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59b1eb54103ace8ed47f41bb2a30d8fccf547c70
winit/src/platform_impl/windows/event_loop.rs
Kirill Chibisov 59b1eb5410 api: make OwnedDisplayHandle wrap an opaque type 
This will help in case we want to linger the event loop during drop
to prevent use after free in the consumers code.
2024-11-13 15:29:05 +03:00

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#![allow(non_snake_case)]
mod runner;
use std::cell::Cell;
use std::ffi::c_void;
use std::os::windows::io::{AsRawHandle as _, FromRawHandle as _, OwnedHandle, RawHandle};
use std::rc::Rc;
use std::sync::atomic::{AtomicU32, Ordering};
use std::sync::{Arc, Mutex, MutexGuard};
use std::time::{Duration, Instant};
use std::{mem, panic, ptr};
use runner::EventLoopRunner;
use windows_sys::Win32::Devices::HumanInterfaceDevice::MOUSE_MOVE_RELATIVE;
use windows_sys::Win32::Foundation::{
GetLastError, FALSE, HANDLE, HWND, LPARAM, LRESULT, POINT, RECT, WAIT_FAILED, WPARAM,
};
use windows_sys::Win32::Graphics::Gdi::{
GetMonitorInfoW, MonitorFromRect, MonitorFromWindow, RedrawWindow, ScreenToClient,
ValidateRect, MONITORINFO, MONITOR_DEFAULTTONULL, RDW_INTERNALPAINT, SC_SCREENSAVE,
};
use windows_sys::Win32::System::Ole::RevokeDragDrop;
use windows_sys::Win32::System::Threading::{
CreateWaitableTimerExW, GetCurrentThreadId, SetWaitableTimer,
CREATE_WAITABLE_TIMER_HIGH_RESOLUTION, INFINITE, TIMER_ALL_ACCESS,
};
use windows_sys::Win32::UI::Controls::{HOVER_DEFAULT, WM_MOUSELEAVE};
use windows_sys::Win32::UI::Input::Ime::{GCS_COMPSTR, GCS_RESULTSTR, ISC_SHOWUICOMPOSITIONWINDOW};
use windows_sys::Win32::UI::Input::KeyboardAndMouse::{
ReleaseCapture, SetCapture, TrackMouseEvent, TME_LEAVE, TRACKMOUSEEVENT,
};
use windows_sys::Win32::UI::Input::Pointer::{
POINTER_FLAG_DOWN, POINTER_FLAG_PRIMARY, POINTER_FLAG_UP, POINTER_FLAG_UPDATE,
};
use windows_sys::Win32::UI::Input::Touch::{
CloseTouchInputHandle, GetTouchInputInfo, TOUCHEVENTF_DOWN, TOUCHEVENTF_MOVE,
TOUCHEVENTF_PRIMARY, TOUCHEVENTF_UP, TOUCHINPUT,
};
use windows_sys::Win32::UI::Input::{RAWINPUT, RIM_TYPEKEYBOARD, RIM_TYPEMOUSE};
use windows_sys::Win32::UI::WindowsAndMessaging::{
CreateWindowExW, DefWindowProcW, DestroyWindow, DispatchMessageW, GetClientRect, GetCursorPos,
GetMenu, LoadCursorW, MsgWaitForMultipleObjectsEx, PeekMessageW, PostMessageW,
RegisterClassExW, RegisterWindowMessageA, SetCursor, SetWindowPos, TranslateMessage,
CREATESTRUCTW, GWL_STYLE, GWL_USERDATA, HTCAPTION, HTCLIENT, MINMAXINFO, MNC_CLOSE, MSG,
MWMO_INPUTAVAILABLE, NCCALCSIZE_PARAMS, PM_REMOVE, PT_TOUCH, QS_ALLEVENTS, RI_MOUSE_HWHEEL,
RI_MOUSE_WHEEL, SC_MINIMIZE, SC_RESTORE, SIZE_MAXIMIZED, SWP_NOACTIVATE, SWP_NOMOVE,
SWP_NOSIZE, SWP_NOZORDER, WHEEL_DELTA, WINDOWPOS, WMSZ_BOTTOM, WMSZ_BOTTOMLEFT,
WMSZ_BOTTOMRIGHT, WMSZ_LEFT, WMSZ_RIGHT, WMSZ_TOP, WMSZ_TOPLEFT, WMSZ_TOPRIGHT,
WM_CAPTURECHANGED, WM_CLOSE, WM_CREATE, WM_DESTROY, WM_DPICHANGED, WM_ENTERSIZEMOVE,
WM_EXITSIZEMOVE, WM_GETMINMAXINFO, WM_IME_COMPOSITION, WM_IME_ENDCOMPOSITION,
WM_IME_SETCONTEXT, WM_IME_STARTCOMPOSITION, WM_INPUT, WM_KEYDOWN, WM_KEYUP, WM_KILLFOCUS,
WM_LBUTTONDOWN, WM_LBUTTONUP, WM_MBUTTONDOWN, WM_MBUTTONUP, WM_MENUCHAR, WM_MOUSEHWHEEL,
WM_MOUSEMOVE, WM_MOUSEWHEEL, WM_NCACTIVATE, WM_NCCALCSIZE, WM_NCCREATE, WM_NCDESTROY,
WM_NCLBUTTONDOWN, WM_PAINT, WM_POINTERDOWN, WM_POINTERUP, WM_POINTERUPDATE, WM_RBUTTONDOWN,
WM_RBUTTONUP, WM_SETCURSOR, WM_SETFOCUS, WM_SETTINGCHANGE, WM_SIZE, WM_SIZING, WM_SYSCOMMAND,
WM_SYSKEYDOWN, WM_SYSKEYUP, WM_TOUCH, WM_WINDOWPOSCHANGED, WM_WINDOWPOSCHANGING,
WM_XBUTTONDOWN, WM_XBUTTONUP, WNDCLASSEXW, WS_EX_LAYERED, WS_EX_NOACTIVATE, WS_EX_TOOLWINDOW,
WS_EX_TRANSPARENT, WS_OVERLAPPED, WS_POPUP, WS_VISIBLE,
};
use super::window::set_skip_taskbar;
use super::SelectedCursor;
use crate::application::ApplicationHandler;
use crate::dpi::{PhysicalPosition, PhysicalSize};
use crate::error::{EventLoopError, RequestError};
use crate::event::{
Event, FingerId, Force, Ime, RawKeyEvent, SurfaceSizeWriter, TouchPhase, WindowEvent,
};
use crate::event_loop::{
ActiveEventLoop as RootActiveEventLoop, ControlFlow, DeviceEvents,
EventLoopProxy as RootEventLoopProxy, EventLoopProxyProvider,
OwnedDisplayHandle as CoreOwnedDisplayHandle,
};
use crate::keyboard::ModifiersState;
use crate::monitor::MonitorHandle as RootMonitorHandle;
use crate::platform::pump_events::PumpStatus;
use crate::platform_impl::platform::dark_mode::try_theme;
use crate::platform_impl::platform::dpi::{become_dpi_aware, dpi_to_scale_factor};
use crate::platform_impl::platform::drop_handler::FileDropHandler;
use crate::platform_impl::platform::icon::WinCursor;
use crate::platform_impl::platform::ime::ImeContext;
use crate::platform_impl::platform::keyboard::KeyEventBuilder;
use crate::platform_impl::platform::keyboard_layout::LAYOUT_CACHE;
use crate::platform_impl::platform::monitor::{self, MonitorHandle};
use crate::platform_impl::platform::window::InitData;
use crate::platform_impl::platform::window_state::{
CursorFlags, ImeState, WindowFlags, WindowState,
};
use crate::platform_impl::platform::{raw_input, util, wrap_device_id, Fullscreen};
use crate::platform_impl::Window;
use crate::utils::Lazy;
use crate::window::{
CustomCursor as RootCustomCursor, CustomCursorSource, Theme, Window as CoreWindow,
WindowAttributes, WindowId,
};
pub(crate) struct WindowData {
pub window_state: Arc<Mutex<WindowState>>,
pub event_loop_runner: Rc<EventLoopRunner>,
pub key_event_builder: KeyEventBuilder,
pub _file_drop_handler: Option<FileDropHandler>,
pub userdata_removed: Cell<bool>,
pub recurse_depth: Cell<u32>,
}
impl WindowData {
fn send_event(&self, event: Event) {
self.event_loop_runner.send_event(event);
}
fn window_state_lock(&self) -> MutexGuard<'_, WindowState> {
self.window_state.lock().unwrap()
}
}
struct ThreadMsgTargetData {
event_loop_runner: Rc<EventLoopRunner>,
}
impl ThreadMsgTargetData {
fn send_event(&self, event: Event) {
self.event_loop_runner.send_event(event);
}
}
/// The result of a subclass procedure (the message handling callback)
#[derive(Clone, Copy)]
pub(crate) enum ProcResult {
DefWindowProc(WPARAM),
Value(isize),
}
pub struct EventLoop {
window_target: ActiveEventLoop,
msg_hook: Option<Box<dyn FnMut(*const c_void) -> bool + 'static>>,
// It is a timer used on timed waits.
// It is created lazily in case if we have `ControlFlow::WaitUntil`.
// Keep it as a field to avoid recreating it on every `ControlFlow::WaitUntil`.
high_resolution_timer: Option<OwnedHandle>,
}
pub(crate) struct PlatformSpecificEventLoopAttributes {
pub(crate) any_thread: bool,
pub(crate) dpi_aware: bool,
pub(crate) msg_hook: Option<Box<dyn FnMut(*const c_void) -> bool + 'static>>,
}
impl Default for PlatformSpecificEventLoopAttributes {
fn default() -> Self {
Self { any_thread: false, dpi_aware: true, msg_hook: None }
}
}
impl PartialEq for PlatformSpecificEventLoopAttributes {
fn eq(&self, other: &Self) -> bool {
self.any_thread.eq(&other.any_thread)
&& self.dpi_aware.eq(&other.dpi_aware)
&& match (&self.msg_hook, &other.msg_hook) {
(Some(this), Some(other)) => std::ptr::eq(&this, &other),
(None, None) => true,
_ => false,
}
}
}
impl Eq for PlatformSpecificEventLoopAttributes {}
impl std::hash::Hash for PlatformSpecificEventLoopAttributes {
fn hash<H: std::hash::Hasher>(&self, state: &mut H) {
self.any_thread.hash(state);
self.dpi_aware.hash(state);
std::ptr::hash(&self.msg_hook, state);
}
}
pub struct ActiveEventLoop {
thread_id: u32,
thread_msg_target: HWND,
pub(crate) runner_shared: Rc<EventLoopRunner>,
}
impl EventLoop {
pub(crate) fn new(
attributes: &mut PlatformSpecificEventLoopAttributes,
) -> Result<Self, EventLoopError> {
let thread_id = unsafe { GetCurrentThreadId() };
if !attributes.any_thread && thread_id != main_thread_id() {
panic!(
"Initializing the event loop outside of the main thread is a significant \
cross-platform compatibility hazard. If you absolutely need to create an \
EventLoop on a different thread, you can use the \
`EventLoopBuilderExtWindows::with_any_thread` function."
