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migrations:dependabot/github_actions/github-actions-338ac7668c migrations:master migrations:jackpot51/orbital-mouse-click-pos migrations:madsmtm/no-x11-dl-common migrations:madsmtm/reduce-custom-cfgs-in-examples migrations:madsmtm/private-apple-apis migrations:madsmtm/launch-in-new migrations:madsmtm/event-time migrations:madsmtm/uikit-safe-area-keyboard migrations:v0.30.x migrations:v0.31.x migrations:madsmtm/window-getter migrations:waker migrations:madsmtm/coalesce-windows-wakeups migrations:kchibisov/core-event-loop migrations:madsmtm/macos-monitor-handle-uuid-v0.30.x migrations:madsmtm/janky-pump-events migrations:notgull/install-docs migrations:madsmtm/init-closure migrations:notgull/winmain migrations:madsmtm/dpi-rect migrations:madsmtm/doc-controlflow-waituntil migrations:kchibisov/platform-trait-example migrations:madsmtm/observer-default-mode migrations:madsmtm/verify-event-order migrations:it migrations:madsmtm/check-commit-msg-length migrations:v0.29.x migrations:feat/dpi-single-unit migrations:notgull/spellcheck migrations:kchibisov/improve-contributing migrations:split-example-a-bit migrations:android-note-unsupported-multi-window migrations:request-ignored migrations:notgull/split migrations:rwh-send-sync migrations:notgull/ime migrations:notgull/ia-xbuild migrations:v0.28.x migrations:fix-alt-modifier-new migrations:v0.27.x migrations:gamepad-device-events
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2 Commits
v0.17.2 ... v0.6.4

Author SHA1 Message Date
Pierre Krieger
444ebc3018 Publish 0.6.4 2017-05-07 20:36:22 +02:00
Jon Gjengset
f8efe87c34 Set WM_CLASS and WM_NAME before mapping window 
ICCCM 4.1.2.5 (https://tronche.com/gui/x/icccm/sec-4.html#WM_CLASS)
states that:

> This property must be present when the window leaves the Withdrawn
> state and may be changed only while the window is in the Withdrawn
> state.

Previously, we would first map the window, and then set these
properties, causing sadness for window managers (#167,
tomaka/glutin#879). This patch changes that by setting the class and
name attributes immediately after the window is created, and before it
is mapped.

Fixes #167.
 2017-05-07 20:34:50 +02:00
96 changed files with 5675 additions and 17208 deletions
Expand all files Collapse all files

56
.circleci/config.yml
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@@ -1,56 +0,0 @@
version: 2
jobs:
android-test:
working_directory: ~/winit
docker:
- image: tomaka/cargo-apk
steps:
- run: apt-get -qq update && apt-get install -y git
- checkout
- restore_cache:
key: android-test-cache-{{ checksum "Cargo.toml" }}
- run: cargo apk build --example window
- save_cache:
key: android-test-cache-{{ checksum "Cargo.toml" }}
paths:
- target
asmjs-test:
working_directory: ~/winit
docker:
- image: tomaka/rustc-emscripten
steps:
- run: apt-get -qq update && apt-get install -y git
- checkout
- restore_cache:
key: asmjs-test-cache-{{ checksum "Cargo.toml" }}
- run: cargo build --example window --target asmjs-unknown-emscripten
- save_cache:
key: asmjs-test-cache-{{ checksum "Cargo.toml" }}
paths:
- target
wasm-test:
working_directory: ~/winit
docker:
- image: tomaka/rustc-emscripten
steps:
- run: apt-get -qq update && apt-get install -y git
- checkout
- restore_cache:
key: wasm-test-cache-{{ checksum "Cargo.toml" }}
- run: cargo build --example window --target wasm32-unknown-emscripten
- save_cache:
key: wasm-test-cache-{{ checksum "Cargo.toml" }}
paths:
- target
workflows:
version: 2
build-test-and-deploy:
jobs:
- android-test
- asmjs-test
- wasm-test

4
.github/PULL_REQUEST_TEMPLATE.md vendored
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@@ -1,4 +0,0 @@
- [ ] Tested on all platforms changed
- [ ] Added an entry to `CHANGELOG.md` if knowledge of this change could be valuable to users
- [ ] Updated documentation to reflect any user-facing changes, including notes of platform-specific behavior
- [ ] Created an example program if it would help users understand this functionality

2
.gitignore vendored
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@@ -1,6 +1,4 @@
Cargo.lock
target/
rls/
.vscode/
*~
#*#

