_connection().get_raw_xcb_connection();
self.xkb_context.set_keymap_from_x11(xcb);
if let Some(state) = self.xkb_context.state_mut() {
let mods = state.modifiers().into();
self.send_modifiers(mods, &mut callback);
}
}
xlib::XkbStateNotify => {
let xev = unsafe { &*(xev as *const _ as *const xlib::XkbStateNotifyEvent) };
// Set the timestamp.
wt.xconn.set_timestamp(xev.time as xproto::Timestamp);
if let Some(state) = self.xkb_context.state_mut() {
state.update_modifiers(
xev.base_mods,
xev.latched_mods,
xev.locked_mods,
xev.base_group as u32,
xev.latched_group as u32,
xev.locked_group as u32,
);
let mods = state.modifiers().into();
self.send_modifiers(mods, &mut callback);
}
}
_ => {}
}
}
pub fn update_mods_from_xinput2_event<T: 'static, F>(
&mut self,
mods: &XIModifierState,
group: &XIModifierState,
mut callback: F,
) where
F: FnMut(&RootAEL, Event<T>),
{
if let Some(state) = self.xkb_context.state_mut() {
state.update_modifiers(
mods.base as u32,
mods.latched as u32,
mods.locked as u32,
group.base as u32,
group.latched as u32,
group.locked as u32,
);
let mods = state.modifiers();
self.send_modifiers(mods.into(), &mut callback);
}
}
pub fn udpate_mods_from_core_event<T: 'static, F>(&mut self, state: u16, mut callback: F)
where
F: FnMut(&RootAEL, Event<T>),
{
let xkb_mask = self.xkb_mod_mask_from_core(state);
let xkb_state = match self.xkb_context.state_mut() {
Some(xkb_state) => xkb_state,
None => return,
};
// NOTE: this is inspired by Qt impl.
let mut depressed = xkb_state.depressed_modifiers() & xkb_mask;
let latched = xkb_state.latched_modifiers() & xkb_mask;
let locked = xkb_state.locked_modifiers() & xkb_mask;
// Set modifiers in depressed if they don't appear in any of the final masks.
depressed |= !(depressed | latched | locked) & xkb_mask;
xkb_state.update_modifiers(
depressed,
latched,
locked,
0,
0,
// Bits 13 and 14 report the state keyboard group.
((state >> 13) & 3) as u32,
);
let mods = xkb_state.modifiers();
self.send_modifiers(mods.into(), &mut callback);
}
pub fn xkb_mod_mask_from_core(&mut self, state: u16) -> xkb_mod_mask_t {
let mods_indices = match self.xkb_context.keymap_mut() {
Some(keymap) => keymap.mods_indices(),
None => return 0,
};
// Build the XKB modifiers from the regular state.
let mut depressed = 0u32;
if let Some(shift) = mods_indices
.shift
.filter(|_| ModMask::SHIFT.intersects(state))
{
depressed |= 1 << shift;
}
if let Some(caps) = mods_indices
.caps
.filter(|_| ModMask::LOCK.intersects(state))
{
depressed |= 1 << caps;
}
if let Some(ctrl) = mods_indices
.ctrl
.filter(|_| ModMask::CONTROL.intersects(state))
{
depressed |= 1 << ctrl;
}
if let Some(alt) = mods_indices.alt.filter(|_| ModMask::M1.intersects(state)) {
depressed |= 1 << alt;
}
if let Some(num) = mods_indices.num.filter(|_| ModMask::M2.intersects(state)) {
depressed |= 1 << num;
}
if let Some(mod3) = mods_indices.mod3.filter(|_| ModMask::M3.intersects(state)) {
depressed |= 1 << mod3;
}
if let Some(logo) = mods_indices.logo.filter(|_| ModMask::M4.intersects(state)) {
depressed |= 1 << logo;
}
if let Some(mod5) = mods_indices.mod5.filter(|_| ModMask::M5.intersects(state)) {
depressed |= 1 << mod5;
}
depressed
}
/// Send modifiers for the active window.