);
}
if attributes.dpi_aware {
become_dpi_aware();
}
let thread_msg_target = create_event_target_window();
let runner_shared = Rc::new(EventLoopRunner::new(thread_msg_target));
insert_event_target_window_data(thread_msg_target, runner_shared.clone());
raw_input::register_all_mice_and_keyboards_for_raw_input(
thread_msg_target,
Default::default(),
);
Ok(EventLoop {
window_target: ActiveEventLoop { thread_id, thread_msg_target, runner_shared },
msg_hook: attributes.msg_hook.take(),
high_resolution_timer: None,
})
}
pub fn window_target(&self) -> &dyn RootActiveEventLoop {
&self.window_target
}
pub fn run_app<A: ApplicationHandler>(mut self, app: A) -> Result<(), EventLoopError> {
self.run_app_on_demand(app)
}
pub fn run_app_on_demand<A: ApplicationHandler>(
&mut self,
mut app: A,
) -> Result<(), EventLoopError> {
self.window_target.clear_exit();
{
let runner = &self.window_target.runner_shared;
let event_loop_windows_ref = &self.window_target;
// # Safety
// We make sure to call runner.clear_event_handler() before
// returning
unsafe {
runner.set_event_handler(move |event| match event {
Event::NewEvents(cause) => app.new_events(event_loop_windows_ref, cause),
Event::WindowEvent { window_id, event } => {
app.window_event(event_loop_windows_ref, window_id, event)
},
Event::DeviceEvent { device_id, event } => {
app.device_event(event_loop_windows_ref, device_id, event)
},
Event::UserWakeUp => app.proxy_wake_up(event_loop_windows_ref),
Event::Suspended => app.suspended(event_loop_windows_ref),
Event::Resumed => app.resumed(event_loop_windows_ref),
Event::CreateSurfaces => app.can_create_surfaces(event_loop_windows_ref),
Event::AboutToWait => app.about_to_wait(event_loop_windows_ref),
Event::LoopExiting => app.exiting(event_loop_windows_ref),
Event::MemoryWarning => app.memory_warning(event_loop_windows_ref),
});
}
}
let exit_code = loop {
self.wait_for_messages(None);
// wait_for_messages calls user application before and after waiting
// so it may have decided to exit.
if let Some(code) = self.exit_code() {
break code;
}
self.dispatch_peeked_messages();
if let Some(code) = self.exit_code() {
break code;
}
};
let runner = &self.window_target.runner_shared;
runner.loop_destroyed();
// # Safety
// We assume that this will effectively call `runner.clear_event_handler()`
// to meet the safety requirements for calling `runner.set_event_handler()` above.
runner.reset_runner();
if exit_code == 0 {
Ok(())
} else {
Err(EventLoopError::ExitFailure(exit_code))
}
}
pub fn pump_app_events<A: ApplicationHandler>(
&mut self,
timeout: Option<Duration>,
mut app: A,
) -> PumpStatus {
{
let runner = &self.window_target.runner_shared;
let event_loop_windows_ref = &self.window_target;
// let user_event_receiver = &self.user_event_receiver;
// # Safety
// We make sure to call runner.clear_event_handler() before
// returning
//
// Note: we're currently assuming nothing can panic and unwind
// to leave the runner in an unsound state with an associated
// event handler.
unsafe {
runner.set_event_handler(move |event| match event {
Event::NewEvents(cause) => app.new_events(event_loop_windows_ref, cause),
Event::WindowEvent { window_id, event } => {
app.window_event(event_loop_windows_ref, window_id, event)
},
Event::DeviceEvent { device_id, event } => {
app.device_event(event_loop_windows_ref, device_id, event)
},
Event::UserWakeUp => app.proxy_wake_up(event_loop_windows_ref),
Event::Suspended => app.suspended(event_loop_windows_ref),
Event::Resumed => app.resumed(event_loop_windows_ref),
Event::CreateSurfaces => app.can_create_surfaces(event_loop_windows_ref),
Event::AboutToWait => app.about_to_wait(event_loop_windows_ref),
Event::LoopExiting => app.exiting(event_loop_windows_ref),
Event::MemoryWarning => app.memory_warning(event_loop_windows_ref),
});
runner.wakeup();
}
}
if self.exit_code().is_none() {
self.wait_for_messages(timeout);
}
// wait_for_messages calls user application before and after waiting
// so it may have decided to exit.
if self.exit_code().is_none() {
self.dispatch_peeked_messages();
}
let runner = &self.window_target.runner_shared;
let status = if let Some(code) = runner.exit_code() {
runner.loop_destroyed();
// Immediately reset the internal state for the loop to allow
// the loop to be run more than once.
runner.reset_runner();
PumpStatus::Exit(code)
} else {
runner.prepare_wait();
PumpStatus::Continue
};
// We wait until we've checked for an exit status before clearing the
// application callback, in case we need to dispatch a LoopExiting event
//
// # Safety
// This pairs up with our call to `runner.set_event_handler` and ensures
// the application's callback can't be held beyond its lifetime.
runner.clear_event_handler();
status
}
/// Waits until new event messages arrive to be peeked.
/// Doesn't peek messages itself.
///
/// Parameter timeout is optional. This method would wait for the smaller timeout
/// between the argument and a timeout from control flow.
fn wait_for_messages(&mut self, timeout: Option<Duration>) {
let runner = &self.window_target.runner_shared;
// We aim to be consistent with the MacOS backend which has a RunLoop
// observer that will dispatch AboutToWait when about to wait for
// events, and NewEvents after the RunLoop wakes up.
//
// We emulate similar behaviour by treating `MsgWaitForMultipleObjectsEx` as our wait
// point and wake up point (when it returns) and we drain all other
// pending messages via `PeekMessage` until we come back to "wait" via
// `MsgWaitForMultipleObjectsEx`.
//
runner.prepare_wait();
wait_for_messages_impl(&mut self.high_resolution_timer, runner.control_flow(), timeout);
// Before we potentially exit, make sure to consistently emit an event for the wake up
runner.wakeup();
}
/// Dispatch all queued messages via `PeekMessageW`
fn dispatch_peeked_messages(&mut self) {
let runner = &self.window_target.runner_shared;
// We generally want to continue dispatching all pending messages
// but we also allow dispatching to be interrupted as a means to
// ensure the `pump_events` won't indefinitely block an external
// event loop if there are too many pending events. This interrupt
// flag will be set after dispatching `RedrawRequested` events.
runner.interrupt_msg_dispatch.set(false);
// # Safety
// The Windows API has no documented requirement for bitwise
// initializing a `MSG` struct (it can be uninitialized memory for the C
// API) and there's no API to construct or initialize a `MSG`. This
// is the simplest way avoid uninitialized memory in Rust
let mut msg: MSG = unsafe { mem::zeroed() };
loop {
unsafe {
if PeekMessageW(&mut msg, 0, 0, 0, PM_REMOVE) == false.into() {
break;
}
let handled = if let Some(callback) = self.msg_hook.as_deref_mut() {
callback(&mut msg as *mut _ as *mut _)
} else {
false
};
if !handled {
TranslateMessage(&msg);
DispatchMessageW(&msg);
}
}
if let Err(payload) = runner.take_panic_error() {
runner.reset_runner();
panic::resume_unwind(payload);
}
if let Some(_code) = runner.exit_code() {
break;
}
if runner.interrupt_msg_dispatch.get() {
break;
}
}
}
fn exit_code(&self) -> Option<i32> {
self.window_target.exit_code()
}
}
impl Drop for EventLoop {
fn drop(&mut self) {
unsafe {
DestroyWindow(self.window_target.thread_msg_target);
}
}
}
impl ActiveEventLoop {
#[inline(always)]
pub(crate) fn create_thread_executor(&self) -> EventLoopThreadExecutor {
EventLoopThreadExecutor { thread_id: self.thread_id, target_window: self.thread_msg_target }
}
pub(crate) fn clear_exit(&self) {
self.runner_shared.clear_exit();
}
fn exit_code(&self) -> Option<i32> {
self.runner_shared.exit_code()
}
}
impl RootActiveEventLoop for ActiveEventLoop {
fn create_proxy(&self) -> RootEventLoopProxy {
let event_loop_proxy = EventLoopProxy { target_window: self.thread_msg_target };
RootEventLoopProxy::new(Arc::new(event_loop_proxy))
}
fn create_window(
&self,
window_attributes: WindowAttributes,
) -> Result<Box<dyn CoreWindow>, RequestError> {
Ok(Box::new(Window::new(self, window_attributes)?))
}
fn create_custom_cursor(
&self,
source: CustomCursorSource,
) -> Result<RootCustomCursor, RequestError> {
Ok(RootCustomCursor { inner: WinCursor::new(&source.inner.0)? })
}
fn available_monitors(&self) -> Box<dyn Iterator<Item = crate::monitor::MonitorHandle>> {
Box::new(
monitor::available_monitors()
.into_iter()
.map(|inner| crate::monitor::MonitorHandle { inner }),
)
}
fn primary_monitor(&self) -> Option<crate::monitor::MonitorHandle> {
Some(RootMonitorHandle { inner: monitor::primary_monitor() })
}
fn exiting(&self) -> bool {
self.runner_shared.exit_code().is_some()
}
fn system_theme(&self) -> Option<Theme> {
Some(if super::dark_mode::should_use_dark_mode() { Theme::Dark } else { Theme::Light })
}
fn listen_device_events(&self, allowed: DeviceEvents) {
raw_input::register_all_mice_and_keyboards_for_raw_input(self.thread_msg_target, allowed);
}
fn set_control_flow(&self, control_flow: ControlFlow) {
self.runner_shared.set_control_flow(control_flow)
}
fn control_flow(&self) -> ControlFlow {
self.runner_shared.control_flow()
}
fn exit(&self) {
self.runner_shared.set_exit_code(0)
}
fn owned_display_handle(&self) -> CoreOwnedDisplayHandle {
CoreOwnedDisplayHandle::new(Arc::new(OwnedDisplayHandle))
}
fn rwh_06_handle(&self) -> &dyn rwh_06::HasDisplayHandle {
self
}
}
impl rwh_06::HasDisplayHandle for ActiveEventLoop {
fn display_handle(&self) -> Result<rwh_06::DisplayHandle<'_>, rwh_06::HandleError> {
let raw = rwh_06::RawDisplayHandle::Windows(rwh_06::WindowsDisplayHandle::new());
unsafe { Ok(rwh_06::DisplayHandle::borrow_raw(raw)) }
}
}
#[derive(Clone)]
pub(crate) struct OwnedDisplayHandle;
impl rwh_06::HasDisplayHandle for OwnedDisplayHandle {
fn display_handle(&self) -> Result<rwh_06::DisplayHandle<'_>, rwh_06::HandleError> {
let raw = rwh_06::RawDisplayHandle::Windows(rwh_06::WindowsDisplayHandle::new());
unsafe { Ok(rwh_06::DisplayHandle::borrow_raw(raw)) }
}
}
/// Returns the id of the main thread.
///
/// Windows has no real API to check if the current executing thread is the "main thread", unlike
/// macOS.
///
/// Windows will let us look up the current thread's id, but there's no API that lets us check what
/// the id of the main thread is. We would somehow need to get the main thread's id before a
/// developer could spin off any other threads inside of the main entrypoint in order to emulate the
/// capabilities of other platforms.
///
/// We can get the id of the main thread by using CRT initialization. CRT initialization can be used
/// to setup global state within a program. The OS will call a list of function pointers which
/// assign values to a static variable. To have get a hold of the main thread id, we need to place
/// our function pointer inside of the `.CRT$XCU` section so it is called before the main
/// entrypoint.
