use scheduler::Instant; use std::{ any::{TypeId, type_name}, cell::{BorrowMutError, Cell, Ref, RefCell, RefMut}, marker::PhantomData, mem, ops::{Deref, DerefMut}, path::{Path, PathBuf}, rc::{Rc, Weak}, sync::{Arc, atomic::Ordering::SeqCst}, time::Duration, }; use anyhow::{Context as _, Result, anyhow}; use derive_more::{Deref, DerefMut}; use futures::{ Future, FutureExt, channel::oneshot, future::{LocalBoxFuture, Shared}, }; use itertools::Itertools; use parking_lot::RwLock; use slotmap::SlotMap; pub use async_context::*; use collections::{FxHashMap, FxHashSet, HashMap, VecDeque}; pub use context::*; pub use entity_map::*; use gpui_util::{ResultExt, debug_panic}; #[cfg(any(test, feature = "test-support"))] pub use headless_app_context::*; use http_client::{HttpClient, Url}; use smallvec::SmallVec; #[cfg(any(test, feature = "test-support"))] pub use test_app::*; #[cfg(any(test, feature = "test-support"))] pub use test_context::*; #[cfg(all(target_os = "macos", any(test, feature = "test-support")))] pub use visual_test_context::*; #[cfg(any(feature = "inspector", debug_assertions))] use crate::InspectorElementRegistry; use crate::{ Action, ActionBuildError, ActionRegistry, Any, AnyView, AnyWindowHandle, AppContext, Arena, ArenaBox, Asset, AssetSource, BackgroundExecutor, Bounds, ClipboardItem, CursorStyle, DispatchPhase, DisplayId, EventEmitter, FocusHandle, FocusMap, ForegroundExecutor, Global, KeyBinding, KeyContext, Keymap, Keystroke, LayoutId, Menu, MenuItem, OwnedMenu, PathPromptOptions, Pixels, Platform, PlatformDisplay, PlatformKeyboardLayout, PlatformKeyboardMapper, Point, Priority, PromptBuilder, PromptButton, PromptHandle, PromptLevel, Render, RenderImage, RenderablePromptHandle, Reservation, ScreenCaptureSource, SharedString, SubscriberSet, Subscription, SvgRenderer, Task, TextRenderingMode, TextSystem, ThermalState, Window, WindowAppearance, WindowButtonLayout, WindowHandle, WindowId, WindowInvalidator, colors::{Colors, GlobalColors}, hash, init_app_menus, }; mod async_context; mod context; mod entity_map; #[cfg(any(test, feature = "test-support"))] mod headless_app_context; #[cfg(any(test, feature = "test-support"))] mod test_app; #[cfg(any(test, feature = "test-support"))] mod test_context; #[cfg(all(target_os = "macos", any(test, feature = "test-support")))] mod visual_test_context; /// The duration for which futures returned from [Context::on_app_quit] can run before the application fully quits. pub const SHUTDOWN_TIMEOUT: Duration = Duration::from_millis(100); /// Temporary(?) wrapper around [`RefCell`] to help us debug any double borrows. /// Strongly consider removing after stabilization. #[doc(hidden)] pub struct AppCell { app: RefCell, } impl AppCell { #[doc(hidden)] #[track_caller] pub fn borrow(&self) -> AppRef<'_> { if option_env!("TRACK_THREAD_BORROWS").is_some() { let thread_id = std::thread::current().id(); eprintln!("borrowed {thread_id:?}"); } AppRef(self.app.borrow()) } #[doc(hidden)] #[track_caller] pub fn borrow_mut(&self) -> AppRefMut<'_> { if option_env!("TRACK_THREAD_BORROWS").is_some() { let thread_id = std::thread::current().id(); eprintln!("borrowed {thread_id:?}"); } AppRefMut(self.app.borrow_mut()) } #[doc(hidden)] #[track_caller] pub fn try_borrow_mut(&self) -> Result, BorrowMutError> { if option_env!("TRACK_THREAD_BORROWS").is_some() { let thread_id = std::thread::current().id(); eprintln!("borrowed {thread_id:?}"); } Ok(AppRefMut(self.app.try_borrow_mut()?)) } } #[doc(hidden)] #[derive(Deref, DerefMut)] pub struct AppRef<'a>(Ref<'a, App>); impl Drop for AppRef<'_> { fn drop(&mut self) { if option_env!("TRACK_THREAD_BORROWS").is_some() { let thread_id = std::thread::current().id(); eprintln!("dropped borrow from {thread_id:?}"); } } } #[doc(hidden)] #[derive(Deref, DerefMut)] pub struct AppRefMut<'a>(RefMut<'a, App>); impl Drop for AppRefMut<'_> { fn drop(&mut self) { if option_env!("TRACK_THREAD_BORROWS").is_some() { let thread_id = std::thread::current().id(); eprintln!("dropped {thread_id:?}"); } } } /// A reference to a GPUI application, typically constructed in the `main` function of your app. /// You won't interact with this type much outside of initial configuration and startup. pub struct Application(Rc); /// Represents an application before it is fully launched. Once your app is /// configured, you'll start the app with `App::run`. impl Application { /// Builds an app with a caller-provided platform implementation. pub fn with_platform(platform: Rc) -> Self { Self(App::new_app( platform, Arc::new(()), Arc::new(NullHttpClient), )) } /// Assigns the source of assets for the application. pub fn with_assets(self, asset_source: impl AssetSource) -> Self { let mut context_lock = self.0.borrow_mut(); let asset_source = Arc::new(asset_source); context_lock.asset_source = asset_source.clone(); context_lock.svg_renderer = SvgRenderer::new(asset_source); drop(context_lock); self } /// Sets the HTTP client for the application. pub fn with_http_client(self, http_client: Arc) -> Self { let mut context_lock = self.0.borrow_mut(); context_lock.http_client = http_client; drop(context_lock); self } /// Configures when the application should automatically quit. /// By default, [`QuitMode::Default`] is used. pub fn with_quit_mode(self, mode: QuitMode) -> Self { self.0.borrow_mut().quit_mode = mode; self } /// Start the application. The provided callback will be called once the /// app is fully launched. pub fn run(self, on_finish_launching: F) where F: 'static + FnOnce(&mut App), { let this = self.0.clone(); let platform = self.0.borrow().platform.clone(); platform.run(Box::new(move || { let cx = &mut *this.borrow_mut(); on_finish_launching(cx); })); } /// Register a handler to be invoked when the platform instructs the application /// to open one or more URLs. pub fn on_open_urls(&self, mut callback: F) -> &Self where F: 'static + FnMut(Vec), { self.0.borrow().platform.on_open_urls(Box::new(callback)); self } /// Invokes a handler when an already-running application is launched. /// On macOS, this can occur when the application icon is double-clicked or the app is launched via the dock. pub fn on_reopen(&self, mut callback: F) -> &Self where F: 'static + FnMut(&mut App), { let this = Rc::downgrade(&self.0); self.0.borrow_mut().platform.on_reopen(Box::new(move || { if let Some(app) = this.upgrade() { callback(&mut app.borrow_mut()); } })); self } /// Returns a handle to the [`BackgroundExecutor`] associated with this app, which can be used to spawn futures in the background. pub fn background_executor(&self) -> BackgroundExecutor { self.0.borrow().background_executor.clone() } /// Returns a handle to the [`ForegroundExecutor`] associated with this app, which can be used to spawn futures in the foreground. pub fn foreground_executor(&self) -> ForegroundExecutor { self.0.borrow().foreground_executor.clone() } /// Returns a reference to the [`TextSystem`] associated with this app. pub fn text_system(&self) -> Arc { self.0.borrow().text_system.clone() } /// Returns the file URL of the executable with the specified name in the application bundle pub fn path_for_auxiliary_executable(&self, name: &str) -> Result { self.0.borrow().path_for_auxiliary_executable(name) } } type Handler = Box bool + 'static>; type Listener = Box bool + 'static>; pub(crate) type KeystrokeObserver = Box bool + 'static>; type QuitHandler = Box LocalBoxFuture<'static, ()> + 'static>; type WindowClosedHandler = Box; type ReleaseListener = Box; type NewEntityListener = Box, &mut App) + 'static>; /// Defines when the application should automatically quit. #[derive(Debug, Clone, Copy, PartialEq, Eq, Default)] pub enum QuitMode { /// Use [`QuitMode::Explicit`] on macOS and [`QuitMode::LastWindowClosed`] on other platforms. #[default] Default, /// Quit automatically when the last window is closed. LastWindowClosed, /// Quit only when requested via [`App::quit`]. Explicit, } #[doc(hidden)] #[derive(Clone, PartialEq, Eq)] pub struct SystemWindowTab { pub id: WindowId, pub title: SharedString, pub handle: AnyWindowHandle, pub last_active_at: Instant, } impl SystemWindowTab { /// Create a new instance of the window tab. pub fn new(title: SharedString, handle: AnyWindowHandle) -> Self { Self { id: handle.id, title, handle, last_active_at: Instant::now(), } } } /// A controller for managing window tabs. #[derive(Default)] pub struct SystemWindowTabController { visible: Option, tab_groups: FxHashMap>, } impl Global for SystemWindowTabController {} impl SystemWindowTabController { /// Create a new instance of the window tab controller. pub fn new() -> Self { Self { visible: None, tab_groups: FxHashMap::default(), } } /// Initialize the global window tab controller. pub fn init(cx: &mut App) { cx.set_global(SystemWindowTabController::new()); } /// Get all tab groups. pub fn tab_groups(&self) -> &FxHashMap> { &self.tab_groups } /// Get the next tab group window handle. pub fn get_next_tab_group_window(cx: &mut App, id: WindowId) -> Option<&AnyWindowHandle> { let controller = cx.global::(); let current_group = controller .tab_groups .iter() .find_map(|(group, tabs)| tabs.iter().find(|tab| tab.id == id).map(|_| group)); let current_group = current_group?; // TODO: `.keys()` returns arbitrary order, what does "next" mean? let mut group_ids: Vec<_> = controller.tab_groups.keys().collect(); let idx = group_ids.iter().position(|g| *g == current_group)?; let next_idx = (idx + 1) % group_ids.len(); controller .tab_groups .get(group_ids[next_idx]) .and_then(|tabs| { tabs.iter() .max_by_key(|tab| tab.last_active_at) .or_else(|| tabs.first()) .map(|tab| &tab.handle) }) } /// Get the previous tab group window handle. pub fn get_prev_tab_group_window(cx: &mut App, id: WindowId) -> Option<&AnyWindowHandle> { let controller = cx.global::(); let current_group = controller .tab_groups .iter() .find_map(|(group, tabs)| tabs.iter().find(|tab| tab.id == id).map(|_| group)); let current_group = current_group?; // TODO: `.keys()` returns arbitrary order, what does "previous" mean? let mut group_ids: Vec<_> = controller.tab_groups.keys().collect(); let idx = group_ids.iter().position(|g| *g == current_group)?; let prev_idx = if idx == 0 { group_ids.len() - 1 } else { idx - 1 }; controller .tab_groups .get(group_ids[prev_idx]) .and_then(|tabs| { tabs.iter() .max_by_key(|tab| tab.last_active_at) .or_else(|| tabs.first()) .map(|tab| &tab.handle) }) } /// Get all tabs in the same window. pub fn tabs(&self, id: WindowId) -> Option<&Vec> { self.tab_groups .values() .find(|tabs| tabs.iter().any(|tab| tab.id == id)) } /// Initialize the visibility of the system window tab controller. pub fn init_visible(cx: &mut App, visible: bool) { let mut controller = cx.global_mut::(); if controller.visible.is_none() { controller.visible = Some(visible); } } /// Get the visibility of the system window tab controller. pub fn is_visible(&self) -> bool { self.visible.unwrap_or(false) } /// Set the visibility of the system window tab controller. pub fn set_visible(cx: &mut App, visible: bool) { let mut controller = cx.global_mut::(); controller.visible = Some(visible); } /// Update the last active of a window. pub fn update_last_active(cx: &mut App, id: WindowId) { let mut controller = cx.global_mut::(); for windows in controller.tab_groups.values_mut() { for tab in windows.iter_mut() { if tab.id == id { tab.last_active_at = Instant::now(); } } } } /// Update the position of a tab within its group. pub fn update_tab_position(cx: &mut App, id: WindowId, ix: usize) { let mut controller = cx.global_mut::(); for (_, windows) in controller.tab_groups.iter_mut() { if let Some(current_pos) = windows.iter().position(|tab| tab.id == id) { if ix < windows.len() && current_pos != ix { let window_tab = windows.remove(current_pos); windows.insert(ix, window_tab); } break; } } } /// Update the title of a tab. pub fn update_tab_title(cx: &mut App, id: WindowId, title: SharedString) { let controller = cx.global::(); let tab = controller .tab_groups .values() .flat_map(|windows| windows.iter()) .find(|tab| tab.id == id); if tab.map_or(true, |t| t.title == title) { return; } let mut controller = cx.global_mut::(); for windows in controller.tab_groups.values_mut() { for tab in windows.iter_mut() { if tab.id == id { tab.title = title; return; } } } } /// Insert a tab into a tab group. pub fn add_tab(cx: &mut App, id: WindowId, tabs: Vec) { let mut controller = cx.global_mut::(); let Some(tab) = tabs.iter().find(|tab| tab.id == id).cloned() else { return; }; let mut expected_tab_ids: Vec<_> = tabs .iter() .filter(|tab| tab.id != id) .map(|tab| tab.id) .sorted() .collect(); let mut tab_group_id = None; for (group_id, group_tabs) in &controller.tab_groups { let tab_ids: Vec<_> = group_tabs.iter().map(|tab| tab.id).sorted().collect(); if tab_ids == expected_tab_ids { tab_group_id = Some(*group_id); break; } } if let Some(tab_group_id) = tab_group_id { if let Some(tabs) = controller.tab_groups.get_mut(&tab_group_id) { tabs.push(tab); } } else { let new_group_id = controller.tab_groups.len(); controller.tab_groups.insert(new_group_id, tabs); } } /// Remove a tab from a tab group. pub fn remove_tab(cx: &mut App, id: WindowId) -> Option { let mut controller = cx.global_mut::(); let mut removed_tab = None; controller.tab_groups.retain(|_, tabs| { if let Some(pos) = tabs.iter().position(|tab| tab.id == id) { removed_tab = Some(tabs.remove(pos)); } !tabs.is_empty() }); removed_tab } /// Move a tab to a new tab group. pub fn move_tab_to_new_window(cx: &mut App, id: WindowId) { let mut removed_tab = Self::remove_tab(cx, id); let mut controller = cx.global_mut::(); if let Some(tab) = removed_tab { let new_group_id = controller.tab_groups.keys().max().map_or(0, |k| k + 1); controller.tab_groups.insert(new_group_id, vec![tab]); } } /// Merge all tab groups into a single group. pub fn merge_all_windows(cx: &mut App, id: WindowId) { let mut controller = cx.global_mut::(); let Some(initial_tabs) = controller.tabs(id) else { return; }; let initial_tabs_len = initial_tabs.len(); let mut all_tabs = initial_tabs.clone(); for (_, mut tabs) in controller.tab_groups.drain() { tabs.retain(|tab| !all_tabs[..initial_tabs_len].contains(tab)); all_tabs.extend(tabs); } controller.tab_groups.insert(0, all_tabs); } /// Selects the next tab in the tab group in the trailing direction. pub fn select_next_tab(cx: &mut App, id: WindowId) { let mut controller = cx.global_mut::(); let Some(tabs) = controller.tabs(id) else { return; }; let current_index = tabs.iter().position(|tab| tab.id == id).unwrap(); let next_index = (current_index + 1) % tabs.len(); let _ = &tabs[next_index].handle.update(cx, |_, window, _| { window.activate_window(); }); } /// Selects the previous tab in the tab group in the leading direction. pub fn select_previous_tab(cx: &mut App, id: WindowId) { let mut controller = cx.global_mut::(); let Some(tabs) = controller.tabs(id) else { return; }; let current_index = tabs.iter().position(|tab| tab.id == id).unwrap(); let previous_index = if current_index == 0 { tabs.len() - 1 } else { current_index - 1 }; let _ = &tabs[previous_index].handle.update(cx, |_, window, _| { window.activate_window(); }); } } pub(crate) enum GpuiMode { #[cfg(any(test, feature = "test-support"))] Test { skip_drawing: bool, }, Production, } impl GpuiMode { #[cfg(any(test, feature = "test-support"))] pub fn test() -> Self { GpuiMode::Test { skip_drawing: false, } } #[inline] pub(crate) fn skip_drawing(&self) -> bool { match self { #[cfg(any(test, feature = "test-support"))] GpuiMode::Test { skip_drawing } => *skip_drawing, GpuiMode::Production => false, } } } /// Contains the state of the full application, and passed as a reference to a variety of callbacks. /// Other [Context] derefs to this type. /// You need a reference to an `App` to access the state of a [Entity]. pub struct App { pub(crate) this: Weak, pub(crate) platform: Rc, text_system: Arc, pub(crate) actions: Rc, pub(crate) active_drag: Option, pub(crate) background_executor: BackgroundExecutor, pub(crate) foreground_executor: ForegroundExecutor, pub(crate) entities: EntityMap, pub(crate) new_entity_observers: SubscriberSet, pub(crate) windows: SlotMap>>, pub(crate) window_handles: FxHashMap, pub(crate) focus_handles: Arc, pub(crate) keymap: Rc>, pub(crate) keyboard_layout: Box, pub(crate) keyboard_mapper: Rc, pub(crate) global_action_listeners: FxHashMap>>, pending_effects: VecDeque, pub(crate) observers: SubscriberSet, pub(crate) event_listeners: SubscriberSet, pub(crate) keystroke_observers: SubscriberSet<(), KeystrokeObserver>, pub(crate) keystroke_interceptors: SubscriberSet<(), KeystrokeObserver>, pub(crate) keyboard_layout_observers: SubscriberSet<(), Handler>, pub(crate) thermal_state_observers: SubscriberSet<(), Handler>, pub(crate) release_listeners: SubscriberSet, pub(crate) global_observers: SubscriberSet, pub(crate) quit_observers: SubscriberSet<(), QuitHandler>, pub(crate) restart_observers: SubscriberSet<(), Handler>, pub(crate) window_closed_observers: SubscriberSet<(), WindowClosedHandler>, /// Per-App element arena. This isolates element allocations between different /// App instances (important for tests where multiple Apps run concurrently). pub(crate) element_arena: RefCell, /// Per-App event arena. pub(crate) event_arena: Arena, // Drop globals last. We need to ensure all tasks owned by entities and // callbacks are marked cancelled at this point as this will also shutdown // the tokio runtime. As any task attempting to spawn a blocking tokio task, // might panic. pub(crate) globals_by_type: FxHashMap>, // assets pub(crate) loading_assets: FxHashMap<(TypeId, u64), Box>, asset_source: Arc, pub(crate) svg_renderer: SvgRenderer, http_client: Arc, // below is plain data, the drop order is insignificant here pub(crate) pending_notifications: FxHashSet, pub(crate) pending_global_notifications: FxHashSet, pub(crate) restart_path: Option, pub(crate) layout_id_buffer: Vec, // We recycle this memory across layout requests. pub(crate) propagate_event: bool, pub(crate) prompt_builder: Option, pub(crate) window_invalidators_by_entity: FxHashMap>, pub(crate) tracked_entities: FxHashMap>, #[cfg(any(feature = "inspector", debug_assertions))] pub(crate) inspector_renderer: Option, #[cfg(any(feature = "inspector", debug_assertions))] pub(crate) inspector_element_registry: InspectorElementRegistry, #[cfg(any(test, feature = "test-support", debug_assertions))] pub(crate) name: Option<&'static str>, pub(crate) text_rendering_mode: Rc>, pub(crate) window_update_stack: Vec, pub(crate) mode: GpuiMode, flushing_effects: bool, pending_updates: usize, quit_mode: QuitMode, quitting: bool, // We need to ensure the leak detector drops last, after all tasks, callbacks and things have been dropped. // Otherwise it may report false positives. #[cfg(any(test, feature = "leak-detection"))] _ref_counts: Arc>, } impl App { #[allow(clippy::new_ret_no_self)] pub(crate) fn new_app( platform: Rc, asset_source: Arc, http_client: Arc, ) -> Rc { let background_executor = platform.background_executor(); let foreground_executor = platform.foreground_executor(); assert!