///
/// The event won't be sent when the `modifiers` match the previously `sent` modifiers value.
fn send_modifiers<T: 'static, F: FnMut(&RootAEL, Event<T>)>(
&self,
modifiers: ModifiersState,
callback: &mut F,
) {
let window_id = match self.active_window {
Some(window) => mkwid(window),
None => return,
};
if self.modifiers.replace(modifiers) != modifiers {
callback(
&self.target,
Event::WindowEvent {
window_id,
event: WindowEvent::ModifiersChanged(self.modifiers.get().into()),
},
);
}
}
fn handle_pressed_keys<T: 'static, F>(
target: &RootAEL,
window_id: crate::window::WindowId,
state: ElementState,
xkb_context: &mut Context,
callback: &mut F,
) where
F: FnMut(&RootAEL, Event<T>),
{
let device_id = mkdid(util::VIRTUAL_CORE_KEYBOARD);
// Update modifiers state and emit key events based on which keys are currently pressed.
let window_target = Self::window_target(target);
let xcb = window_target
.xconn
.xcb_connection()
.get_raw_xcb_connection();
let keymap = match xkb_context.keymap_mut() {
Some(keymap) => keymap,
None => return,
};
// Send the keys using the sythetic state to not alter the main state.
let mut xkb_state = match XkbState::new_x11(xcb, keymap) {
Some(xkb_state) => xkb_state,
None => return,
};
let mut key_processor = match xkb_context.key_context_with_state(&mut xkb_state) {
Some(key_processor) => key_processor,
None => return,
};
for keycode in window_target
.xconn
.query_keymap()
.into_iter()
.filter(|k| *k >= KEYCODE_OFFSET)
{
let event = key_processor.process_key_event(keycode as u32, state, false);
let event = Event::WindowEvent {
window_id,
event: WindowEvent::KeyboardInput {
device_id,
event,
is_synthetic: true,
},
};
callback(target, event);
}
}
fn process_dpi_change<T: 'static, F>(&self, callback: &mut F)
where
F: FnMut(&RootAEL, Event<T>),
{
let wt = Self::window_target(&self.target);
wt.xconn
.reload_database()
.expect("failed to reload Xft database");
// In the future, it would be quite easy to emit monitor hotplug events.
let prev_list = {
let prev_list = wt.xconn.invalidate_cached_monitor_list();
match prev_list {
Some(prev_list) => prev_list,
None => return,
}
};
let new_list = wt
.xconn
.available_monitors()
.expect("Failed to get monitor list");
for new_monitor in new_list {
// Previous list may be empty, in case of disconnecting and
// reconnecting the only one monitor. We still need to emit events in
// this case.
let maybe_prev_scale_factor = prev_list
.iter()
.find(|prev_monitor| prev_monitor.name == new_monitor.name)
.map(|prev_monitor| prev_monitor.scale_factor);
if Some(new_monitor.scale_factor) != maybe_prev_scale_factor {
for window in wt.windows.borrow().iter().filter_map(|(_, w)| w.upgrade()) {
window.refresh_dpi_for_monitor(&new_monitor, maybe_prev_scale_factor, |event| {
callback(&self.target, event);
})
}
}
}
}
fn window_exists(&self, window_id: xproto::Window) -> bool {
self.with_window(window_id, |_| ()).is_some()
}
}
fn is_first_touch(first: &mut Option<u64>, num: &mut u32, id: u64, phase: TouchPhase) -> bool {
match phase {
TouchPhase::Started => {
if *num == 0 {
*first = Some(id);
}
*num += 1;
}
TouchPhase::Cancelled | TouchPhase::Ended => {
if *first == Some(id) {
*first = None;
}
*num = num.saturating_sub(1);
}
_ => (),
}
*first == Some(id)
}
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