///
/// Full details of CRT initialization can be found here:
/// <https://docs.microsoft.com/en-us/cpp/c-runtime-library/crt-initialization?view=msvc-160>
fn main_thread_id() -> u32 {
static mut MAIN_THREAD_ID: u32 = 0;
/// Function pointer used in CRT initialization section to set the above static field's value.
// Mark as used so this is not removable.
#[used]
#[allow(non_upper_case_globals)]
// Place the function pointer inside of CRT initialization section so it is loaded before
// main entrypoint.
//
// See: https://doc.rust-lang.org/stable/reference/abi.html#the-link_section-attribute
#[link_section = ".CRT$XCU"]
static INIT_MAIN_THREAD_ID: unsafe fn() = {
unsafe fn initer() {
unsafe { MAIN_THREAD_ID = GetCurrentThreadId() };
}
initer
};
unsafe { MAIN_THREAD_ID }
}
/// Returns the minimum `Option<Duration>`, taking into account that `None`
/// equates to an infinite timeout, not a zero timeout (so can't just use
/// `Option::min`)
fn min_timeout(a: Option<Duration>, b: Option<Duration>) -> Option<Duration> {
a.map_or(b, |a_timeout| b.map_or(Some(a_timeout), |b_timeout| Some(a_timeout.min(b_timeout))))
}
// Implementation taken from https://github.com/rust-lang/rust/blob/db5476571d9b27c862b95c1e64764b0ac8980e23/src/libstd/sys/windows/mod.rs
fn dur2timeout(dur: Duration) -> u32 {
// Note that a duration is a (u64, u32) (seconds, nanoseconds) pair, and the
// timeouts in windows APIs are typically u32 milliseconds. To translate, we
// have two pieces to take care of:
//
// * Nanosecond precision is rounded up
// * Greater than u32::MAX milliseconds (50 days) is rounded up to INFINITE (never time out).
dur.as_secs()
.checked_mul(1000)
.and_then(|ms| ms.checked_add((dur.subsec_nanos() as u64) / 1_000_000))
.and_then(
|ms| {
if dur.subsec_nanos() % 1_000_000 > 0 {
ms.checked_add(1)
} else {
Some(ms)
}
},
)
.map(|ms| if ms > u32::MAX as u64 { INFINITE } else { ms as u32 })
.unwrap_or(INFINITE)
}
/// Set upper limit for waiting time to avoid overflows.
/// I chose 50 days as a limit because it is used in dur2timeout.
const FIFTY_DAYS: Duration = Duration::from_secs(50_u64 * 24 * 60 * 60);
/// Waitable timers use 100 ns intervals to indicate due time.
/// <https://learn.microsoft.com/en-us/windows/win32/api/synchapi/nf-synchapi-setwaitabletimer#parameters>
/// And there is no point waiting using other ways for such small timings
/// because they are even less precise (can overshoot by few ms).
const MIN_WAIT: Duration = Duration::from_nanos(100);
fn create_high_resolution_timer() -> Option<OwnedHandle> {
unsafe {
let handle: HANDLE = CreateWaitableTimerExW(
ptr::null(),
ptr::null(),
CREATE_WAITABLE_TIMER_HIGH_RESOLUTION,
TIMER_ALL_ACCESS,
);
// CREATE_WAITABLE_TIMER_HIGH_RESOLUTION is supported only after
// Win10 1803 but it is already default option for rustc
// (std uses it to implement `std::thread::sleep`).
if handle == 0 {
None
} else {
Some(OwnedHandle::from_raw_handle(handle as *mut c_void))
}
}
}
/// This function should not return error if parameters are valid
/// but there is no guarantee about that at MSDN docs
/// so we return result of GetLastError if fail.
///
/// ## Safety
///
/// timer must be a valid timer handle created by [create_high_resolution_timer].
/// timeout divided by 100 nanoseconds must be more than 0 and less than i64::MAX.
unsafe fn set_high_resolution_timer(timer: RawHandle, timeout: Duration) -> Result<(), u32> {
const INTERVAL_NS: u32 = MIN_WAIT.subsec_nanos();
const INTERVALS_IN_SEC: u64 = (Duration::from_secs(1).as_nanos() / INTERVAL_NS as u128) as u64;
let intervals_to_wait: u64 =
timeout.as_secs() * INTERVALS_IN_SEC + u64::from(timeout.subsec_nanos() / INTERVAL_NS);
debug_assert!(intervals_to_wait < i64::MAX as u64, "Must be called with smaller duration",);
// Use negative time to indicate relative time.
let due_time: i64 = -(intervals_to_wait as i64);
unsafe {
let set_result = SetWaitableTimer(timer as HANDLE, &due_time, 0, None, ptr::null(), FALSE);
if set_result != FALSE {
Ok(())
} else {
Err(GetLastError())
}
}
}
/// Implementation detail of [EventLoop::wait_for_messages].
///
/// Does actual system-level waiting and doesn't process any messages itself,
/// including winits internal notifications about waiting and new messages arrival.
fn wait_for_messages_impl(
high_resolution_timer: &mut Option<OwnedHandle>,
control_flow: ControlFlow,
timeout: Option<Duration>,
) {
let timeout = {
let control_flow_timeout = match control_flow {
ControlFlow::Wait => None,
ControlFlow::Poll => Some(Duration::ZERO),
ControlFlow::WaitUntil(wait_deadline) => {
let start = Instant::now();
Some(wait_deadline.saturating_duration_since(start))
},
};
let timeout = min_timeout(timeout, control_flow_timeout);
if timeout == Some(Duration::ZERO) {
// Do not wait if we don't have time.
return;
}
// Now we decided to wait so need to do some clamping
// to avoid problems with overflow and calling WinAPI with invalid parameters.
timeout
.map(|t| t.min(FIFTY_DAYS))
// If timeout is less than minimally supported by Windows,
// increase it to that minimum. Who want less than microsecond delays anyway?
.map(|t| t.max(MIN_WAIT))
};
if timeout.is_some() && high_resolution_timer.is_none() {
*high_resolution_timer = create_high_resolution_timer();
}
let high_resolution_timer: Option<RawHandle> =
high_resolution_timer.as_ref().map(OwnedHandle::as_raw_handle);
let use_timer: bool;
if let (Some(handle), Some(timeout)) = (high_resolution_timer, timeout) {
let res = unsafe {
// Safety: handle can be Some only if we succeeded in creating high resolution
// timer. We properly clamped timeout so it can be used as argument
// to timer.
set_high_resolution_timer(handle, timeout)
};
if let Err(error_code) = res {
// We successfully got timer but failed to set it?
// Should be some bug in our code.
tracing::trace!("Failed to set high resolution timer: last error {}", error_code);
use_timer = false;
} else {
use_timer = true;
}
} else {
use_timer = false;
}
unsafe {
// Either:
// 1. User wants to wait indefinely if timeout is not set.
// 2. We failed to get and set high resolution timer and we need something instead of it.
let wait_duration_ms = timeout.map(dur2timeout).unwrap_or(INFINITE);
let (num_handles, raw_handles) =
if use_timer { (1, [high_resolution_timer.unwrap()]) } else { (0, [ptr::null_mut()]) };
let result = MsgWaitForMultipleObjectsEx(
num_handles,
raw_handles.as_ptr() as *const _,
wait_duration_ms,
QS_ALLEVENTS,
MWMO_INPUTAVAILABLE,
);
if result == WAIT_FAILED {
// Well, nothing smart to do in such case.
// Treat it as spurious wake up.
tracing::warn!("Failed to MsgWaitForMultipleObjectsEx: error code {}", GetLastError(),);
}
}
}
pub(crate) struct EventLoopThreadExecutor {
thread_id: u32,
target_window: HWND,
}
unsafe impl Send for EventLoopThreadExecutor {}
unsafe impl Sync for EventLoopThreadExecutor {}
impl EventLoopThreadExecutor {
/// Check to see if we're in the parent event loop's thread.
pub(super) fn in_event_loop_thread(&self) -> bool {
let cur_thread_id = unsafe { GetCurrentThreadId() };
self.thread_id == cur_thread_id
}
/// Executes a function in the event loop thread. If we're already in the event loop thread,
/// we just call the function directly.
///
/// The `Inserted` can be used to inject a `WindowState` for the callback to use. The state is
/// removed automatically if the callback receives a `WM_CLOSE` message for the window.
///
/// Note that if you are using this to change some property of a window and updating
/// `WindowState` then you should call this within the lock of `WindowState`. Otherwise the
/// events may be sent to the other thread in different order to the one in which you set
/// `WindowState`, leaving them out of sync.
///
/// Note that we use a FnMut instead of a FnOnce because we're too lazy to create an equivalent
/// to the unstable FnBox.
pub(super) fn execute_in_thread<F>(&self, mut function: F)
where
F: FnMut() + Send + 'static,
{
unsafe {
if self.in_event_loop_thread() {
function();
} else {
// We double-box because the first box is a fat pointer.
let boxed2: ThreadExecFn = Box::new(Box::new(function));
let raw = Box::into_raw(boxed2);
let res = PostMessageW(self.target_window, EXEC_MSG_ID.get(), raw as usize, 0);
assert!(res != false.into(), "PostMessage failed; is the messages queue full?");
}
}
}
}
type ThreadExecFn = Box<Box<dyn FnMut()>>;
pub struct EventLoopProxy {
target_window: HWND,
}
unsafe impl Send for EventLoopProxy {}
impl EventLoopProxyProvider for EventLoopProxy {
fn wake_up(&self) {
unsafe { PostMessageW(self.target_window, USER_EVENT_MSG_ID.get(), 0, 0) };
}
}
/// A lazily-initialized window message ID.
pub struct LazyMessageId {
/// The ID.
id: AtomicU32,
/// The name of the message.
name: &'static str,
}
/// An invalid custom window ID.
const INVALID_ID: u32 = 0x0;
impl LazyMessageId {
/// Create a new `LazyId`.
const fn new(name: &'static str) -> Self {
Self { id: AtomicU32::new(INVALID_ID), name }
}
/// Get the message ID.
pub fn get(&self) -> u32 {
// Load the ID.
let id = self.id.load(Ordering::Relaxed);
if id != INVALID_ID {
return id;
}
// Register the message.
// SAFETY: We are sure that the pointer is a valid C string ending with '\0'.
assert!(self.name.ends_with('\0'));
let new_id = unsafe { RegisterWindowMessageA(self.name.as_ptr()) };
assert_ne!(
new_id,
0,
"RegisterWindowMessageA returned zero for '{}': {}",
self.name,
std::io::Error::last_os_error()
);
// Store the new ID. Since `RegisterWindowMessageA` returns the same value for any given
// string, the target value will always either be a). `INVALID_ID` or b). the
// correct ID. Therefore a compare-and-swap operation here (or really any
// consideration) is never necessary.
self.id.store(new_id, Ordering::Relaxed);
new_id
}
}
// Message sent by the `EventLoopProxy` when we want to wake up the thread.
// WPARAM and LPARAM are unused.
static USER_EVENT_MSG_ID: LazyMessageId = LazyMessageId::new("Winit::WakeupMsg\0");
// Message sent when we want to execute a closure in the thread.
// WPARAM contains a Box<Box<dyn FnMut()>> that must be retrieved with `Box::from_raw`,
// and LPARAM is unused.
static EXEC_MSG_ID: LazyMessageId = LazyMessageId::new("Winit::ExecMsg\0");
// Message sent by a `Window` when it wants to be destroyed by the main thread.