( background_executor.is_main_thread(), "must construct App on main thread" ); let text_system = Arc::new(TextSystem::new(platform.text_system())); let entities = EntityMap::new(); let keyboard_layout = platform.keyboard_layout(); let keyboard_mapper = platform.keyboard_mapper(); #[cfg(any(test, feature = "leak-detection"))] let _ref_counts = entities.ref_counts_drop_handle(); let app = Rc::new_cyclic(|this| AppCell { app: RefCell::new(App { this: this.clone(), platform: platform.clone(), text_system, text_rendering_mode: Rc::new(Cell::new(TextRenderingMode::default())), mode: GpuiMode::Production, actions: Rc::new(ActionRegistry::default()), flushing_effects: false, pending_updates: 0, active_drag: None, background_executor, foreground_executor, svg_renderer: SvgRenderer::new(asset_source.clone()), loading_assets: Default::default(), asset_source, http_client, globals_by_type: FxHashMap::default(), entities, new_entity_observers: SubscriberSet::new(), windows: SlotMap::with_key(), window_update_stack: Vec::new(), window_handles: FxHashMap::default(), focus_handles: Arc::new(RwLock::new(SlotMap::with_key())), keymap: Rc::new(RefCell::new(Keymap::default())), keyboard_layout, keyboard_mapper, global_action_listeners: FxHashMap::default(), pending_effects: VecDeque::new(), pending_notifications: FxHashSet::default(), pending_global_notifications: FxHashSet::default(), observers: SubscriberSet::new(), tracked_entities: FxHashMap::default(), window_invalidators_by_entity: FxHashMap::default(), event_listeners: SubscriberSet::new(), release_listeners: SubscriberSet::new(), keystroke_observers: SubscriberSet::new(), keystroke_interceptors: SubscriberSet::new(), keyboard_layout_observers: SubscriberSet::new(), thermal_state_observers: SubscriberSet::new(), global_observers: SubscriberSet::new(), quit_observers: SubscriberSet::new(), restart_observers: SubscriberSet::new(), restart_path: None, window_closed_observers: SubscriberSet::new(), layout_id_buffer: Default::default(), propagate_event: true, prompt_builder: Some(PromptBuilder::Default), #[cfg(any(feature = "inspector", debug_assertions))] inspector_renderer: None, #[cfg(any(feature = "inspector", debug_assertions))] inspector_element_registry: InspectorElementRegistry::default(), quit_mode: QuitMode::default(), quitting: false, #[cfg(any(test, feature = "test-support", debug_assertions))] name: None, element_arena: RefCell::new(Arena::new(1024 * 1024)), event_arena: Arena::new(1024 * 1024), #[cfg(any(test, feature = "leak-detection"))] _ref_counts, }), }); init_app_menus(platform.as_ref(), &app.borrow()); SystemWindowTabController::init(&mut app.borrow_mut()); platform.on_keyboard_layout_change(Box::new({ let app = Rc::downgrade(&app); move || { if let Some(app) = app.upgrade() { let cx = &mut app.borrow_mut(); cx.keyboard_layout = cx.platform.keyboard_layout(); cx.keyboard_mapper = cx.platform.keyboard_mapper(); cx.keyboard_layout_observers .clone() .retain(&(), move |callback| (callback)(cx)); } } })); platform.on_thermal_state_change(Box::new({ let app = Rc::downgrade(&app); move || { if let Some(app) = app.upgrade() { let cx = &mut app.borrow_mut(); cx.thermal_state_observers .clone() .retain(&(), move |callback| (callback)(cx)); } } })); platform.on_quit(Box::new({ let cx = Rc::downgrade(&app); move || { if let Some(cx) = cx.upgrade() { cx.borrow_mut().shutdown(); } } })); app } #[doc(hidden)] pub fn ref_counts_drop_handle(&self) -> impl Sized + use<> { self.entities.ref_counts_drop_handle() } /// Captures a snapshot of all entities that currently have alive handles. /// /// The returned [`LeakDetectorSnapshot`] can later be passed to /// [`assert_no_new_leaks`](Self::assert_no_new_leaks) to verify that no /// entities created after the snapshot are still alive. #[cfg(any(test, feature = "leak-detection"))] pub fn leak_detector_snapshot(&self) -> LeakDetectorSnapshot { self.entities.leak_detector_snapshot() } /// Asserts that no entities created after `snapshot` still have alive handles. /// /// Entities that were already tracked at the time of the snapshot are ignored, /// even if they still have handles. Only *new* entities (those whose /// `EntityId` was not present in the snapshot) are considered leaks. /// /// # Panics /// /// Panics if any new entity handles exist. The panic message lists every /// leaked entity with its type name, and includes allocation-site backtraces /// when `LEAK_BACKTRACE` is set. #[cfg(any(test, feature = "leak-detection"))] pub fn assert_no_new_leaks(&self, snapshot: &LeakDetectorSnapshot) { self.entities.assert_no_new_leaks(snapshot) } /// Quit the application gracefully. Handlers registered with [`Context::on_app_quit`] /// will be given 100ms to complete before exiting. pub fn shutdown(&mut self) { let mut futures = Vec::new(); for observer in self.quit_observers.remove(&()) { futures.push(observer(self)); } self.windows.clear(); self.window_handles.clear(); self.flush_effects(); self.quitting = true; let futures = futures::future::join_all(futures); if self .foreground_executor .block_with_timeout(SHUTDOWN_TIMEOUT, futures) .is_err() { log::error!("timed out waiting on app_will_quit"); } self.quitting = false; } /// Get the id of the current keyboard layout pub fn keyboard_layout(&self) -> &dyn PlatformKeyboardLayout { self.keyboard_layout.as_ref() } /// Get the current keyboard mapper. pub fn keyboard_mapper(&self) -> &Rc { &self.keyboard_mapper } /// Invokes a handler when the current keyboard layout changes pub fn on_keyboard_layout_change(&self, mut callback: F) -> Subscription where F: 'static + FnMut(&mut App), { let (subscription, activate) = self.keyboard_layout_observers.insert( (), Box::new(move |cx| { callback(cx); true }), ); activate(); subscription } /// Gracefully quit the application via the platform's standard routine. pub fn quit(&self) { self.platform.quit(); } /// Schedules all windows in the application to be redrawn. This can be called /// multiple times in an update cycle and still result in a single redraw. pub fn refresh_windows(&mut self) { self.pending_effects.push_back(Effect::RefreshWindows); } pub(crate) fn update(&mut self, update: impl FnOnce(&mut Self) -> R) -> R { self.start_update(); let result = update(self); self.finish_update(); result } pub(crate) fn start_update(&mut self) { self.pending_updates += 1; } pub(crate) fn finish_update(&mut self) { if !self.flushing_effects && self.pending_updates == 1 { self.flushing_effects = true; self.flush_effects(); self.flushing_effects = false; } self.pending_updates -= 1; } /// Arrange a callback to be invoked when the given entity calls `notify` on its respective context. pub fn observe( &mut self, entity: &Entity, mut on_notify: impl FnMut(Entity, &mut App) + 'static, ) -> Subscription where W: 'static, { self.observe_internal(entity, move |e, cx| { on_notify(e, cx); true }) } pub(crate) fn detect_accessed_entities( &mut self, callback: impl FnOnce(&mut App) -> R, ) -> (R, FxHashSet) { let accessed_entities_start = self.entities.accessed_entities.get_mut().clone(); let result = callback(self); let entities_accessed_in_callback = self .entities .accessed_entities .get_mut() .difference(&accessed_entities_start) .copied() .collect::>(); (result, entities_accessed_in_callback) } pub(crate) fn record_entities_accessed( &mut self, window_handle: AnyWindowHandle, invalidator: WindowInvalidator, entities: &FxHashSet, ) { let mut tracked_entities = std::mem::take(self.tracked_entities.entry(window_handle.id).or_default()); for entity in tracked_entities.iter() { self.window_invalidators_by_entity .entry(*entity) .and_modify(|windows| { windows.remove(&window_handle.id); }); } for entity in entities.iter() { self.window_invalidators_by_entity .entry(*entity) .or_default() .insert(window_handle.id, invalidator.clone()); } tracked_entities.clear(); tracked_entities.extend(entities.iter().copied()); self.tracked_entities .insert(window_handle.id, tracked_entities); } pub(crate) fn new_observer(&mut self, key: EntityId, value: Handler) -> Subscription { let (subscription, activate) = self.observers.insert(key, value); self.defer(move |_| activate()); subscription } pub(crate) fn observe_internal( &mut self, entity: &Entity, mut on_notify: impl FnMut(Entity, &mut App) -> bool + 'static, ) -> Subscription where W: 'static, { let entity_id = entity.entity_id(); let handle = entity.downgrade(); self.new_observer( entity_id, Box::new(move |cx| { if let