80
.travis.yml
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@@ -1,72 +1,30 @@
language: rust
rust:
- nightly
- stable
cache: cargo
matrix:
include:
# Linux 32bit
- env: TARGET=i686-unknown-linux-gnu
os: linux
rust: nightly
addons:
apt:
# Cross compiler and cross compiled C libraries
packages: &i686_packages
- gcc-multilib
- env: TARGET=i686-unknown-linux-gnu
os: linux
rust: stable
addons:
apt:
packages: *i686_packages
- env: TARGET=i686-unknown-linux-gnu
os: linux
rust: 1.24.1
addons:
apt:
packages: *i686_packages
# Linux 64bit
- env: TARGET=x86_64-unknown-linux-gnu
os: linux
rust: nightly
- env: TARGET=x86_64-unknown-linux-gnu
os: linux
rust: stable
- env: TARGET=x86_64-unknown-linux-gnu
os: linux
rust: 1.24.1
# macOS
- env: TARGET=x86_64-apple-darwin
os: osx
rust: nightly
- env: TARGET=x86_64-apple-darwin
os: osx
rust: stable
- env: TARGET=x86_64-apple-darwin
os: osx
rust: 1.24.1
# iOS
- env: TARGET=x86_64-apple-ios
os: osx
rust: nightly
- env: TARGET=x86_64-apple-ios
os: osx
rust: stable
- env: TARGET=x86_64-apple-ios
os: osx
rust: 1.24.1
addons:
apt:
packages:
- libxxf86vm-dev
install:
- rustup self update
- rustup target add $TARGET; true
- |
if [ $TRAVIS_OS_NAME = osx ]; then
rustup target add x86_64-apple-ios
fi
script:
- cargo build --target $TARGET --verbose
# Running iOS apps on OSX requires the simulator so we skip that for now
- if [ "$TARGET" != "x86_64-apple-ios" ]; then cargo test --target $TARGET --verbose; fi
- cargo build --verbose
- if [ $TRAVIS_OS_NAME = osx ]; then cargo build --target x86_64-apple-ios --verbose; fi
- cargo test --verbose
os:
- linux
- osx
after_success:
- |