// WPARAM and LPARAM are unused.
pub(crate) static DESTROY_MSG_ID: LazyMessageId = LazyMessageId::new("Winit::DestroyMsg\0");
// WPARAM is a bool specifying the `WindowFlags::MARKER_RETAIN_STATE_ON_SIZE` flag. See the
// documentation in the `window_state` module for more information.
pub(crate) static SET_RETAIN_STATE_ON_SIZE_MSG_ID: LazyMessageId =
LazyMessageId::new("Winit::SetRetainMaximized\0");
static THREAD_EVENT_TARGET_WINDOW_CLASS: Lazy<Vec<u16>> =
Lazy::new(|| util::encode_wide("Winit Thread Event Target"));
/// When the taskbar is created, it registers a message with the "TaskbarCreated" string and then
/// broadcasts this message to all top-level windows <https://docs.microsoft.com/en-us/windows/win32/shell/taskbar#taskbar-creation-notification>
pub(crate) static TASKBAR_CREATED: LazyMessageId = LazyMessageId::new("TaskbarCreated\0");
fn create_event_target_window() -> HWND {
use windows_sys::Win32::UI::WindowsAndMessaging::{CS_HREDRAW, CS_VREDRAW};
unsafe {
let class = WNDCLASSEXW {
cbSize: mem::size_of::<WNDCLASSEXW>() as u32,
style: CS_HREDRAW | CS_VREDRAW,
lpfnWndProc: Some(thread_event_target_callback),
cbClsExtra: 0,
cbWndExtra: 0,
hInstance: util::get_instance_handle(),
hIcon: 0,
hCursor: 0, // must be null in order for cursor state to work properly
hbrBackground: 0,
lpszMenuName: ptr::null(),
lpszClassName: THREAD_EVENT_TARGET_WINDOW_CLASS.as_ptr(),
hIconSm: 0,
};
RegisterClassExW(&class);
}
unsafe {
// WS_EX_TOOLWINDOW prevents this window from ever showing up in the taskbar, which
// we want to avoid. If you remove this style, this window won't show up in the
// taskbar *initially*, but it can show up at some later point. This can sometimes
// happen on its own after several hours have passed, although this has proven
// difficult to reproduce. Alternatively, it can be manually triggered by killing
// `explorer.exe` and then starting the process back up.
// It is unclear why the bug is triggered by waiting for several hours.
let window = CreateWindowExW(
WS_EX_NOACTIVATE | WS_EX_TRANSPARENT | WS_EX_LAYERED | WS_EX_TOOLWINDOW,
THREAD_EVENT_TARGET_WINDOW_CLASS.as_ptr(),
ptr::null(),
WS_OVERLAPPED,
0,
0,
0,
0,
0,
0,
util::get_instance_handle(),
ptr::null(),
);
super::set_window_long(
window,
GWL_STYLE,
// The window technically has to be visible to receive WM_PAINT messages (which are
// used for delivering events during resizes), but it isn't displayed to
// the user because of the LAYERED style.
(WS_VISIBLE | WS_POPUP) as isize,
);
window
}
}
fn insert_event_target_window_data(
thread_msg_target: HWND,
event_loop_runner: Rc<EventLoopRunner>,
) {
let userdata = ThreadMsgTargetData { event_loop_runner };
let input_ptr = Box::into_raw(Box::new(userdata));
unsafe { super::set_window_long(thread_msg_target, GWL_USERDATA, input_ptr as isize) };
}
/// Capture mouse input, allowing `window` to receive mouse events when the cursor is outside of
/// the window.
unsafe fn capture_mouse(window: HWND, window_state: &mut WindowState) {
window_state.mouse.capture_count += 1;
unsafe { SetCapture(window) };
}
/// Release mouse input, stopping windows on this thread from receiving mouse input when the cursor
/// is outside the window.
unsafe fn release_mouse(mut window_state: MutexGuard<'_, WindowState>) {
window_state.mouse.capture_count = window_state.mouse.capture_count.saturating_sub(1);
if window_state.mouse.capture_count == 0 {
// ReleaseCapture() causes a WM_CAPTURECHANGED where we lock the window_state.
drop(window_state);
unsafe { ReleaseCapture() };
}
}
fn normalize_pointer_pressure(pressure: u32) -> Option<Force> {
match pressure {
1..=1024 => Some(Force::Normalized(pressure as f64 / 1024.0)),
_ => None,
}
}
/// Emit a `ModifiersChanged` event whenever modifiers have changed.
/// Returns the current modifier state
fn update_modifiers(window: HWND, userdata: &WindowData) {
use crate::event::WindowEvent::ModifiersChanged;
let modifiers = {
let mut layouts = LAYOUT_CACHE.lock().unwrap();
layouts.get_agnostic_mods()
};
let mut window_state = userdata.window_state.lock().unwrap();
if window_state.modifiers_state != modifiers {
window_state.modifiers_state = modifiers;
// Drop lock
drop(window_state);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: ModifiersChanged(modifiers.into()),
});
}
}
unsafe fn gain_active_focus(window: HWND, userdata: &WindowData) {
use crate::event::WindowEvent::Focused;
update_modifiers(window, userdata);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: Focused(true),
});
}
unsafe fn lose_active_focus(window: HWND, userdata: &WindowData) {
use crate::event::WindowEvent::{Focused, ModifiersChanged};
userdata.window_state_lock().modifiers_state = ModifiersState::empty();
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: ModifiersChanged(ModifiersState::empty().into()),
});
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: Focused(false),
});
}
/// Any window whose callback is configured to this function will have its events propagated
/// through the events loop of the thread the window was created in.
// This is the callback that is called by `DispatchMessage` in the events loop.
//
// Returning 0 tells the Win32 API that the message has been processed.
// FIXME: detect WM_DWMCOMPOSITIONCHANGED and call DwmEnableBlurBehindWindow if necessary
pub(super) unsafe extern "system" fn public_window_callback(
window: HWND,
msg: u32,
wparam: WPARAM,
lparam: LPARAM,
) -> LRESULT {
let userdata = unsafe { super::get_window_long(window, GWL_USERDATA) };
let userdata_ptr = match (userdata, msg) {
(0, WM_NCCREATE) => {
let createstruct = unsafe { &mut *(lparam as *mut CREATESTRUCTW) };
let initdata = unsafe { &mut *(createstruct.lpCreateParams as *mut InitData<'_>) };
let result = match unsafe { initdata.on_nccreate(window) } {
Some(userdata) => unsafe {
super::set_window_long(window, GWL_USERDATA, userdata as _);
DefWindowProcW(window, msg, wparam, lparam)
},
None => -1, // failed to create the window
};
return result;
},
// Getting here should quite frankly be impossible,
// but we'll make window creation fail here just in case.
(0, WM_CREATE) => return -1,
(_, WM_CREATE) => unsafe {
let createstruct = &mut *(lparam as *mut CREATESTRUCTW);
let initdata = createstruct.lpCreateParams;
let initdata = &mut *(initdata as *mut InitData<'_>);
initdata.on_create();
return DefWindowProcW(window, msg, wparam, lparam);
},
(0, _) => return unsafe { DefWindowProcW(window, msg, wparam, lparam) },
_ => userdata as *mut WindowData,
};
let (result, userdata_removed, recurse_depth) = {
let userdata = unsafe { &*(userdata_ptr) };
userdata.recurse_depth.set(userdata.recurse_depth.get() + 1);
let result = unsafe { public_window_callback_inner(window, msg, wparam, lparam, userdata) };
let userdata_removed = userdata.userdata_removed.get();
let recurse_depth = userdata.recurse_depth.get() - 1;
userdata.recurse_depth.set(recurse_depth);
(result, userdata_removed, recurse_depth)
};
if userdata_removed && recurse_depth == 0 {
drop(unsafe { Box::from_raw(userdata_ptr) });
}
result
}
unsafe fn public_window_callback_inner(
window: HWND,
msg: u32,
wparam: WPARAM,
lparam: LPARAM,
userdata: &WindowData,
) -> LRESULT {
let mut result = ProcResult::DefWindowProc(wparam);
// Send new modifiers before sending key events.
let mods_changed_callback = || match msg {
WM_KEYDOWN | WM_SYSKEYDOWN | WM_KEYUP | WM_SYSKEYUP => {
update_modifiers(window, userdata);
result = ProcResult::Value(0);
},
_ => (),
};
userdata
.event_loop_runner
.catch_unwind(mods_changed_callback)
.unwrap_or_else(|| result = ProcResult::Value(-1));
let keyboard_callback = || {
use crate::event::WindowEvent::KeyboardInput;
let events =
userdata.key_event_builder.process_message(window, msg, wparam, lparam, &mut result);
for event in events {
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: KeyboardInput {
device_id: None,
event: event.event,
is_synthetic: event.is_synthetic,
},
});
}
};
userdata
.event_loop_runner
.catch_unwind(keyboard_callback)
.unwrap_or_else(|| result = ProcResult::Value(-1));
// I decided to bind the closure to `callback` and pass it to catch_unwind rather than passing
// the closure to catch_unwind directly so that the match body indentation wouldn't change and
// the git blame and history would be preserved.
let callback = || match msg {
WM_NCCALCSIZE => {
let window_flags = userdata.window_state_lock().window_flags;
if wparam == 0 || window_flags.contains(WindowFlags::MARKER_DECORATIONS) {
result = ProcResult::DefWindowProc(wparam);
return;
}
let params = unsafe { &mut *(lparam as *mut NCCALCSIZE_PARAMS) };
if util::is_maximized(window) {
// Limit the window size when maximized to the current monitor.
// Otherwise it would include the non-existent decorations.
//
// Use `MonitorFromRect` instead of `MonitorFromWindow` to select
// the correct monitor here.
// See https://github.com/MicrosoftEdge/WebView2Feedback/issues/2549
let monitor = unsafe { MonitorFromRect(&params.rgrc[0], MONITOR_DEFAULTTONULL) };
if let Ok(monitor_info) = monitor::get_monitor_info(monitor) {
params.rgrc[0] = monitor_info.monitorInfo.rcWork;
}
} else if window_flags.contains(WindowFlags::MARKER_UNDECORATED_SHADOW) {
// Extend the client area to cover the whole non-client area.
// https://docs.microsoft.com/en-us/windows/win32/winmsg/wm-nccalcsize#remarks
//
// HACK(msiglreith): To add the drop shadow we slightly tweak the non-client area.
// This leads to a small black 1px border on the top. Adding a margin manually
// on all 4 borders would result in the caption getting drawn by the DWM.
//
// Another option would be to allow the DWM to paint inside the client area.