Some(entity) = handle.upgrade() { on_notify(entity, cx) } else { false } }), ) } /// Arrange for the given callback to be invoked whenever the given entity emits an event of a given type. /// The callback is provided a handle to the emitting entity and a reference to the emitted event. pub fn subscribe( &mut self, entity: &Entity, mut on_event: impl FnMut(Entity, &Event, &mut App) + 'static, ) -> Subscription where T: 'static + EventEmitter, Event: 'static, { self.subscribe_internal(entity, move |entity, event, cx| { on_event(entity, event, cx); true }) } pub(crate) fn new_subscription( &mut self, key: EntityId, value: (TypeId, Listener), ) -> Subscription { let (subscription, activate) = self.event_listeners.insert(key, value); self.defer(move |_| activate()); subscription } pub(crate) fn subscribe_internal( &mut self, entity: &Entity, mut on_event: impl FnMut(Entity, &Evt, &mut App) -> bool + 'static, ) -> Subscription where T: 'static + EventEmitter, Evt: 'static, { let entity_id = entity.entity_id(); let handle = entity.downgrade(); self.new_subscription( entity_id, ( TypeId::of::(), Box::new(move |event, cx| { let event: &Evt = event.downcast_ref().expect("invalid event type"); if let Some(entity) = handle.upgrade() { on_event(entity, event, cx) } else { false } }), ), ) } /// Returns handles to all open windows in the application. /// Each handle could be downcast to a handle typed for the root view of that window. /// To find all windows of a given type, you could filter on pub fn windows(&self) -> Vec { self.windows .keys() .flat_map(|window_id| self.window_handles.get(&window_id).copied()) .collect() } /// Returns the window handles ordered by their appearance on screen, front to back. /// /// The first window in the returned list is the active/topmost window of the application. /// /// This method returns None if the platform doesn't implement the method yet. pub fn window_stack(&self) -> Option> { self.platform.window_stack() } /// Returns a handle to the window that is currently focused at the platform level, if one exists. pub fn active_window(&self) -> Option { self.platform.active_window() } /// Opens a new window with the given option and the root view returned by the given function. /// The function is invoked with a `Window`, which can be used to interact with window-specific /// functionality. pub fn open_window( &mut self, options: crate::WindowOptions, build_root_view: impl FnOnce(&mut Window, &mut App) -> Entity, ) -> anyhow::Result> { self.update(|cx| { let id = cx.windows.insert(None); let handle = WindowHandle::new(id); match Window::new(handle.into(), options, cx) { Ok(mut window) => { cx.window_update_stack.push(id); let root_view = build_root_view(&mut window, cx); cx.window_update_stack.pop(); window.root.replace(root_view.into()); window.defer(cx, |window: &mut Window, cx| window.appearance_changed(cx)); // allow a window to draw at least once before returning // this didn't cause any issues on non windows platforms as it seems we always won the race to on_request_frame // on windows we quite frequently lose the race and return a window that has never rendered, which leads to a crash // where DispatchTree::root_node_id asserts on empty nodes let clear = window.draw(cx); clear.clear(); cx.window_handles.insert(id, window.handle); cx.windows.get_mut(id).unwrap().replace(Box::new(window)); Ok(handle) } Err(e) => { cx.windows.remove(id); Err(e) } } }) } /// Instructs the platform to activate the application by bringing it to the foreground. pub fn activate(&self, ignoring_other_apps: bool) { self.platform.activate(ignoring_other_apps); } /// Hide the application at the platform level. pub fn hide(&self) { self.platform.hide(); } /// Hide other applications at the platform level. pub fn hide_other_apps(&self) { self.platform.hide_other_apps(); } /// Unhide other applications at the platform level. pub fn unhide_other_apps(&self) { self.platform.unhide_other_apps(); } /// Returns the list of currently active displays. pub fn displays(&self) -> Vec> { self.platform.displays() } /// Returns the primary display that will be used for new windows. pub fn primary_display(&self) -> Option> { self.platform.primary_display() } /// Returns whether `screen_capture_sources` may work. pub fn is_screen_capture_supported(&self) -> bool { self.platform.is_screen_capture_supported() } /// Returns a list of available screen capture sources. pub fn screen_capture_sources( &self, ) -> oneshot::Receiver>>> { self.platform.screen_capture_sources() } /// Returns the display with the given ID, if one exists. pub fn find_display(&self, id: DisplayId) -> Option> { self.displays() .iter() .find(|display| display.id() == id) .cloned() } /// Returns the current thermal state of the system. pub fn thermal_state(&self) -> ThermalState { self.platform.thermal_state() } /// Invokes a handler when the thermal state changes pub fn on_thermal_state_change(&self, mut callback: F) -> Subscription where F: 'static + FnMut(&mut App), { let (subscription, activate) = self.thermal_state_observers.insert( (), Box::new(move |cx| { callback(cx); true }), ); activate(); subscription } /// Returns the appearance of the application's windows. pub fn window_appearance(&self) -> WindowAppearance { self.platform.window_appearance() } /// Returns the window button layout configuration when supported. pub fn button_layout(&self) -> Option { self.platform.button_layout() } /// Reads data from the platform clipboard. pub fn read_from_clipboard(&self) -> Option { self.platform.read_from_clipboard() } /// Sets the text rendering mode for the application. pub fn set_text_rendering_mode(&mut self, mode: TextRenderingMode) { self.text_rendering_mode.set(mode); } /// Returns the current text rendering mode for the application. pub fn text_rendering_mode(&self) -> TextRenderingMode { self.text_rendering_mode.get() } /// Writes data to the platform clipboard. pub fn write_to_clipboard(&self, item: ClipboardItem) { self.platform.write_to_clipboard(item) } /// Reads data from the primary selection buffer. /// Only available on Linux. #[cfg(any(target_os = "linux", target_os = "freebsd"))] pub fn read_from_primary(&self) -> Option { self.platform.read_from_primary() } /// Writes data to the primary selection buffer. /// Only available on Linux. #[cfg(any(target_os = "linux", target_os = "freebsd"))] pub fn write_to_primary(&self, item: ClipboardItem) { self.platform.write_to_primary(item) } /// Reads data from macOS's "Find" pasteboard. /// /// Used to share the current search string between apps. /// /// https://developer.apple.com/documentation/appkit/nspasteboard/name-swift.struct/find #[cfg(target_os = "macos")] pub fn read_from_find_pasteboard(&self) -> Option { self.platform.read_from_find_pasteboard() } /// Writes data to macOS's "Find" pasteboard. /// /// Used to share the current search string between apps. /// /// https://developer.apple.com/documentation/appkit/nspasteboard/name-swift.struct/find #[cfg(target_os = "macos")] pub fn write_to_find_pasteboard(&self, item: ClipboardItem) { self.platform.write_to_find_pasteboard(item) } /// Writes credentials to the platform keychain. pub fn write_credentials( &self, url: &str, username: &str, password: &[u8], ) -> Task> { self.platform.write_credentials(url, username, password) } /// Reads credentials from the platform keychain. pub fn read_credentials(&self, url: &str) -> Task)>>> { self.platform.read_credentials(url) } /// Deletes credentials from the platform keychain. pub fn delete_credentials(&self, url: &str) -> Task> { self.platform.delete_credentials(url) } /// Directs the platform's default browser to open the given URL. pub fn open_url(&self, url: &str) { self.platform.open_url(url); } /// Registers the given URL scheme (e.g. `zed` for `zed://` urls) to be /// opened by the current app. /// /// On some platforms (e.g. macOS) you may be able to register URL schemes /// as part of app distribution, but this method exists to let you register /// schemes at runtime. pub fn register_url_scheme(&self, scheme: &str) -> Task> { self.platform.register_url_scheme(scheme) } /// Returns the full pathname of the current app bundle. /// /// Returns an error if the app is not being run from a bundle. pub fn app_path(&self) -> Result { self.platform.app_path() } /// On Linux, returns the name of the compositor in use. /// /// Returns an empty string on other platforms. pub fn compositor_name(&self) -> &'static str { self.platform.compositor_name() } /// Returns the file URL of the executable with the specified name in the application bundle pub fn path_for_auxiliary_executable(&self, name: &str) -> Result { self.platform.path_for_auxiliary_executable(name) } /// Displays a platform modal for selecting paths. /// /// When one or more paths are selected, they'll be relayed asynchronously via the returned oneshot channel. /// If cancelled, a `None` will be relayed instead. /// May return an error on Linux if the file picker couldn't be opened. pub fn prompt_for_paths( &self, options: PathPromptOptions, ) -> oneshot::Receiver>>> { self.platform.prompt_for_paths(options) } /// Displays a platform modal for selecting a new