winit-sonoma-fix/src/platform_impl/macos/app_state.rs
2019-12-22 11:17:23 -05:00

307 lines
10 KiB
Rust

use std::{
collections::VecDeque,
fmt::{self, Debug},
hint::unreachable_unchecked,
mem,
rc::Rc,
sync::{
atomic::{AtomicBool, Ordering},
Mutex, MutexGuard,
},
time::Instant,
};
use cocoa::{appkit::NSApp, base::nil, foundation::NSString};
use crate::{
event::{Event, StartCause, WindowEvent},
event_loop::{ControlFlow, EventLoopWindowTarget as RootWindowTarget},
platform_impl::platform::{observer::EventLoopWaker, util::Never},
window::WindowId,
};
use objc::runtime::Object;
lazy_static! {
static ref HANDLER: Handler = Default::default();
}
impl Event<Never> {
fn userify<T: 'static>(self) -> Event<T> {
self.map_nonuser_event()
// `Never` can't be constructed, so the `UserEvent` variant can't
// be present here.
.unwrap_or_else(|_| unsafe { unreachable_unchecked() })
}
}
pub trait EventHandler: Debug {
fn handle_nonuser_event(&mut self, event: Event<Never>, control_flow: &mut ControlFlow);
fn handle_user_events(&mut self, control_flow: &mut ControlFlow);
}
struct EventLoopHandler<T: 'static> {
callback: Box<dyn FnMut(Event<T>, &RootWindowTarget<T>, &mut ControlFlow)>,
will_exit: bool,
window_target: Rc<RootWindowTarget<T>>,
}
impl<T> Debug for EventLoopHandler<T> {
fn fmt(&self, formatter: &mut fmt::Formatter<'_>) -> fmt::Result {
formatter
.debug_struct("EventLoopHandler")
.field("window_target", &self.window_target)
.finish()
}
}
impl<T> EventHandler for EventLoopHandler<T> {
fn handle_nonuser_event(&mut self, event: Event<Never>, control_flow: &mut ControlFlow) {
(self.callback)(event.userify(), &self.window_target, control_flow);
self.will_exit |= *control_flow == ControlFlow::Exit;
if self.will_exit {
*control_flow = ControlFlow::Exit;
}
}
fn handle_user_events(&mut self, control_flow: &mut ControlFlow) {
let mut will_exit = self.will_exit;
for event in self.window_target.p.receiver.try_iter() {
(self.callback)(Event::UserEvent(event), &self.window_target, control_flow);
will_exit |= *control_flow == ControlFlow::Exit;
if will_exit {
*control_flow = ControlFlow::Exit;
}
}
self.will_exit = will_exit;
}
}
#[derive(Default)]
struct Handler {
ready: AtomicBool,
in_callback: AtomicBool,
control_flow: Mutex<ControlFlow>,
control_flow_prev: Mutex<ControlFlow>,
start_time: Mutex<Option<Instant>>,
callback: Mutex<Option<Box<dyn EventHandler>>>,
pending_events: Mutex<VecDeque<Event<Never>>>,
pending_redraw: Mutex<Vec<WindowId>>,
waker: Mutex<EventLoopWaker>,
}
unsafe impl Send for Handler {}
unsafe impl Sync for Handler {}
impl Handler {
fn events<'a>(&'a self) -> MutexGuard<'a, VecDeque<Event<Never>>> {
self.pending_events.lock().unwrap()
}
fn redraw<'a>(&'a self) -> MutexGuard<'a, Vec<WindowId>> {
self.pending_redraw.lock().unwrap()
}
fn waker<'a>(&'a self) -> MutexGuard<'a, EventLoopWaker> {
self.waker.lock().unwrap()
}
fn is_ready(&self) -> bool {
self.ready.load(Ordering::Acquire)
}
fn set_ready(&self) {
self.ready.store(true, Ordering::Release);
}
fn should_exit(&self) -> bool {
*self.control_flow.lock().unwrap() == ControlFlow::Exit
}
fn get_control_flow_and_update_prev(&self) -> ControlFlow {
let control_flow = self.control_flow.lock().unwrap();
*self.control_flow_prev.lock().unwrap() = *control_flow;
*control_flow
}
fn get_old_and_new_control_flow(&self) -> (ControlFlow, ControlFlow) {
let old = *self.control_flow_prev.lock().unwrap();
let new = *self.control_flow.lock().unwrap();
(old, new)
}
fn get_start_time(&self) -> Option<Instant> {
*self.start_time.lock().unwrap()
}
fn update_start_time(&self) {
*self.start_time.lock().unwrap() = Some(Instant::now());
}
fn take_events(&self) -> VecDeque<Event<Never>> {
mem::replace(&mut *self.events(), Default::default())
}
fn should_redraw(&self) -> Vec<WindowId> {
mem::replace(&mut *self.redraw(), Default::default())
}
fn get_in_callback(&self) -> bool {
self.in_callback.load(Ordering::Acquire)
}
fn set_in_callback(&self, in_callback: bool) {
self.in_callback.store(in_callback, Ordering::Release);
}
fn handle_nonuser_event(&self, event: Event<Never>) {
if let Some(ref mut callback) = *self.callback.lock().unwrap() {
callback.handle_nonuser_event(event, &mut *self.control_flow.lock().unwrap());
}
}
fn handle_user_events(&self) {
if let Some(ref mut callback) = *self.callback.lock().unwrap() {
callback.handle_user_events(&mut *self.control_flow.lock().unwrap());
}
}
}
pub enum AppState {}
impl AppState {
// This function extends lifetime of `callback` to 'static as its side effect
pub unsafe fn set_callback<F, T>(callback: F, window_target: Rc<RootWindowTarget<T>>)
where
F: FnMut(Event<T>, &RootWindowTarget<T>, &mut ControlFlow),
{
*HANDLER.callback.lock().unwrap() = Some(Box::new(EventLoopHandler {
// This transmute is always safe, in case it was reached through `run`, since our
// lifetime will be already 'static. In other cases caller should ensure that all data
// they passed to callback will actually outlive it, some apps just can't move
// everything to event loop, so this is something that they should care about.