// Unfortunately this results in janky resize behavior, where the compositor is
// ahead of the window surface. Currently, there seems no option to achieve this
// with the Windows API.
params.rgrc[0].top += 1;
params.rgrc[0].bottom += 1;
}
result = ProcResult::Value(0);
},
WM_ENTERSIZEMOVE => {
userdata
.window_state_lock()
.set_window_flags_in_place(|f| f.insert(WindowFlags::MARKER_IN_SIZE_MOVE));
result = ProcResult::Value(0);
},
WM_EXITSIZEMOVE => {
let mut state = userdata.window_state_lock();
if state.dragging {
state.dragging = false;
unsafe { PostMessageW(window, WM_LBUTTONUP, 0, lparam) };
}
state.set_window_flags_in_place(|f| f.remove(WindowFlags::MARKER_IN_SIZE_MOVE));
result = ProcResult::Value(0);
},
WM_NCLBUTTONDOWN => {
if wparam == HTCAPTION as _ {
unsafe { PostMessageW(window, WM_MOUSEMOVE, 0, lparam) };
}
result = ProcResult::DefWindowProc(wparam);
},
WM_CLOSE => {
use crate::event::WindowEvent::CloseRequested;
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: CloseRequested,
});
result = ProcResult::Value(0);
},
WM_DESTROY => {
use crate::event::WindowEvent::Destroyed;
unsafe { RevokeDragDrop(window) };
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: Destroyed,
});
result = ProcResult::Value(0);
},
WM_NCDESTROY => {
unsafe { super::set_window_long(window, GWL_USERDATA, 0) };
userdata.userdata_removed.set(true);
result = ProcResult::Value(0);
},
WM_PAINT => {
userdata.window_state_lock().redraw_requested =
userdata.event_loop_runner.should_buffer();
// We'll buffer only in response to `UpdateWindow`, if win32 decides to redraw the
// window outside the normal flow of the event loop. This way mark event as handled
// and request a normal redraw with `RedrawWindow`.
if !userdata.event_loop_runner.should_buffer() {
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::RedrawRequested,
});
}
// NOTE: calling `RedrawWindow` during `WM_PAINT` does nothing, since to mark
// `WM_PAINT` as handled we should call the `DefWindowProcW`. Call it and check whether
// user asked for redraw during `RedrawRequested` event handling and request it again
// after marking `WM_PAINT` as handled.
result = ProcResult::Value(unsafe { DefWindowProcW(window, msg, wparam, lparam) });
if std::mem::take(&mut userdata.window_state_lock().redraw_requested) {
unsafe { RedrawWindow(window, ptr::null(), 0, RDW_INTERNALPAINT) };
}
},
WM_WINDOWPOSCHANGING => {
let mut window_state = userdata.window_state_lock();
if let Some(ref mut fullscreen) = window_state.fullscreen {
let window_pos = unsafe { &mut *(lparam as *mut WINDOWPOS) };
let new_rect = RECT {
left: window_pos.x,
top: window_pos.y,
right: window_pos.x + window_pos.cx,
bottom: window_pos.y + window_pos.cy,
};
const NOMOVE_OR_NOSIZE: u32 = SWP_NOMOVE | SWP_NOSIZE;
let new_rect = if window_pos.flags & NOMOVE_OR_NOSIZE != 0 {
let cur_rect = util::WindowArea::Outer.get_rect(window).expect(
"Unexpected GetWindowRect failure; please report this error to \
rust-windowing/winit",
);
match window_pos.flags & NOMOVE_OR_NOSIZE {
NOMOVE_OR_NOSIZE => None,
SWP_NOMOVE => Some(RECT {
left: cur_rect.left,
top: cur_rect.top,
right: cur_rect.left + window_pos.cx,
bottom: cur_rect.top + window_pos.cy,
}),
SWP_NOSIZE => Some(RECT {
left: window_pos.x,
top: window_pos.y,
right: window_pos.x - cur_rect.left + cur_rect.right,
bottom: window_pos.y - cur_rect.top + cur_rect.bottom,
}),
_ => unreachable!(),
}
} else {
Some(new_rect)
};
if let Some(new_rect) = new_rect {
let new_monitor = unsafe { MonitorFromRect(&new_rect, MONITOR_DEFAULTTONULL) };
match fullscreen {
Fullscreen::Borderless(ref mut fullscreen_monitor) => {
if new_monitor != 0
&& fullscreen_monitor
.as_ref()
.map(|monitor| new_monitor != monitor.hmonitor())
.unwrap_or(true)
{
if let Ok(new_monitor_info) = monitor::get_monitor_info(new_monitor)
{
let new_monitor_rect = new_monitor_info.monitorInfo.rcMonitor;
window_pos.x = new_monitor_rect.left;
window_pos.y = new_monitor_rect.top;
window_pos.cx = new_monitor_rect.right - new_monitor_rect.left;
window_pos.cy = new_monitor_rect.bottom - new_monitor_rect.top;
}
*fullscreen_monitor = Some(MonitorHandle::new(new_monitor));
}
},
Fullscreen::Exclusive(ref video_mode) => {
let old_monitor = video_mode.monitor.hmonitor();
if let Ok(old_monitor_info) = monitor::get_monitor_info(old_monitor) {
let old_monitor_rect = old_monitor_info.monitorInfo.rcMonitor;
window_pos.x = old_monitor_rect.left;
window_pos.y = old_monitor_rect.top;
window_pos.cx = old_monitor_rect.right - old_monitor_rect.left;
window_pos.cy = old_monitor_rect.bottom - old_monitor_rect.top;
}
},
}
}
}
result = ProcResult::Value(0);
},
// WM_MOVE supplies client area positions, so we send Moved here instead.
WM_WINDOWPOSCHANGED => {
use crate::event::WindowEvent::Moved;
let windowpos = lparam as *const WINDOWPOS;
if unsafe { (*windowpos).flags & SWP_NOMOVE != SWP_NOMOVE } {
let physical_position =
unsafe { PhysicalPosition::new((*windowpos).x, (*windowpos).y) };
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: Moved(physical_position),
});
}
// This is necessary for us to still get sent WM_SIZE.
result = ProcResult::DefWindowProc(wparam);
},
WM_SIZE => {
use crate::event::WindowEvent::SurfaceResized;
let w = super::loword(lparam as u32) as u32;
let h = super::hiword(lparam as u32) as u32;
let physical_size = PhysicalSize::new(w, h);
let event = Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: SurfaceResized(physical_size),
};
{
let mut w = userdata.window_state_lock();
// See WindowFlags::MARKER_RETAIN_STATE_ON_SIZE docs for info on why this `if` check
// exists.
if !w.window_flags().contains(WindowFlags::MARKER_RETAIN_STATE_ON_SIZE) {
let maximized = wparam == SIZE_MAXIMIZED as usize;
w.set_window_flags_in_place(|f| f.set(WindowFlags::MAXIMIZED, maximized));
}
}
userdata.send_event(event);
result = ProcResult::Value(0);
},
WM_SIZING => {
/// Calculate the amount to add to round `value` to the nearest multiple of `increment`.
fn snap_to_nearest_increment_delta(value: i32, increment: i32) -> i32 {
let half_one = increment / 2;
let half_two = increment - half_one;
half_one - (value - half_two) % increment
}
let scale_factor = userdata.window_state_lock().scale_factor;
let Some(inc) = userdata
.window_state_lock()
.surface_resize_increments
.map(|inc| inc.to_physical(scale_factor))
.filter(|inc| inc.width > 0 && inc.height > 0)
else {
result = ProcResult::Value(0);
return;
};
let side = wparam as u32;
// The desired new size of the window, decorations included.
let rect = unsafe { &mut *(lparam as *mut RECT) };
// We need to calculate the dimensions of the window decorations to get the true
// size of the window's contents
let adj_rect = userdata
.window_state_lock()
.window_flags
.adjust_rect(window, *rect)
.unwrap_or(*rect);
let deco_width = rect.left - adj_rect.left + adj_rect.right - rect.right;
let deco_height = rect.top - adj_rect.top + adj_rect.bottom - rect.bottom;
let width = rect.right - rect.left - deco_width;
let height = rect.bottom - rect.top - deco_height;
let mut width_delta = snap_to_nearest_increment_delta(width, inc.width);
let mut height_delta = snap_to_nearest_increment_delta(height, inc.height);
// Windows won't bound check the value of `rect` after we're done here, so we
// have to check manually. If the width/height we snap to would go out of bounds, just
// set it equal to the min/max bound.
let min_size =
userdata.window_state_lock().min_size.map(|size| size.to_physical(scale_factor));
let max_size =
userdata.window_state_lock().max_size.map(|size| size.to_physical(scale_factor));
let final_width = width + width_delta;
let final_height = height + height_delta;
if let Some(min_size) = min_size {
if final_width < min_size.width {
width_delta += min_size.width - final_width;
}
if final_height < min_size.height {
height_delta += min_size.height - final_height;
}
}
if let Some(max_size) = max_size {
if final_width > max_size.width {
width_delta -= final_width - max_size.width;
}
if final_height > max_size.height {
height_delta -= final_height - max_size.height;
}
}
match side {
WMSZ_LEFT | WMSZ_BOTTOMLEFT | WMSZ_TOPLEFT => {
rect.left -= width_delta;
},
WMSZ_RIGHT | WMSZ_BOTTOMRIGHT | WMSZ_TOPRIGHT => {
rect.right += width_delta;
},
_ => {},
}
match side {
WMSZ_TOP | WMSZ_TOPLEFT | WMSZ_TOPRIGHT => {
rect.top -= height_delta;
},
WMSZ_BOTTOM | WMSZ_BOTTOMLEFT | WMSZ_BOTTOMRIGHT => {
rect.bottom += height_delta;
},
_ => {},
}
result = ProcResult::DefWindowProc(wparam);
},
WM_MENUCHAR => {
result = ProcResult::Value((MNC_CLOSE << 16) as isize);
},
WM_IME_STARTCOMPOSITION => {
let ime_allowed = userdata.window_state_lock().ime_allowed;
if ime_allowed {
userdata.window_state_lock().ime_state = ImeState::Enabled;
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::Ime(Ime::Enabled),
});
}
result = ProcResult::DefWindowProc(wparam);
},
WM_IME_COMPOSITION => {
let ime_allowed_and_composing = {
let w = userdata.window_state_lock();
w.ime_allowed && w.ime_state != ImeState::Disabled
};
// Windows Hangul IME sends WM_IME_COMPOSITION after WM_IME_ENDCOMPOSITION, so
// check whether composing.
if ime_allowed_and_composing {
let ime_context = unsafe { ImeContext::current(window) };
if lparam == 0 {
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::Ime(Ime::Preedit(String::new(), None)),
});
}
// Google Japanese Input and ATOK have both flags, so
// first, receive composing result if exist.
if (lparam as u32 & GCS_RESULTSTR) != 0 {
if let Some(text) = unsafe { ime_context.get_composed_text() } {
userdata.window_state_lock().ime_state = ImeState::Enabled;
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::Ime(Ime::Preedit(String::new(), None)),
});
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::Ime(Ime::Commit(text)),
});
}
}
// Next, receive preedit range for next composing if exist.
if (lparam as u32 & GCS_COMPSTR) != 0 {
if let Some((text, first, last)) =
unsafe { ime_context.get_composing_text_and_cursor() }
{
userdata.window_state_lock().ime_state = ImeState::Preedit;
let cursor_range = first.map(|f| (f, last.unwrap_or(f)));
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::Ime(Ime::Preedit(text, cursor_range)),
});
}
}
}
// Not calling DefWindowProc to hide composing text drawn by IME.
result = ProcResult::Value(0);
},
WM_IME_ENDCOMPOSITION => {
let ime_allowed_or_composing = {
let w = userdata.window_state_lock();
w.ime_allowed || w.ime_state != ImeState::Disabled
};
if ime_allowed_or_composing {
if userdata.window_state_lock().ime_state == ImeState::Preedit {
// Windows Hangul IME sends WM_IME_COMPOSITION after WM_IME_ENDCOMPOSITION, so
// trying receiving composing result and commit if exists.