path where a file can be saved. /// /// The provided directory will be used to set the initial location. /// When a path is selected, it is relayed asynchronously via the returned oneshot channel. /// If cancelled, a `None` will be relayed instead. /// May return an error on Linux if the file picker couldn't be opened. pub fn prompt_for_new_path( &self, directory: &Path, suggested_name: Option<&str>, ) -> oneshot::Receiver>> { self.platform.prompt_for_new_path(directory, suggested_name) } /// Reveals the specified path at the platform level, such as in Finder on macOS. pub fn reveal_path(&self, path: &Path) { self.platform.reveal_path(path) } /// Opens the specified path with the system's default application. pub fn open_with_system(&self, path: &Path) { self.platform.open_with_system(path) } /// Returns whether the user has configured scrollbars to auto-hide at the platform level. pub fn should_auto_hide_scrollbars(&self) -> bool { self.platform.should_auto_hide_scrollbars() } /// Restarts the application. pub fn restart(&mut self) { self.restart_observers .clone() .retain(&(), |observer| observer(self)); self.platform.restart(self.restart_path.take()) } /// Sets the path to use when restarting the application. pub fn set_restart_path(&mut self, path: PathBuf) { self.restart_path = Some(path); } /// Returns the HTTP client for the application. pub fn http_client(&self) -> Arc { self.http_client.clone() } /// Sets the HTTP client for the application. pub fn set_http_client(&mut self, new_client: Arc) { self.http_client = new_client; } /// Configures when the application should automatically quit. /// By default, [`QuitMode::Default`] is used. pub fn set_quit_mode(&mut self, mode: QuitMode) { self.quit_mode = mode; } /// Returns the SVG renderer used by the application. pub fn svg_renderer(&self) -> SvgRenderer { self.svg_renderer.clone() } pub(crate) fn push_effect(&mut self, effect: Effect) { match &effect { Effect::Notify { emitter } => { if !self.pending_notifications.insert(*emitter) { return; } } Effect::NotifyGlobalObservers { global_type } => { if !self.pending_global_notifications.insert(*global_type) { return; } } _ => {} }; self.pending_effects.push_back(effect); } /// Called at the end of [`App::update`] to complete any side effects /// such as notifying observers, emitting events, etc. Effects can themselves /// cause effects, so we continue looping until all effects are processed. fn flush_effects(&mut self) { loop { self.release_dropped_entities(); self.release_dropped_focus_handles(); if let Some(effect) = self.pending_effects.pop_front() { match effect { Effect::Notify { emitter } => { self.apply_notify_effect(emitter); } Effect::Emit { emitter, event_type, event, } => self.apply_emit_effect(emitter, event_type, &*event), Effect::RefreshWindows => { self.apply_refresh_effect(); } Effect::NotifyGlobalObservers { global_type } => { self.apply_notify_global_observers_effect(global_type); } Effect::Defer { callback } => { self.apply_defer_effect(callback); } Effect::EntityCreated { entity, tid, window, } => { self.apply_entity_created_effect(entity, tid, window); } } } else { #[cfg(any(test, feature = "test-support"))] for window in self .windows .values() .filter_map(|window| { let window = window.as_deref()?; window.invalidator.is_dirty().then_some(window.handle) }) .collect::>() { self.update_window(window, |_, window, cx| window.draw(cx).clear()) .unwrap(); } if self.pending_effects.is_empty() { self.event_arena.clear(); break; } } } } /// Repeatedly called during `flush_effects` to release any entities whose /// reference count has become zero. We invoke any release observers before dropping /// each entity. fn release_dropped_entities(&mut self) { loop { let dropped = self.entities.take_dropped(); if dropped.is_empty() { break; } for (entity_id, mut entity) in dropped { self.observers.remove(&entity_id); self.event_listeners.remove(&entity_id); for release_callback in self.release_listeners.remove(&entity_id) { release_callback(entity.as_mut(), self); } } } } /// Repeatedly called during `flush_effects` to handle a focused handle being dropped. fn release_dropped_focus_handles(&mut self) { self.focus_handles .clone() .write() .retain(|handle_id, focus| { if focus.ref_count.load(SeqCst) == 0 { for window_handle in self.windows() { window_handle .update(self, |_, window, _| { if window.focus == Some(handle_id) { window.blur(); } }) .unwrap(); } false } else { true } }); } fn apply_notify_effect(&mut self, emitter: EntityId) { self.pending_notifications.remove(&emitter); self.observers .clone() .retain(&emitter, |handler| handler(self)); } fn apply_emit_effect(&mut self, emitter: EntityId, event_type: TypeId, event: &dyn Any) { self.event_listeners .clone() .retain(&emitter, |(stored_type, handler)| { if *stored_type == event_type { handler(event, self) } else { true } }); } fn apply_refresh_effect(&mut self) { for window in self.windows.values_mut() { if let Some(window) = window.as_deref_mut() { window.refreshing = true; window.invalidator.set_dirty(true); } } } fn apply_notify_global_observers_effect(&mut self, type_id: TypeId) { self.pending_global_notifications.remove(&type_id); self.global_observers .clone() .retain(&type_id, |observer| observer(self)); } fn apply_defer_effect(&mut self, callback: Box) { callback(self); } fn apply_entity_created_effect( &mut self, entity: AnyEntity, tid: TypeId, window: Option, ) { self.new_entity_observers.clone().retain(&tid, |observer| { if let Some(id) = window { self.update_window_id(id, { let entity = entity.clone(); |_, window, cx| (observer)(entity, &mut Some(window), cx) }) .expect("All windows should be off the stack when flushing effects"); } else { (observer)(entity.clone(), &mut None, self) } true }); } fn update_window_id(&mut self, id: WindowId, update: F) -> Result where F: FnOnce(AnyView, &mut Window, &mut App) -> T, { self.update(|cx| { let mut window = cx.windows.get_mut(id)?.take()?; let root_view = window.root.clone().unwrap(); cx.window_update_stack.push(window.handle.id); let result = update(root_view, &mut window, cx); fn trail(id: WindowId, window: Box, cx: &mut App) -> Option<()> { cx.window_update_stack.pop(); if window.removed { cx.window_handles.remove(&id); cx.windows.remove(id); cx.window_closed_observers.clone().retain(&(), |callback| { callback(cx, id); true }); let quit_on_empty = match cx.quit_mode { QuitMode::Explicit => false, QuitMode::LastWindowClosed => true, QuitMode::Default => cfg!(not(target_os = "macos")), }; if quit_on_empty && cx.windows.is_empty() { cx.quit(); } } else { cx.windows.get_mut(id)?.replace(window); } Some(()) } trail(id, window, cx)?; Some(result) }) .context("window not found") } /// Creates an `AsyncApp`, which can be cloned and has a static lifetime /// so it can be held across `await` points. pub fn to_async(&self) -> AsyncApp { AsyncApp { app: self.this.clone(), background_executor: self.background_executor.clone(), foreground_executor: self.foreground_executor.clone(), } } /// Obtains a reference to the executor, which can be used to spawn futures. pub fn background_executor(&self) -> &BackgroundExecutor { &self.background_executor } /// Obtains a reference to the executor, which can be used to spawn futures. pub fn foreground_executor(&self) -> &ForegroundExecutor { if self.quitting { panic!("Can't spawn on main thread after on_app_quit") }; &self.foreground_executor } /// Spawns the future returned by the given function on the main thread. The closure will be invoked /// with [AsyncApp], which allows the application state to be accessed across await points. #[track_caller] pub fn spawn(&self, f: AsyncFn) -> Task where AsyncFn: AsyncFnOnce(&mut AsyncApp) -> R + 'static, R: 'static, { if self.quitting { debug_panic!("Can't spawn on main thread after on_app_quit") }; let mut cx = self.to_async(); self.foreground_executor .spawn(async move { f(&mut cx).await }.boxed_local()) } /// Spawns the future returned by the given function on the main thread with /// the given priority. The closure will be invoked with [AsyncApp], which /// allows the application state to be accessed across await points. pub fn spawn_with_priority(&self, priority: Priority, f: AsyncFn) -> Task where AsyncFn: AsyncFnOnce(&mut AsyncApp) -> R + 'static, R: 'static, { if self.quitting { debug_panic!("Can't spawn on main thread after on_app_quit") }; let mut cx = self.to_async(); self.foreground_executor .spawn_with_priority(priority, async move { f(&mut cx).await }.boxed_local()) } /// Schedules the given function to be run at the end of the current effect cycle, allowing entities /// that are currently on the stack to be returned to the app. pub fn defer(&mut self, f: impl FnOnce(&mut App) + 'static) { self.push_effect(Effect::Defer { callback: Box::new(f), }); } /// Accessor for the application's asset source, which is provided when constructing the `App`. pub fn asset_source(&self) -> &Arc { &self.asset_source } /// Accessor for the text system. pub fn text_system(&self) -> &Arc { &self.text_system } /// Check whether a global of the given type has been assigned. pub fn has_global(&self) -> bool { self.globals_by_type.contains_key(&TypeId::of::()) } /// Access the global of the given type. Panics if a global for that type has not been assigned. #[track_caller] pub fn global(&self) -> &G { self.globals_by_type .get(&TypeId::of::()) .map(|any_state| any_state.downcast_ref::().unwrap()) .with_context(|| format!