callback: mem::transmute::<
Box<dyn FnMut(Event<T>, &RootWindowTarget<T>, &mut ControlFlow)>,
Box<dyn FnMut(Event<T>, &RootWindowTarget<T>, &mut ControlFlow)>,
>(Box::new(callback)),
will_exit: false,
window_target,
}));
}
pub fn exit() {
HANDLER.set_in_callback(true);
HANDLER.handle_nonuser_event(Event::LoopDestroyed);
HANDLER.set_in_callback(false);
HANDLER.callback.lock().unwrap().take();
}
pub fn launched() {
HANDLER.set_ready();
HANDLER.waker().start();
HANDLER.set_in_callback(true);
HANDLER.handle_nonuser_event(Event::NewEvents(StartCause::Init));
HANDLER.set_in_callback(false);
}
pub fn wakeup() {
if !HANDLER.is_ready() {
return;
}
let start = HANDLER.get_start_time().unwrap();
let cause = match HANDLER.get_control_flow_and_update_prev() {
ControlFlow::Poll => StartCause::Poll,
ControlFlow::Wait => StartCause::WaitCancelled {
start,
requested_resume: None,
},
ControlFlow::WaitUntil(requested_resume) => {
if Instant::now() >= requested_resume {
StartCause::ResumeTimeReached {
start,
requested_resume,
}
} else {
StartCause::WaitCancelled {
start,
requested_resume: Some(requested_resume),
}
}
}
ControlFlow::Exit => StartCause::Poll, //panic!("unexpected `ControlFlow::Exit`"),
};
HANDLER.set_in_callback(true);
HANDLER.handle_nonuser_event(Event::NewEvents(cause));
HANDLER.set_in_callback(false);
}
// This is called from multiple threads at present
pub fn queue_redraw(window_id: WindowId) {
let mut pending_redraw = HANDLER.redraw();
if !pending_redraw.contains(&window_id) {
pending_redraw.push(window_id);
}
}
pub fn queue_event(event: Event<Never>) {
if !unsafe { msg_send![class!(NSThread), isMainThread] } {
panic!("Event queued from different thread: {:#?}", event);
}
HANDLER.events().push_back(event);
}
pub fn queue_events(mut events: VecDeque<Event<Never>>) {
if !unsafe { msg_send![class!(NSThread), isMainThread] } {
panic!("Events queued from different thread: {:#?}", events);
}
HANDLER.events().append(&mut events);
}
pub fn cleared() {
if !HANDLER.is_ready() {
return;
}
if !HANDLER.get_in_callback() {
HANDLER.set_in_callback(true);
HANDLER.handle_user_events();
for event in HANDLER.take_events() {
HANDLER.handle_nonuser_event(event);
}
HANDLER.handle_nonuser_event(Event::MainEventsCleared);
for window_id in HANDLER.should_redraw() {
HANDLER.handle_nonuser_event(Event::RedrawRequested(window_id));
}
HANDLER.handle_nonuser_event(Event::RedrawEventsCleared);
HANDLER.set_in_callback(false);
}
if HANDLER.should_exit() {
unsafe {
let _: () = msg_send![NSApp(), stop: nil];
let windows: *const Object = msg_send![NSApp(), windows];
let window: *const Object = msg_send![windows, objectAtIndex:0];
assert_ne!(window, nil);
let title: *const Object = msg_send![window, title];
assert_ne!(title, nil);
let postfix = NSString::alloc(nil).init_str("*");
let some_unique_title: *const Object =
msg_send![title, stringByAppendingString: postfix];
assert_ne!(some_unique_title, nil);
// To stop event loop immediately, we need to send some UI event here.
let _: () = msg_send![window, setTitle: some_unique_title];
// And restore it.
let _: () = msg_send![window, setTitle: title];
};
}
HANDLER.update_start_time();
match HANDLER.get_old_and_new_control_flow() {
(ControlFlow::Exit, _) | (_, ControlFlow::Exit) => (),
(old, new) if old == new => (),
(_, ControlFlow::Wait) => HANDLER.waker().stop(),
(_, ControlFlow::WaitUntil(instant)) => HANDLER.waker().start_at(instant),
(_, ControlFlow::Poll) => HANDLER.waker().start(),
}
}
}