let ime_context = unsafe { ImeContext::current(window) };
if let Some(text) = unsafe { ime_context.get_composed_text() } {
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::Ime(Ime::Preedit(String::new(), None)),
});
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::Ime(Ime::Commit(text)),
});
}
}
userdata.window_state_lock().ime_state = ImeState::Disabled;
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::Ime(Ime::Disabled),
});
}
result = ProcResult::DefWindowProc(wparam);
},
WM_IME_SETCONTEXT => {
// Hide composing text drawn by IME.
let wparam = wparam & (!ISC_SHOWUICOMPOSITIONWINDOW as usize);
result = ProcResult::DefWindowProc(wparam);
},
// this is necessary for us to maintain minimize/restore state
WM_SYSCOMMAND => {
if wparam == SC_RESTORE as usize {
let mut w = userdata.window_state_lock();
w.set_window_flags_in_place(|f| f.set(WindowFlags::MINIMIZED, false));
}
if wparam == SC_MINIMIZE as usize {
let mut w = userdata.window_state_lock();
w.set_window_flags_in_place(|f| f.set(WindowFlags::MINIMIZED, true));
}
// Send `WindowEvent::Minimized` here if we decide to implement one
if wparam == SC_SCREENSAVE as usize {
let window_state = userdata.window_state_lock();
if window_state.fullscreen.is_some() {
result = ProcResult::Value(0);
return;
}
}
result = ProcResult::DefWindowProc(wparam);
},
WM_MOUSEMOVE => {
use crate::event::WindowEvent::{PointerEntered, PointerLeft, PointerMoved};
use crate::event::{PointerKind, PointerSource};
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
let cursor_moved;
{
let mut w = userdata.window_state_lock();
let mouse_was_inside_window =
w.mouse.cursor_flags().contains(CursorFlags::IN_WINDOW);
match get_pointer_move_kind(window, mouse_was_inside_window, x, y) {
PointerMoveKind::Enter => {
w.mouse
.set_cursor_flags(window, |f| f.set(CursorFlags::IN_WINDOW, true))
.ok();
drop(w);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerEntered {
device_id: None,
primary: true,
position,
kind: PointerKind::Mouse,
},
});
// Calling TrackMouseEvent in order to receive mouse leave events.
unsafe {
TrackMouseEvent(&mut TRACKMOUSEEVENT {
cbSize: mem::size_of::<TRACKMOUSEEVENT>() as u32,
dwFlags: TME_LEAVE,
hwndTrack: window,
dwHoverTime: HOVER_DEFAULT,
})
};
},
PointerMoveKind::Leave => {
w.mouse
.set_cursor_flags(window, |f| f.set(CursorFlags::IN_WINDOW, false))
.ok();
drop(w);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerLeft {
device_id: None,
primary: true,
position: Some(position),
kind: PointerKind::Mouse,
},
});
},
PointerMoveKind::None => drop(w),
}
// handle spurious WM_MOUSEMOVE messages
// see https://devblogs.microsoft.com/oldnewthing/20031001-00/?p=42343
// and http://debugandconquer.blogspot.com/2015/08/the-cause-of-spurious-mouse-move.html
let mut w = userdata.window_state_lock();
cursor_moved = w.mouse.last_position != Some(position);
w.mouse.last_position = Some(position);
}
if cursor_moved {
update_modifiers(window, userdata);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerMoved {
device_id: None,
primary: true,
position,
source: PointerSource::Mouse,
},
});
}
result = ProcResult::Value(0);
},
WM_MOUSELEAVE => {
use crate::event::PointerKind::Mouse;
use crate::event::WindowEvent::PointerLeft;
{
let mut w = userdata.window_state_lock();
w.mouse.set_cursor_flags(window, |f| f.set(CursorFlags::IN_WINDOW, false)).ok();
}
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerLeft { device_id: None, primary: true, position: None, kind: Mouse },
});
result = ProcResult::Value(0);
},
WM_MOUSEWHEEL => {
use crate::event::MouseScrollDelta::LineDelta;
let value = (wparam >> 16) as i16;
let value = value as f32 / WHEEL_DELTA as f32;
update_modifiers(window, userdata);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::MouseWheel {
device_id: None,
delta: LineDelta(0.0, value),
phase: TouchPhase::Moved,
},
});
result = ProcResult::Value(0);
},
WM_MOUSEHWHEEL => {
use crate::event::MouseScrollDelta::LineDelta;
let value = (wparam >> 16) as i16;
let value = -value as f32 / WHEEL_DELTA as f32; // NOTE: inverted! See https://github.com/rust-windowing/winit/pull/2105/
update_modifiers(window, userdata);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: WindowEvent::MouseWheel {
device_id: None,
delta: LineDelta(value, 0.0),
phase: TouchPhase::Moved,
},
});
result = ProcResult::Value(0);
},
WM_KEYDOWN | WM_SYSKEYDOWN => {
if msg == WM_SYSKEYDOWN {
result = ProcResult::DefWindowProc(wparam);
}
},
WM_KEYUP | WM_SYSKEYUP => {
if msg == WM_SYSKEYUP && unsafe { GetMenu(window) != 0 } {
// let Windows handle event if the window has a native menu, a modal event loop
// is started here on Alt key up.
result = ProcResult::DefWindowProc(wparam);
}
},
WM_LBUTTONDOWN => {
use crate::event::ElementState::Pressed;
use crate::event::MouseButton::Left;
use crate::event::WindowEvent::PointerButton;
unsafe { capture_mouse(window, &mut userdata.window_state_lock()) };
update_modifiers(window, userdata);
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerButton {
device_id: None,
primary: true,
state: Pressed,
position,
button: Left.into(),
},
});
result = ProcResult::Value(0);
},
WM_LBUTTONUP => {
use crate::event::ElementState::Released;
use crate::event::MouseButton::Left;
use crate::event::WindowEvent::PointerButton;
unsafe { release_mouse(userdata.window_state_lock()) };
update_modifiers(window, userdata);
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerButton {
device_id: None,
primary: true,
state: Released,
position,
button: Left.into(),
},
});
result = ProcResult::Value(0);
},
WM_RBUTTONDOWN => {
use crate::event::ElementState::Pressed;
use crate::event::MouseButton::Right;
use crate::event::WindowEvent::PointerButton;
unsafe { capture_mouse(window, &mut userdata.window_state_lock()) };
update_modifiers(window, userdata);
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerButton {
device_id: None,
primary: true,
state: Pressed,
position,
button: Right.into(),
},
});
result = ProcResult::Value(0);
},
WM_RBUTTONUP => {
use crate::event::ElementState::Released;
use crate::event::MouseButton::Right;
use crate::event::WindowEvent::PointerButton;
unsafe { release_mouse(userdata.window_state_lock()) };
update_modifiers(window, userdata);
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerButton {
device_id: None,
primary: true,
state: Released,
position,
button: Right.into(),
},
});
result = ProcResult::Value(0);
},
WM_MBUTTONDOWN => {
use crate::event::ElementState::Pressed;
use crate::event::MouseButton::Middle;
use crate::event::WindowEvent::PointerButton;
unsafe { capture_mouse(window, &mut userdata.window_state_lock()) };
update_modifiers(window, userdata);
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerButton {
device_id: None,
primary: true,
state: Pressed,
position,
button: Middle.into(),
},
});
result = ProcResult::Value(0);
},
WM_MBUTTONUP => {
use crate::event::ElementState::Released;
use crate::event::MouseButton::Middle;
use crate::event::WindowEvent::PointerButton;
unsafe { release_mouse(userdata.window_state_lock()) };
update_modifiers(window, userdata);
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerButton {
device_id: None,
primary: true,
state: Released,
position,
button: Middle.into(),
},
});
result = ProcResult::Value(0);
},
WM_XBUTTONDOWN => {
use crate::event::ElementState::Pressed;
use crate::event::MouseButton::{Back, Forward, Other};
use crate::event::WindowEvent::PointerButton;
let xbutton = super::get_xbutton_wparam(wparam as u32);
unsafe { capture_mouse(window, &mut userdata.window_state_lock()) };
update_modifiers(window, userdata);
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerButton {
device_id: None,
primary: true,
state: Pressed,
position,
button: match xbutton {
1 => Back,
2 => Forward,
_ => Other(xbutton),
}
.into(),
},
});
result = ProcResult::Value(0);
},
WM_XBUTTONUP => {
use crate::event::ElementState::Released;
use crate::event::MouseButton::{Back, Forward, Other};
use crate::event::WindowEvent::PointerButton;
let xbutton = super::get_xbutton_wparam(wparam as u32);
unsafe { release_mouse(userdata.window_state_lock()) };
update_modifiers(window, userdata);
let x = super::get_x_lparam(lparam as u32) as i32;
let y = super::get_y_lparam(lparam as u32) as i32;
let position = PhysicalPosition::new(x as f64, y as f64);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: PointerButton {
device_id: None,
primary: true,
state: Released,
position,
button: match xbutton {
1 => Back,
2 => Forward,
_ => Other(xbutton),
}
.into(),
},
});
result = ProcResult::Value(0);
},
WM_CAPTURECHANGED => {
// lparam here is a handle to the window which is gaining mouse capture.
// If it is the same as our window, then we're essentially retaining the capture. This
// can happen if `SetCapture` is called on our window when it already has the mouse
// capture.
if lparam != window {
userdata.window_state_lock().mouse.capture_count = 0;
}
result = ProcResult::Value(0);
},
WM_TOUCH => {
use crate::event::ButtonSource::Touch;
use crate::event::ElementState::{Pressed, Released};
use crate::event::{PointerKind, PointerSource};
let pcount = super::loword(wparam as u32) as usize;
let mut inputs = Vec::with_capacity(pcount);
let htouch = lparam;
if unsafe {
GetTouchInputInfo(
htouch,
pcount as u32,
inputs.as_mut_ptr(),
mem::size_of::<TOUCHINPUT>() as i32,
) > 0
} {
unsafe { inputs.set_len(pcount) };
for input in &inputs {
let mut position = POINT { x: input.x / 100, y: input.y / 100 };
if unsafe { ScreenToClient(window, &mut position) } == false.into() {
continue;
}
let x = position.x as f64 + (input.x % 100) as f64 / 100f64;
let y = position.y as f64 + (input.y % 100) as f64 / 100f64;
let position = PhysicalPosition::new(x, y);
let window_id = WindowId::from_raw(window as usize);
let finger_id = FingerId::from_raw(input.dwID as usize);
let primary = util::has_flag(input.dwFlags, TOUCHEVENTF_PRIMARY);
if util::has_flag(input.dwFlags, TOUCHEVENTF_DOWN) {
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerEntered {
device_id: None,
primary,
position,
kind: PointerKind::Touch(finger_id),
},
});
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerButton {
device_id: None,
primary,
state: Pressed,
position,
button: Touch { finger_id, force: None },
},
});
} else if util::has_flag(input.dwFlags, TOUCHEVENTF_UP) {
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerButton {
device_id: None,
primary,
state: Released,
position,
button: Touch { finger_id, force: None },
},
});
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerLeft {
device_id: None,
primary,
position: Some(position),
kind: PointerKind::Touch(finger_id),
},
});
} else if util::has_flag(input.dwFlags, TOUCHEVENTF_MOVE) {
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerMoved {
device_id: None,
primary,
position,
source: PointerSource::Touch { finger_id, force: None },
},
});
} else {
continue;
}
}
}
unsafe { CloseTouchInputHandle(htouch) };
result = ProcResult::Value(0);
},
WM_POINTERDOWN | WM_POINTERUPDATE | WM_POINTERUP => {
use crate::event::ElementState::{Pressed, Released};
use crate::event::{ButtonSource, PointerKind, PointerSource};
if let (
Some(GetPointerFrameInfoHistory),
Some(SkipPointerFrameMessages),
Some(GetPointerDeviceRects),
) = (
*util::GET_POINTER_FRAME_INFO_HISTORY,
*util::SKIP_POINTER_FRAME_MESSAGES,
*util::GET_POINTER_DEVICE_RECTS,
) {
let pointer_id = super::loword(wparam as u32) as u32;
let mut entries_count = 0u32;
let mut pointers_count = 0u32;
if unsafe {
GetPointerFrameInfoHistory(
pointer_id,
&mut entries_count,
&mut pointers_count,
ptr::null_mut(),
)
} == false.into()
{
result = ProcResult::Value(0);
return;
}
let pointer_info_count = (entries_count * pointers_count) as usize;
let mut pointer_infos = Vec::with_capacity(pointer_info_count);
if unsafe {
GetPointerFrameInfoHistory(
pointer_id,
&mut entries_count,
&mut pointers_count,
pointer_infos.as_mut_ptr(),
)
} == false.into()
{
result = ProcResult::Value(0);
return;
}
unsafe { pointer_infos.set_len(pointer_info_count) };
// https://docs.microsoft.com/en-us/windows/desktop/api/winuser/nf-winuser-getpointerframeinfohistory
// The information retrieved appears in reverse chronological order, with the most
// recent entry in the first row of the returned array
for pointer_info in pointer_infos.iter().rev() {
let mut device_rect = mem::MaybeUninit::uninit();
let mut display_rect = mem::MaybeUninit::uninit();
if unsafe {
GetPointerDeviceRects(
pointer_info.sourceDevice,
device_rect.as_mut_ptr(),
display_rect.as_mut_ptr(),
)
} == false.into()
{
continue;
}
let device_rect = unsafe { device_rect.assume_init() };
let display_rect = unsafe { display_rect.assume_init() };
// For the most precise himetric to pixel conversion we calculate the ratio
// between the resolution of the display device (pixel) and
// the touch device (himetric).