("no state of type {} exists", type_name::())) .unwrap() } /// Access the global of the given type if a value has been assigned. pub fn try_global(&self) -> Option<&G> { self.globals_by_type .get(&TypeId::of::()) .map(|any_state| any_state.downcast_ref::().unwrap()) } /// Access the global of the given type mutably. Panics if a global for that type has not been assigned. #[track_caller] pub fn global_mut(&mut self) -> &mut G { let global_type = TypeId::of::(); self.push_effect(Effect::NotifyGlobalObservers { global_type }); self.globals_by_type .get_mut(&global_type) .and_then(|any_state| any_state.downcast_mut::()) .with_context(|| format!("no state of type {} exists", type_name::())) .unwrap() } /// Access the global of the given type mutably. A default value is assigned if a global of this type has not /// yet been assigned. pub fn default_global(&mut self) -> &mut G { let global_type = TypeId::of::(); self.push_effect(Effect::NotifyGlobalObservers { global_type }); self.globals_by_type .entry(global_type) .or_insert_with(|| Box::::default()) .downcast_mut::() .unwrap() } /// Sets the value of the global of the given type. pub fn set_global(&mut self, global: G) { let global_type = TypeId::of::(); self.push_effect(Effect::NotifyGlobalObservers { global_type }); self.globals_by_type.insert(global_type, Box::new(global)); } /// Clear all stored globals. Does not notify global observers. #[cfg(any(test, feature = "test-support"))] pub fn clear_globals(&mut self) { self.globals_by_type.drain(); } /// Remove the global of the given type from the app context. Does not notify global observers. pub fn remove_global(&mut self) -> G { let global_type = TypeId::of::(); self.push_effect(Effect::NotifyGlobalObservers { global_type }); *self .globals_by_type .remove(&global_type) .unwrap_or_else(|| panic!("no global added for {}", std::any::type_name::())) .downcast() .unwrap() } /// Register a callback to be invoked when a global of the given type is updated. pub fn observe_global( &mut self, mut f: impl FnMut(&mut Self) + 'static, ) -> Subscription { let (subscription, activate) = self.global_observers.insert( TypeId::of::(), Box::new(move |cx| { f(cx); true }), ); self.defer(move |_| activate()); subscription } /// Move the global of the given type to the stack. #[track_caller] pub(crate) fn lease_global(&mut self) -> GlobalLease { GlobalLease::new( self.globals_by_type .remove(&TypeId::of::()) .with_context(|| format!("no global registered of type {}", type_name::())) .unwrap(), ) } /// Restore the global of the given type after it is moved to the stack. pub(crate) fn end_global_lease(&mut self, lease: GlobalLease) { let global_type = TypeId::of::(); self.push_effect(Effect::NotifyGlobalObservers { global_type }); self.globals_by_type.insert(global_type, lease.global); } pub(crate) fn new_entity_observer( &self, key: TypeId, value: NewEntityListener, ) -> Subscription { let (subscription, activate) = self.new_entity_observers.insert(key, value); activate(); subscription } /// Arrange for the given function to be invoked whenever a view of the specified type is created. /// The function will be passed a mutable reference to the view along with an appropriate context. pub fn observe_new( &self, on_new: impl 'static + Fn(&mut T, Option<&mut Window>, &mut Context), ) -> Subscription { self.new_entity_observer( TypeId::of::(), Box::new( move |any_entity: AnyEntity, window: &mut Option<&mut Window>, cx: &mut App| { any_entity .downcast::() .unwrap() .update(cx, |entity_state, cx| { on_new(entity_state, window.as_deref_mut(), cx) }) }, ), ) } /// Observe the release of a entity. The callback is invoked after the entity /// has no more strong references but before it has been dropped. pub fn observe_release( &self, handle: &Entity, on_release: impl FnOnce(&mut T, &mut App) + 'static, ) -> Subscription where T: 'static, { let (subscription, activate) = self.release_listeners.insert( handle.entity_id(), Box::new(move |entity, cx| { let entity = entity.downcast_mut().expect("invalid entity type"); on_release(entity, cx) }), ); activate(); subscription } /// Observe the release of a entity. The callback is invoked after the entity /// has no more strong references but before it has been dropped. pub fn observe_release_in( &self, handle: &Entity, window: &Window, on_release: impl FnOnce(&mut T, &mut Window, &mut App) + 'static, ) -> Subscription where T: 'static, { let window_handle = window.handle; self.observe_release(handle, move |entity, cx| { let _ = window_handle.update(cx, |_, window, cx| on_release(entity, window, cx)); }) } /// Register a callback to be invoked when a keystroke is received by the application /// in any window. Note that this fires after all other action and event mechanisms have resolved /// and that this API will not be invoked if the event's propagation is stopped. pub fn observe_keystrokes( &mut self, mut f: impl FnMut(&KeystrokeEvent, &mut Window, &mut App) + 'static, ) -> Subscription { fn inner( keystroke_observers: &SubscriberSet<(), KeystrokeObserver>, handler: KeystrokeObserver, ) -> Subscription { let (subscription, activate) = keystroke_observers.insert((), handler); activate(); subscription } inner( &self.keystroke_observers, Box::new(move |event, window, cx| { f(event, window, cx); true }), ) } /// Register a callback to be invoked when a keystroke is received by the application /// in any window. Note that this fires _before_ all other action and event mechanisms have resolved /// unlike [`App::observe_keystrokes`] which fires after. This means that `cx.stop_propagation` calls /// within interceptors will prevent action dispatch pub fn intercept_keystrokes( &mut self, mut f: impl FnMut(&KeystrokeEvent, &mut Window, &mut App) + 'static, ) -> Subscription { fn inner( keystroke_interceptors: &SubscriberSet<(), KeystrokeObserver>, handler: KeystrokeObserver, ) -> Subscription { let (subscription, activate) = keystroke_interceptors.insert((), handler); activate(); subscription } inner( &self.keystroke_interceptors, Box::new(move |event, window, cx| { f(event, window, cx); true }), ) } /// Register key bindings. pub fn bind_keys(&mut self, bindings: impl IntoIterator) { self.keymap.borrow_mut().add_bindings(bindings); self.pending_effects.push_back(Effect::RefreshWindows); } /// Clear all key bindings in the app. pub fn clear_key_bindings(&mut self) { self.keymap.borrow_mut().clear(); self.pending_effects.push_back(Effect::RefreshWindows); } /// Get all key bindings in the app. pub fn key_bindings(&self) -> Rc> { self.keymap.clone() } /// Register a global handler for actions invoked via the keyboard. These handlers are run at /// the end of the bubble phase for actions, and so will only be invoked if there are no other /// handlers or if they called `cx.propagate()`. pub fn on_action( &mut self, listener: impl Fn(&A, &mut Self) + 'static, ) -> &mut Self { self.global_action_listeners .entry(TypeId::of::()) .or_default() .push(Rc::new(move |action, phase, cx| { if phase == DispatchPhase::Bubble { let action = action.downcast_ref().unwrap(); listener(action, cx) } })); self } /// Event handlers propagate events by default. Call this method to stop dispatching to /// event handlers with a lower z-index (mouse) or higher in the tree (keyboard). This is /// the opposite of [`Self::propagate`]. It's also possible to cancel a call to [`Self::propagate`] by /// calling this method before effects are flushed. pub fn stop_propagation(&mut self) { self.propagate_event = false; } /// Action handlers stop propagation by default during the bubble phase of action dispatch /// dispatching to action handlers higher in the element tree. This is the opposite of /// [`Self::stop_propagation`]. It's also possible to cancel a call to [`Self::stop_propagation`] by calling /// this method before effects are flushed. pub fn propagate(&mut self) { self.propagate_event = true; } /// Build an action from some arbitrary data, typically a keymap entry. pub fn build_action( &self, name: &str, data: Option, ) -> std::result::Result, ActionBuildError> { self.actions.build_action(name, data) } /// Get all action names that have been registered. Note that registration only allows for /// actions to be built dynamically, and is unrelated to binding actions in the element tree. pub fn all_action_names(&self) -> &[&'static str] { self.actions.all_action_names() } /// Returns key bindings that invoke the given action on the currently focused element, without /// checking context. Bindings are returned in the order they were added. For display, the last /// binding should take precedence. pub fn all_bindings_for_input(&self, input: &[Keystroke]) -> Vec { RefCell::borrow(&self.keymap).all_bindings_for_input(input) } /// Get all non-internal actions that have been registered, along with their schemas. pub fn action_schemas( &self, generator: &mut schemars::SchemaGenerator, ) -> Vec<(&'static