let himetric_to_pixel_ratio_x = (display_rect.right - display_rect.left) as f64
/ (device_rect.right - device_rect.left) as f64;
let himetric_to_pixel_ratio_y = (display_rect.bottom - display_rect.top) as f64
/ (device_rect.bottom - device_rect.top) as f64;
// ptHimetricLocation's origin is 0,0 even on multi-monitor setups.
// On multi-monitor setups we need to translate the himetric location to the
// rect of the display device it's attached to.
let x = display_rect.left as f64
+ pointer_info.ptHimetricLocation.x as f64 * himetric_to_pixel_ratio_x;
let y = display_rect.top as f64
+ pointer_info.ptHimetricLocation.y as f64 * himetric_to_pixel_ratio_y;
let mut location = POINT { x: x.floor() as i32, y: y.floor() as i32 };
if unsafe { ScreenToClient(window, &mut location) } == false.into() {
continue;
}
let force = if let PT_TOUCH = pointer_info.pointerType {
let mut touch_info = mem::MaybeUninit::uninit();
util::GET_POINTER_TOUCH_INFO.and_then(|GetPointerTouchInfo| {
match unsafe {
GetPointerTouchInfo(pointer_info.pointerId, touch_info.as_mut_ptr())
} {
0 => None,
_ => normalize_pointer_pressure(unsafe {
touch_info.assume_init().pressure
}),
}
})
} else {
None
};
let x = location.x as f64 + x.fract();
let y = location.y as f64 + y.fract();
let position = PhysicalPosition::new(x, y);
let window_id = WindowId::from_raw(window as usize);
let finger_id = FingerId::from_raw(pointer_info.pointerId as usize);
let primary = util::has_flag(pointer_info.pointerFlags, POINTER_FLAG_PRIMARY);
if util::has_flag(pointer_info.pointerFlags, POINTER_FLAG_DOWN) {
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerEntered {
device_id: None,
primary,
position,
kind: if let PT_TOUCH = pointer_info.pointerType {
PointerKind::Touch(finger_id)
} else {
PointerKind::Unknown
},
},
});
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerButton {
device_id: None,
primary,
state: Pressed,
position,
button: if let PT_TOUCH = pointer_info.pointerType {
ButtonSource::Touch { finger_id, force }
} else {
ButtonSource::Unknown(0)
},
},
});
} else if util::has_flag(pointer_info.pointerFlags, POINTER_FLAG_UP) {
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerButton {
device_id: None,
primary,
state: Released,
position,
button: if let PT_TOUCH = pointer_info.pointerType {
ButtonSource::Touch { finger_id, force }
} else {
ButtonSource::Unknown(0)
},
},
});
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerLeft {
device_id: None,
primary,
position: Some(position),
kind: if let PT_TOUCH = pointer_info.pointerType {
PointerKind::Touch(finger_id)
} else {
PointerKind::Unknown
},
},
});
} else if util::has_flag(pointer_info.pointerFlags, POINTER_FLAG_UPDATE) {
userdata.send_event(Event::WindowEvent {
window_id,
event: WindowEvent::PointerMoved {
device_id: None,
primary,
position,
source: if let PT_TOUCH = pointer_info.pointerType {
PointerSource::Touch { finger_id, force }
} else {
PointerSource::Unknown
},
},
});
} else {
continue;
}
}
unsafe { SkipPointerFrameMessages(pointer_id) };
}
result = ProcResult::Value(0);
},
WM_NCACTIVATE => {
let is_active = wparam != false.into();
let active_focus_changed = userdata.window_state_lock().set_active(is_active);
if active_focus_changed {
if is_active {
unsafe { gain_active_focus(window, userdata) };
} else {
unsafe { lose_active_focus(window, userdata) };
}
}
result = ProcResult::DefWindowProc(wparam);
},
WM_SETFOCUS => {
let active_focus_changed = userdata.window_state_lock().set_focused(true);
if active_focus_changed {
unsafe { gain_active_focus(window, userdata) };
}
result = ProcResult::Value(0);
},
WM_KILLFOCUS => {
let active_focus_changed = userdata.window_state_lock().set_focused(false);
if active_focus_changed {
unsafe { lose_active_focus(window, userdata) };
}
result = ProcResult::Value(0);
},
WM_SETCURSOR => {
let set_cursor_to = {
let window_state = userdata.window_state_lock();
// The return value for the preceding `WM_NCHITTEST` message is conveniently
// provided through the low-order word of lParam. We use that here since
// `WM_MOUSEMOVE` seems to come after `WM_SETCURSOR` for a given cursor movement.
let in_client_area = super::loword(lparam as u32) as u32 == HTCLIENT;
if in_client_area {
Some(window_state.mouse.selected_cursor.clone())
} else {
None
}
};
match set_cursor_to {
Some(selected_cursor) => {
let hcursor = match selected_cursor {
SelectedCursor::Named(cursor_icon) => unsafe {
LoadCursorW(0, util::to_windows_cursor(cursor_icon))
},
SelectedCursor::Custom(cursor) => cursor.as_raw_handle(),
};
unsafe { SetCursor(hcursor) };
result = ProcResult::Value(0);
},
None => result = ProcResult::DefWindowProc(wparam),
}
},
WM_GETMINMAXINFO => {
let mmi = lparam as *mut MINMAXINFO;
let window_state = userdata.window_state_lock();
let window_flags = window_state.window_flags;
if window_state.min_size.is_some() || window_state.max_size.is_some() {
if let Some(min_size) = window_state.min_size {
let min_size = min_size.to_physical(window_state.scale_factor);
let (width, height): (u32, u32) =
window_flags.adjust_size(window, min_size).into();
unsafe { (*mmi).ptMinTrackSize = POINT { x: width as i32, y: height as i32 } };
}
if let Some(max_size) = window_state.max_size {
let max_size = max_size.to_physical(window_state.scale_factor);
let (width, height): (u32, u32) =
window_flags.adjust_size(window, max_size).into();
unsafe { (*mmi).ptMaxTrackSize = POINT { x: width as i32, y: height as i32 } };
}
}
result = ProcResult::Value(0);
},
// Only sent on Windows 8.1 or newer. On Windows 7 and older user has to log out to change
// DPI, therefore all applications are closed while DPI is changing.
WM_DPICHANGED => {
use crate::event::WindowEvent::ScaleFactorChanged;
// This message actually provides two DPI values - x and y. However MSDN says that
// "you only need to use either the X-axis or the Y-axis value when scaling your
// application since they are the same".
// https://msdn.microsoft.com/en-us/library/windows/desktop/dn312083(v=vs.85).aspx
let new_dpi_x = super::loword(wparam as u32) as u32;
let new_scale_factor = dpi_to_scale_factor(new_dpi_x);
let old_scale_factor: f64;
let (allow_resize, window_flags) = {
let mut window_state = userdata.window_state_lock();
old_scale_factor = window_state.scale_factor;
window_state.scale_factor = new_scale_factor;
if new_scale_factor == old_scale_factor {
result = ProcResult::Value(0);
return;
}
let allow_resize = window_state.fullscreen.is_none()
&& !window_state.window_flags().contains(WindowFlags::MAXIMIZED);
(allow_resize, window_state.window_flags)
};
// New size as suggested by Windows.
let suggested_rect = unsafe { *(lparam as *const RECT) };
// The window rect provided is the window's outer size, not it's surface size. However,
// win32 doesn't provide an `UnadjustWindowRectEx` function to get the client rect from
// the outer rect, so we instead adjust the window rect to get the decoration margins
// and remove them from the outer size.
let margin_left: i32;
let margin_top: i32;
// let margin_right: i32;
// let margin_bottom: i32;
{
let adjusted_rect =
window_flags.adjust_rect(window, suggested_rect).unwrap_or(suggested_rect);
margin_left = suggested_rect.left - adjusted_rect.left;
margin_top = suggested_rect.top - adjusted_rect.top;
// margin_right = adjusted_rect.right - suggested_rect.right;
// margin_bottom = adjusted_rect.bottom - suggested_rect.bottom;
}
let old_physical_inner_rect = util::WindowArea::Inner
.get_rect(window)
.expect("failed to query (old) inner window area");
let old_physical_surface_size = PhysicalSize::new(
(old_physical_inner_rect.right - old_physical_inner_rect.left) as u32,
(old_physical_inner_rect.bottom - old_physical_inner_rect.top) as u32,
);
// `allow_resize` prevents us from re-applying DPI adjustment to the restored size after
// exiting fullscreen (the restored size is already DPI adjusted).
let new_physical_surface_size = match allow_resize {
// We calculate our own size because the default suggested rect doesn't do a great
// job of preserving the window's logical size.
true => old_physical_surface_size
.to_logical::<f64>(old_scale_factor)
.to_physical::<u32>(new_scale_factor),
false => old_physical_surface_size,
};
let new_surface_size = Arc::new(Mutex::new(new_physical_surface_size));
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: ScaleFactorChanged {
scale_factor: new_scale_factor,
surface_size_writer: SurfaceSizeWriter::new(Arc::downgrade(&new_surface_size)),
},
});
let new_physical_surface_size = *new_surface_size.lock().unwrap();
drop(new_surface_size);
let dragging_window: bool;
{
let window_state = userdata.window_state_lock();
dragging_window =
window_state.window_flags().contains(WindowFlags::MARKER_IN_SIZE_MOVE);
// Unset maximized if we're changing the window's size.
if new_physical_surface_size != old_physical_surface_size {
WindowState::set_window_flags(window_state, window, |f| {
f.set(WindowFlags::MAXIMIZED, false)
});
}
}
let new_outer_rect: RECT;
{
let suggested_ul =
(suggested_rect.left + margin_left, suggested_rect.top + margin_top);
let mut conservative_rect = RECT {
left: suggested_ul.0,
top: suggested_ul.1,
right: suggested_ul.0 + new_physical_surface_size.width as i32,
bottom: suggested_ul.1 + new_physical_surface_size.height as i32,
};
conservative_rect = window_flags
.adjust_rect(window, conservative_rect)
.unwrap_or(conservative_rect);
// If we're dragging the window, offset the window so that the cursor's
// relative horizontal position in the title bar is preserved.
if dragging_window {
let bias = {
let cursor_pos = {
let mut pos = unsafe { mem::zeroed() };
unsafe { GetCursorPos(&mut pos) };
pos
};
let suggested_cursor_horizontal_ratio = (cursor_pos.x - suggested_rect.left)
as f64
/ (suggested_rect.right - suggested_rect.left) as f64;
(cursor_pos.x
- (suggested_cursor_horizontal_ratio
* (conservative_rect.right - conservative_rect.left) as f64)
as i32)
- conservative_rect.left
};
conservative_rect.left += bias;
conservative_rect.right += bias;
}
// Check to see if the new window rect is on the monitor with the new DPI factor.
// If it isn't, offset the window so that it is.
let new_dpi_monitor = unsafe { MonitorFromWindow(window, MONITOR_DEFAULTTONULL) };
let conservative_rect_monitor =
unsafe { MonitorFromRect(&conservative_rect, MONITOR_DEFAULTTONULL) };
new_outer_rect = if conservative_rect_monitor == new_dpi_monitor {
conservative_rect
} else {
let get_monitor_rect = |monitor| {
let mut monitor_info = MONITORINFO {
cbSize: mem::size_of::<MONITORINFO>() as _,
..unsafe { mem::zeroed() }
};
unsafe { GetMonitorInfoW(monitor, &mut monitor_info) };
monitor_info.rcMonitor
};
let wrong_monitor = conservative_rect_monitor;
let wrong_monitor_rect = get_monitor_rect(wrong_monitor);
let new_monitor_rect = get_monitor_rect(new_dpi_monitor);
// The direction to nudge the window in to get the window onto the monitor with
// the new DPI factor. We calculate this by seeing which monitor edges are
// shared and nudging away from the wrong monitor based on those.
#[allow(clippy::bool_to_int_with_if)]
let delta_nudge_to_dpi_monitor = (
if wrong_monitor_rect.left == new_monitor_rect.right {
-1
} else if wrong_monitor_rect.right == new_monitor_rect.left {
1
} else {
0
},
if wrong_monitor_rect.bottom == new_monitor_rect.top {
1
} else if wrong_monitor_rect.top == new_monitor_rect.bottom {
-1
} else {
0
},
);
let abort_after_iterations = new_monitor_rect.right - new_monitor_rect.left
+ new_monitor_rect.bottom
- new_monitor_rect.top;
for _ in 0..abort_after_iterations {
conservative_rect.left += delta_nudge_to_dpi_monitor.0;
conservative_rect.right += delta_nudge_to_dpi_monitor.0;
conservative_rect.top += delta_nudge_to_dpi_monitor.1;
conservative_rect.bottom += delta_nudge_to_dpi_monitor.1;
if unsafe { MonitorFromRect(&conservative_rect, MONITOR_DEFAULTTONULL) }
== new_dpi_monitor
{
break;
}
}
conservative_rect
};
}
unsafe {
SetWindowPos(
window,
0,
new_outer_rect.left,
new_outer_rect.top,
new_outer_rect.right - new_outer_rect.left,
new_outer_rect.bottom - new_outer_rect.top,
SWP_NOZORDER | SWP_NOACTIVATE,
)
};
result = ProcResult::Value(0);
},
WM_SETTINGCHANGE => {
use crate::event::WindowEvent::ThemeChanged;
let preferred_theme = userdata.window_state_lock().preferred_theme;
if preferred_theme.is_none() {
let new_theme = try_theme(window, preferred_theme);
let mut window_state = userdata.window_state_lock();
if window_state.current_theme != new_theme {
window_state.current_theme = new_theme;
drop(window_state);
userdata.send_event(Event::WindowEvent {
window_id: WindowId::from_raw(window as usize),
event: ThemeChanged(new_theme),
});
}
}
result = ProcResult::DefWindowProc(wparam);
},
_ => {
if msg == DESTROY_MSG_ID.get() {
unsafe { DestroyWindow(window) };
result = ProcResult::Value(0);
} else if msg == SET_RETAIN_STATE_ON_SIZE_MSG_ID.get() {
let mut window_state = userdata.window_state_lock();
window_state.set_window_flags_in_place(|f| {
f.set(WindowFlags::MARKER_RETAIN_STATE_ON_SIZE, wparam != 0)
});
result = ProcResult::Value(0);
} else if msg == TASKBAR_CREATED.get() {
let window_state = userdata.window_state_lock();
unsafe { set_skip_taskbar(window, window_state.skip_taskbar) };
result = ProcResult::DefWindowProc(wparam);
} else {
result = ProcResult::DefWindowProc(wparam);
}
},
};
userdata
.event_loop_runner
.catch_unwind(callback)
.unwrap_or_else(|| result = ProcResult::Value(-1));
match result {
ProcResult::DefWindowProc(wparam) => unsafe { DefWindowProcW(window, msg, wparam, lparam) },
ProcResult::Value(val) => val,
}
}
unsafe extern "system" fn thread_event_target_callback(
window: HWND,
msg: u32,
wparam: WPARAM,
lparam: LPARAM,
) -> LRESULT {
let userdata_ptr =
unsafe { super::get_window_long(window, GWL_USERDATA) } as *mut ThreadMsgTargetData;
if userdata_ptr.is_null() {
// `userdata_ptr` will always be null for the first `WM_GETMINMAXINFO`, as well as
// `WM_NCCREATE` and `WM_CREATE`.
return unsafe { DefWindowProcW(window, msg, wparam, lparam) };
}
let userdata = unsafe { Box::from_raw(userdata_ptr) };
if msg != WM_PAINT {
unsafe { RedrawWindow(window, ptr::null(), 0, RDW_INTERNALPAINT) };
}
let mut userdata_removed = false;
// I decided to bind the closure to `callback` and pass it to catch_unwind rather than passing
// the closure to catch_unwind directly so that the match body indentation wouldn't change and
// the git blame and history would be preserved.
let callback = || match msg {
WM_NCDESTROY => {
unsafe { super::set_window_long(window, GWL_USERDATA, 0) };
userdata_removed = true;
0
},
WM_PAINT => unsafe {
ValidateRect(window, ptr::null());
// Default WM_PAINT behaviour. This makes sure modals and popups are shown immediately
// when opening them.
DefWindowProcW(window, msg, wparam, lparam)
},
WM_INPUT => {
if let Some(data) = raw_input::get_raw_input_data(lparam as _) {
unsafe { handle_raw_input(&userdata, data) };
}
unsafe { DefWindowProcW(window, msg, wparam, lparam) }
},
_ if msg == USER_EVENT_MSG_ID.get() => {
// synthesis a placeholder UserEvent, so that if the callback is
// re-entered it can be buffered for later delivery. the real
// user event is still in the mpsc channel and will be pulled
// once the placeholder event is delivered to the wrapper
// `event_handler`
userdata.send_event(Event::UserWakeUp);
0
},
_ if msg == EXEC_MSG_ID.get() => {
let mut function: ThreadExecFn = unsafe { Box::from_raw(wparam as *mut _) };
function();
0
},
_ => unsafe { DefWindowProcW(window, msg, wparam, lparam) },
};
let result = userdata.event_loop_runner.catch_unwind(callback).unwrap_or(-1);
if userdata_removed {
drop(userdata);
} else {
Box::leak(userdata);
}
result
}
unsafe fn handle_raw_input(userdata: &ThreadMsgTargetData, data: RAWINPUT) {
use crate::event::DeviceEvent::{Button, Key, MouseWheel, PointerMotion};
use crate::event::ElementState::{Pressed, Released};
use crate::event::MouseScrollDelta::LineDelta;
let device_id = Some(wrap_device_id(data.header.hDevice as _));
if data.header.dwType == RIM_TYPEMOUSE {
let mouse = unsafe { data.data.mouse };
if util::has_flag(mouse.usFlags as u32, MOUSE_MOVE_RELATIVE) {
let x = mouse.lLastX as f64;
let y = mouse.lLastY as f64;
if x != 0.0 || y != 0.0 {
userdata.send_event(Event::DeviceEvent {
device_id,
event: PointerMotion { delta: (x, y) },
});
}
}
let button_flags = unsafe { mouse.Anonymous.Anonymous.usButtonFlags };
if util::has_flag(button_flags as u32, RI_MOUSE_WHEEL) {
let button_data = unsafe { mouse.Anonymous.Anonymous.usButtonData } as i16;
let delta = button_data as f32 / WHEEL_DELTA as f32;
userdata.send_event(Event::DeviceEvent {
device_id,
event: MouseWheel { delta: LineDelta(0.0, delta) },
});
}
if util::has_flag(button_flags as u32, RI_MOUSE_HWHEEL) {
let button_data = unsafe { mouse.Anonymous.Anonymous.usButtonData } as i16;
let delta = -button_data as f32 / WHEEL_DELTA as f32;
userdata.send_event(Event::DeviceEvent {
device_id,
event: MouseWheel { delta: LineDelta(delta, 0.0) },
});
}
let button_state = raw_input::get_raw_mouse_button_state(button_flags as u32);
for (button, state) in button_state.iter().enumerate() {
if let Some(state) = *state {
userdata.send_event(Event::DeviceEvent {
device_id,
event: Button { button: button as _, state },
});
}
}
} else if data.header.dwType == RIM_TYPEKEYBOARD {
let keyboard = unsafe { data.data.keyboard };
let pressed = keyboard.Message == WM_KEYDOWN || keyboard.Message == WM_SYSKEYDOWN;
let released = keyboard.Message == WM_KEYUP || keyboard.Message == WM_SYSKEYUP;
if !pressed && !released {
return;
}
if let Some(physical_key) = raw_input::get_keyboard_physical_key(keyboard) {
let state = if pressed { Pressed } else { Released };
userdata.send_event(Event::DeviceEvent {
device_id,
event: Key(RawKeyEvent { physical_key, state }),
});
}
}
}
enum PointerMoveKind {
/// Pointer enterd to the window.
Enter,
/// Pointer leaved the window client area.
Leave,
/// Pointer is inside the window or `GetClientRect` failed.
None,
}
fn get_pointer_move_kind(
window: HWND,
mouse_was_inside_window: bool,
x: i32,
y: i32,
) -> PointerMoveKind {
let rect: RECT = unsafe {
let mut rect: RECT = mem::zeroed();
if GetClientRect(window, &mut rect) == false.into() {
return PointerMoveKind::None; // exit early if GetClientRect failed
}
rect
};
let x = (rect.left..rect.right).contains(&x);
let y = (rect.top..rect.bottom).contains(&y);
if !mouse_was_inside_window && x && y {
PointerMoveKind::Enter
} else if mouse_was_inside_window && !(x && y) {
PointerMoveKind::Leave
} else {
PointerMoveKind::None
}
}
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