str, Option)> { self.actions.action_schemas(generator) } /// Get the schema for a specific action by name. /// Returns `None` if the action is not found. /// Returns `Some(None)` if the action exists but has no schema. /// Returns `Some(Some(schema))` if the action exists and has a schema. pub fn action_schema_by_name( &self, name: &str, generator: &mut schemars::SchemaGenerator, ) -> Option> { self.actions.action_schema_by_name(name, generator) } /// Get a map from a deprecated action name to the canonical name. pub fn deprecated_actions_to_preferred_actions(&self) -> &HashMap<&'static str, &'static str> { self.actions.deprecated_aliases() } /// Get a map from an action name to the deprecation messages. pub fn action_deprecation_messages(&self) -> &HashMap<&'static str, &'static str> { self.actions.deprecation_messages() } /// Get a map from an action name to the documentation. pub fn action_documentation(&self) -> &HashMap<&'static str, &'static str> { self.actions.documentation() } /// Register a callback to be invoked when the application is about to quit. /// It is not possible to cancel the quit event at this point. pub fn on_app_quit( &self, mut on_quit: impl FnMut(&mut App) -> Fut + 'static, ) -> Subscription where Fut: 'static + Future, { let (subscription, activate) = self.quit_observers.insert( (), Box::new(move |cx| { let future = on_quit(cx); future.boxed_local() }), ); activate(); subscription } /// Register a callback to be invoked when the application is about to restart. /// /// These callbacks are called before any `on_app_quit` callbacks. pub fn on_app_restart(&self, mut on_restart: impl 'static + FnMut(&mut App)) -> Subscription { let (subscription, activate) = self.restart_observers.insert( (), Box::new(move |cx| { on_restart(cx); true }), ); activate(); subscription } /// Register a callback to be invoked when a window is closed /// The window is no longer accessible at the point this callback is invoked. pub fn on_window_closed( &self, mut on_closed: impl FnMut(&mut App, WindowId) + 'static, ) -> Subscription { let (subscription, activate) = self.window_closed_observers.insert((), Box::new(on_closed)); activate(); subscription } pub(crate) fn clear_pending_keystrokes(&mut self) { for window in self.windows() { window .update(self, |_, window, cx| { if window.pending_input_keystrokes().is_some() { window.clear_pending_keystrokes(); window.pending_input_changed(cx); } }) .ok(); } } /// Checks if the given action is bound in the current context, as defined by the app's current focus, /// the bindings in the element tree, and any global action listeners. pub fn is_action_available(&mut self, action: &dyn Action) -> bool { let mut action_available = false; if let Some(window) = self.active_window() && let Ok(window_action_available) = window.update(self, |_, window, cx| window.is_action_available(action, cx)) { action_available = window_action_available; } action_available || self .global_action_listeners .contains_key(&action.as_any().type_id()) } /// Sets the menu bar for this application. This will replace any existing menu bar. pub fn set_menus(&self, menus: impl IntoIterator) { let menus: Vec = menus.into_iter().collect(); self.platform.set_menus(menus, &self.keymap.borrow()); } /// Gets the menu bar for this application. pub fn get_menus(&self) -> Option> { self.platform.get_menus() } /// Sets the right click menu for the app icon in the dock pub fn set_dock_menu(&self, menus: Vec) { self.platform.set_dock_menu(menus, &self.keymap.borrow()) } /// Performs the action associated with the given dock menu item, only used on Windows for now. pub fn perform_dock_menu_action(&self, action: usize) { self.platform.perform_dock_menu_action(action); } /// Adds given path to the bottom of the list of recent paths for the application. /// The list is usually shown on the application icon's context menu in the dock, /// and allows to open the recent files via that context menu. /// If the path is already in the list, it will be moved to the bottom of the list. pub fn add_recent_document(&self, path: &Path) { self.platform.add_recent_document(path); } /// Updates the jump list with the updated list of recent paths for the application, only used on Windows for now. /// Note that this also sets the dock menu on Windows. pub fn update_jump_list( &self, menus: Vec, entries: Vec>, ) -> Task>> { self.platform.update_jump_list(menus, entries) } /// Dispatch an action to the currently active window or global action handler /// See [`crate::Action`] for more information on how actions work pub fn dispatch_action(&mut self, action: &dyn Action) { if let Some(active_window) = self.active_window() { active_window .update(self, |_, window, cx| { window.dispatch_action(action.boxed_clone(), cx) }) .log_err(); } else { self.dispatch_global_action(action); } } fn dispatch_global_action(&mut self, action: &dyn Action) { self.propagate_event = true; if let Some(mut global_listeners) = self .global_action_listeners .remove(&action.as_any().type_id()) { for listener in &global_listeners { listener(action.as_any(), DispatchPhase::Capture, self); if !self.propagate_event { break; } } global_listeners.extend( self.global_action_listeners .remove(&action.as_any().type_id()) .unwrap_or_default(), ); self.global_action_listeners .insert(action.as_any().type_id(), global_listeners); } if self.propagate_event && let Some(mut global_listeners) = self .global_action_listeners .remove(&action.as_any().type_id()) { for listener in global_listeners.iter().rev() { listener(action.as_any(), DispatchPhase::Bubble, self); if !self.propagate_event { break; } } global_listeners.extend( self.global_action_listeners .remove(&action.as_any().type_id()) .unwrap_or_default(), ); self.global_action_listeners .insert(action.as_any().type_id(), global_listeners); } } /// Is there currently something being dragged? pub fn has_active_drag(&self) -> bool { self.active_drag.is_some() } /// Gets the cursor style of the currently active drag operation. pub fn active_drag_cursor_style(&self) -> Option { self.active_drag.as_ref().and_then(|drag| drag.cursor_style) } /// Stops active drag and clears any related effects. pub fn stop_active_drag(&mut self, window: &mut Window) -> bool { if self.active_drag.is_some() { self.active_drag = None; window.refresh(); true } else { false } } /// Sets the cursor style for the currently active drag operation. pub fn set_active_drag_cursor_style( &mut self, cursor_style: CursorStyle, window: &mut Window, ) -> bool { if let Some(ref mut drag) = self.active_drag { drag.cursor_style = Some(cursor_style); window.refresh(); true } else { false } } /// Set the prompt renderer for GPUI. This will replace the default or platform specific /// prompts with this custom implementation. pub fn set_prompt_builder( &mut self, renderer: impl Fn( PromptLevel, &str, Option<&str>, &[PromptButton], PromptHandle, &mut Window, &mut App, ) -> RenderablePromptHandle + 'static, ) { self.prompt_builder = Some(PromptBuilder::Custom(Box::new(renderer))); } /// Reset the prompt builder to the default implementation. pub fn reset_prompt_builder(&mut self) { self.prompt_builder = Some(PromptBuilder::Default); } /// Remove an asset from GPUI's cache pub fn remove_asset(&mut self, source: &A::Source) { let asset_id = (TypeId::of::(), hash(source)); self.loading_assets.remove(&asset_id); } /// Asynchronously load an asset, if the asset hasn't finished loading this will return None. /// /// Note that the multiple calls to this method will only result in one `Asset::load` call at a /// time, and the results of this call will be cached pub fn fetch_asset(&mut self, source: &A::Source) -> (Shared>, bool) { let asset_id = (TypeId::of::(), hash(source)); let mut is_first = false; let task = self .loading_assets .remove(&asset_id) .map(|boxed_task| *boxed_task.downcast::>>().unwrap()) .unwrap_or_else(|| { is_first = true; let future = A::load(source.clone(), self); self.background_executor().spawn(future).shared() }); self.loading_assets.insert(asset_id, Box::new(task.clone())); (task, is_first) } /// Obtain a new [`FocusHandle`], which allows you to track and manipulate the keyboard focus /// for elements rendered within this window. #[track_caller] pub fn focus_handle(&self) -> FocusHandle { FocusHandle::new(&self.focus_handles) } /// Tell GPUI that an entity has changed and observers of it should be notified. pub fn notify(&mut self, entity_id: EntityId) { let window_invalidators = mem::take( self.window_invalidators_by_entity .entry(entity_id) .or_default(), ); if window_invalidators.is_empty() { if self.pending_notifications.insert(entity_id) { self.pending_effects .push_back(Effect::Notify { emitter: entity_id }); } } else { for invalidator in window_invalidators.values() { invalidator.invalidate_view(entity_id, self); } } self.window_invalidators_by_entity .insert(entity_id, window_invalidators); } /// Returns the name for this [`App`]. #[cfg(any(test, feature = "test-support", debug_assertions))] pub fn get_name(&self) -> Option<&'static str> { self.name } /// Returns `true` if the platform file picker supports selecting a mix of files and directories. pub fn can_select_mixed_files_and_dirs(&self) -> bool { self.platform.can_select_mixed_files_and_dirs() } /// Removes an image from the sprite atlas on all windows. /// /// If the current window is being updated, it will be removed from `App.windows`, you can use `current_window` to specify the current window. /// This is a no-op if the image is not in the sprite atlas. pub fn drop_image(&mut self, image: Arc, current_window: Option<&mut Window>) { // remove the texture from all other windows for window in self.windows.values_mut().flatten() { _ = window.drop_image(image.clone()); } // remove the texture from the current window if let Some(window) = current_window { _ = window.drop_image(image); } } /// Sets the renderer for the inspector. #[cfg(any(feature = "inspector", debug_assertions))] pub fn set_inspector_renderer(&mut self, f: crate::InspectorRenderer) { self.inspector_renderer = Some(f); } /// Registers a renderer specific to an inspector state. #[cfg(any(feature = "inspector", debug_assertions))] pub fn register_inspector_element( &mut self, f: impl 'static + Fn(crate::InspectorElementId, &T, &mut Window, &mut App) -> R, ) { self.inspector_element_registry.register(f); } /// Initializes gpui's default colors for the application. /// /// These colors can be accessed through `cx.default_colors()`. pub fn init_colors(&mut self) { self.set_global(GlobalColors(Arc::new(Colors::default()))); } } impl AppContext for App { /// Builds an entity that is owned by the application. /// /// The given function will be invoked with a [`Context`] and must return an object representing the entity. An /// [`Entity`] handle will be returned, which can be used to access the entity in a context. fn new(&mut self, build_entity: impl FnOnce(&mut Context) -> T) -> Entity { self.update(|cx| { let slot = cx.entities.reserve(); let handle = slot.clone(); let entity = build_entity(&mut Context::new_context(cx, slot.downgrade())); cx.push_effect(Effect::EntityCreated { entity: handle.into_any(), tid: TypeId::of::(), window: cx.window_update_stack.last().cloned(), }); cx.entities.insert(slot, entity) }) } fn reserve_entity(&mut self) -> Reservation { Reservation(self.entities.reserve()) } fn insert_entity( &mut self, reservation: Reservation, build_entity: impl FnOnce(&mut Context) -> T, ) -> Entity { self.update(|cx| { let slot = reservation.0; let entity = build_entity(&mut Context::new_context(cx, slot.downgrade())); cx.entities.insert(slot, entity) }) } /// Updates the entity referenced by the given handle. The function is passed a mutable reference to the /// entity along with a `Context` for the entity. fn update_entity( &mut self, handle: &Entity, update: impl FnOnce(&mut T, &mut Context) -> R, ) -> R { self.update(|cx| { let mut entity = cx.entities.lease(handle); let result = update( &mut entity, &mut Context::new_context(cx, handle.downgrade()), ); cx.entities.end_lease(entity); result }) } fn as_mut<'a, T>(&'a mut self, handle: &Entity) -> GpuiBorrow<'a, T> where T: 'static, { GpuiBorrow::new(handle.clone(), self) } fn read_entity(&self, handle: &Entity, read: impl FnOnce(&T, &App) -> R) -> R where T: 'static, { let entity = self.entities.read(handle); read(entity, self) } fn update_window(&mut self, handle: AnyWindowHandle, update: F) -> Result where F: FnOnce(AnyView, &mut Window, &mut App) -> T, { self.update_window_id(handle.id, update) } fn read_window( &self, window: &WindowHandle, read: impl FnOnce(Entity, &App) -> R, ) -> Result where T: 'static, { let window = self .windows .get(window.id) .context("window not found")? .as_deref() .expect("attempted to read a window that is already on the stack"); let root_view = window.root.clone().unwrap(); let view = root_view .downcast::() .map_err(|_| anyhow!("root view's type has changed"))?; Ok(read(view, self)) } fn background_spawn(&self, future: impl Future + Send + 'static) -> Task where R: Send + 'static, { self.background_executor.spawn(future) } fn read_global(&self, callback: impl FnOnce(&G, &App) -> R) -> R where G: Global, { let mut g = self.global::(); callback(g, self) } } /// These effects are processed at the end of each application update cycle. pub(crate) enum Effect { Notify { emitter: EntityId, }, Emit { emitter: EntityId, event_type: TypeId, event: ArenaBox, }, RefreshWindows, NotifyGlobalObservers { global_type: TypeId, }, Defer { callback: Box, }, EntityCreated { entity: AnyEntity, tid: TypeId, window: Option, }, } impl std::fmt::Debug for Effect { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { match self { Effect::Notify { emitter } => write!(f, "Notify({})", emitter), Effect::Emit { emitter, .. } => write!(f, "Emit({:?})", emitter), Effect::RefreshWindows => write!(f, "RefreshWindows"), Effect::NotifyGlobalObservers { global_type } => { write!(f, "NotifyGlobalObservers({:?})", global_type) } Effect::Defer { .. } => write!(f, "Defer(..)"), Effect::EntityCreated { entity, .. } => write!(f, "EntityCreated({:?})", entity), } } } /// Wraps a global variable value during `update_global` while the value has been moved to the stack. pub(crate) struct GlobalLease { global: Box, global_type: PhantomData, } impl GlobalLease { fn new(global: Box) -> Self { GlobalLease { global, global_type: PhantomData, } } } impl Deref for GlobalLease { type Target = G; fn deref(&self) -> &Self::Target { self.global.downcast_ref().unwrap() } } impl DerefMut for GlobalLease { fn deref_mut(&mut self) -> &mut Self::Target { self.global.downcast_mut().unwrap() } } /// Contains state associated with an active drag operation, started by dragging an element /// within the window or by dragging into the app from the underlying platform. pub struct AnyDrag { /// The view used to render this drag pub view: AnyView, /// The value of the dragged item, to be dropped pub value: Arc, /// This is used to render the dragged item in the same place /// on the original element that the drag was initiated pub cursor_offset: Point, /// The cursor style to use while dragging pub cursor_style: Option, } /// Contains state associated with a tooltip. You'll only need this struct if you're implementing /// tooltip behavior on a custom element. Otherwise, use [Div::tooltip](crate::Interactivity::tooltip). #[derive(Clone)] pub struct AnyTooltip { /// The view used to display the tooltip pub view: AnyView, /// The absolute position of the mouse when the tooltip was deployed. pub mouse_position: Point, /// Given the bounds of the tooltip, checks whether the tooltip should still be visible and /// updates its state accordingly. This is needed atop the hovered element's mouse move handler /// to handle the case where the element is not painted (e.g. via use of `visible_on_hover`). pub check_visible_and_update: Rc, &mut Window, &mut App) -> bool>, } /// A keystroke event, and potentially the associated action #[derive(Debug)] pub struct KeystrokeEvent { /// The keystroke that occurred pub keystroke: Keystroke, /// The action that was resolved for the keystroke, if any pub action: Option>, /// The context stack at the time pub context_stack: Vec, } struct NullHttpClient; impl HttpClient for NullHttpClient { fn send( &self, _req: http_client::Request, ) -> futures::future::BoxFuture< 'static, anyhow::Result>, > { async move { anyhow::bail!("No HttpClient available"); } .boxed() } fn user_agent(&self) -> Option<&http_client::http::HeaderValue> { None } fn proxy(&self) -> Option<&Url> { None } } /// A mutable reference to an entity owned by GPUI pub struct GpuiBorrow<'a, T> { inner: Option>, app: &'a mut App, } impl<'a, T: 'static> GpuiBorrow<'a, T> { fn new(inner: Entity, app: &'a mut App) -> Self { app.start_update(); let lease = app.entities.lease(&inner); Self { inner: Some(lease), app, } } } impl<'a, T: 'static> std::borrow::Borrow for GpuiBorrow<'a, T> { fn borrow(&self) -> &T { self.inner.as_ref().unwrap().borrow() } } impl<'a, T: 'static> std::borrow::BorrowMut for GpuiBorrow<'a, T> { fn borrow_mut(&mut self) -> &mut T { self.inner.as_mut().unwrap().borrow_mut() } } impl<'a, T: 'static> std::ops::Deref for GpuiBorrow<'a, T> { type Target = T; fn deref(&self) -> &Self::Target { self.inner.as_ref().unwrap() } } impl<'a, T: 'static> std::ops::DerefMut for GpuiBorrow<'a, T> { fn deref_mut(&mut self) -> &mut T { self.inner.as_mut().unwrap() } } impl<'a, T> Drop for GpuiBorrow<'a, T> { fn drop(&mut self) { let lease = self.inner.take().unwrap(); self.app.notify(lease.id); self.app.entities.end_lease(lease); self.app.finish_update(); } } #[cfg(test)] mod test { use std::{cell::RefCell, rc::Rc}; use crate::{AppContext, TestAppContext}; #[test] fn test_gpui_borrow() { let cx = TestAppContext::single(); let observation_count = Rc::new(RefCell::new(0)); let state = cx.update(|cx| { let state = cx.new(|_| false); cx.observe(&state, { let observation_count = observation_count.clone(); move |_, _| { let mut count = observation_count.borrow_mut(); *count += 1; } }) .detach(); state }); cx.update(|cx| { // Calling this like this so that we don't clobber the borrow_mut above *std::borrow::BorrowMut::borrow_mut(&mut state.as_mut(cx)) = true; }); cx.update(|cx| { state.write(cx, false); }); assert_eq!(*observation_count.borrow(), 2); } }