252
CHANGELOG.md
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@@ -1,252 +0,0 @@
# Unreleased
# Version 0.17.2 (2018-08-19)
- On macOS, fix `<C-Tab>` so applications receive the event.
- On macOS, fix `<Cmd-{key}>` so applications receive the event.
- On Wayland, key press events will now be repeated.
# Version 0.17.1 (2018-08-05)
- On X11, prevent a compilation failure in release mode for versions of Rust greater than or equal to 1.30.
- Fixed deadlock that broke fullscreen mode on Windows.
# Version 0.17.0 (2018-08-02)
- Cocoa and core-graphics updates.
- Fixed thread-safety issues in several `Window` functions on Windows.
- On MacOS, the key state for modifiers key events is now properly set.
- On iOS, the view is now set correctly. This makes it possible to render things (instead of being stuck on a black screen), and touch events work again.
- Added NetBSD support.
- **Breaking:** On iOS, `UIView` is now the default root view. `WindowBuilderExt::with_root_view_class` can be used to set the root view objective-c class to `GLKView` (OpenGLES) or `MTKView` (Metal/MoltenVK).
- On iOS, the `UIApplication` is not started until `Window::new` is called.
- Fixed thread unsafety with cursor hiding on macOS.
- On iOS, fixed the size of the `JmpBuf` type used for `setjmp`/`longjmp` calls. Previously this was a buffer overflow on most architectures.
- On Windows, use cached window DPI instead of repeatedly querying the system. This fixes sporadic crashes on Windows 7.
# Version 0.16.2 (2018-07-07)
- On Windows, non-resizable windows now have the maximization button disabled. This is consistent with behavior on macOS and popular X11 WMs.
- Corrected incorrect `unreachable!` usage when guessing the DPI factor with no detected monitors.
# Version 0.16.1 (2018-07-02)
- Added logging through `log`. Logging will become more extensive over time.
- On X11 and Windows, the window's DPI factor is guessed before creating the window. This *greatly* cuts back on unsightly auto-resizing that would occur immediately after window creation.
- Fixed X11 backend compilation for environments where `c_char` is unsigned.
# Version 0.16.0 (2018-06-25)
- Windows additionally has `WindowBuilderExt::with_no_redirection_bitmap`.
- **Breaking:** Removed `VirtualKeyCode::LMenu` and `VirtualKeyCode::RMenu`; Windows now generates `VirtualKeyCode::LAlt` and `VirtualKeyCode::RAlt` instead.
- On X11, exiting fullscreen no longer leaves the window in the monitor's top left corner.
- **Breaking:** `Window::hidpi_factor` has been renamed to `Window::get_hidpi_factor` for better consistency. `WindowEvent::HiDPIFactorChanged` has been renamed to `WindowEvent::HiDpiFactorChanged`. DPI factors are always represented as `f64` instead of `f32` now.
- The Windows backend is now DPI aware. `WindowEvent::HiDpiFactorChanged` is implemented, and `MonitorId::get_hidpi_factor` and `Window::hidpi_factor` return accurate values.
- Implemented `WindowEvent::HiDpiFactorChanged` on X11.
- On macOS, `Window::set_cursor_position` is now relative to the client area.
- On macOS, setting the maximum and minimum dimensions now applies to the client area dimensions rather than to the window dimensions.
- On iOS, `MonitorId::get_dimensions` has been implemented and both `MonitorId::get_hidpi_factor` and `Window::get_hidpi_factor` return accurate values.
- On Emscripten, `MonitorId::get_hidpi_factor` now returns the same value as `Window::get_hidpi_factor` (it previously would always return 1.0).
- **Breaking:** The entire API for sizes, positions, etc. has changed. In the majority of cases, winit produces and consumes positions and sizes as `LogicalPosition` and `LogicalSize`, respectively. The notable exception is `MonitorId` methods, which deal in `PhysicalPosition` and `PhysicalSize`. See the documentation for specifics and explanations of the types. Additionally, winit automatically conserves logical size when the DPI factor changes.
- **Breaking:** All deprecated methods have been removed. For `Window::platform_display` and `Window::platform_window`, switch to the appropriate platform-specific `WindowExt` methods. For `Window::get_inner_size_points` and `Window::get_inner_size_pixels`, use the `LogicalSize` returned by `Window::get_inner_size` and convert as needed.
- HiDPI support for Wayland.
- `EventsLoop::get_available_monitors` and `EventsLoop::get_primary_monitor` now have identical counterparts on `Window`, so this information can be acquired without an `EventsLoop` borrow.
- `AvailableMonitorsIter` now implements `Debug`.
- Fixed quirk on macOS where certain keys would generate characters at twice the normal rate when held down.
- On X11, all event loops now share the same `XConnection`.
- **Breaking:** `Window::set_cursor_state` and `CursorState` enum removed in favor of the more composable `Window::grab_cursor` and `Window::hide_cursor`. As a result, grabbing the cursor no longer automatically hides it; you must call both methods to retain the old behavior on Windows and macOS. `Cursor::NoneCursor` has been removed, as it's no longer useful.
- **Breaking:** `Window::set_cursor_position` now returns `Result<(), String>`, thus allowing for `Box<Error>` conversion via `?`.
# Version 0.15.1 (2018-06-13)
- On X11, the `Moved` event is no longer sent when the window is resized without changing position.
- `MouseCursor` and `CursorState` now implement `Default`.
- `WindowBuilder::with_resizable` implemented for Windows, X11, Wayland, and macOS.
- `Window::set_resizable` implemented for Windows, X11, Wayland, and macOS.
- On X11, if the monitor's width or height in millimeters is reported as 0, the DPI is now 1.0 instead of +inf.
- On X11, the environment variable `WINIT_HIDPI_FACTOR` has been added for overriding DPI factor.
- On X11, enabling transparency no longer causes the window contents to flicker when resizing.
- On X11, `with_override_redirect` now actually enables override redirect.
- macOS now generates `VirtualKeyCode::LAlt` and `VirtualKeyCode::RAlt` instead of `None` for both.
- On macOS, `VirtualKeyCode::RWin` and `VirtualKeyCode::LWin` are no longer switched.
- On macOS, windows without decorations can once again be resized.
- Fixed race conditions when creating an `EventsLoop` on X11, most commonly manifesting as "[xcb] Unknown sequence number while processing queue".
- On macOS, `CursorMoved` and `MouseInput` events are only generated if they occurs within the window's client area.
- On macOS, resizing the window no longer generates a spurious `MouseInput` event.
# Version 0.15.0 (2018-05-22)
- `Icon::to_cardinals` is no longer public, since it was never supposed to be.
- Wayland: improve diagnostics if initialization fails
- Fix some system event key doesn't work when focused, do not block keyevent forward to system on macOS
- On X11, the scroll wheel position is now correctly reset on i3 and other WMs that have the same quirk.
- On X11, `Window::get_current_monitor` now reliably returns the correct monitor.
- On X11, `Window::hidpi_factor` returns values from XRandR rather than the inaccurate values previously queried from the core protocol.
- On X11, the primary monitor is detected correctly even when using versions of XRandR less than 1.5.
- `MonitorId` now implements `Debug`.
- Fixed bug on macOS where using `with_decorations(false)` would cause `set_decorations(true)` to produce a transparent titlebar with no title.
- Implemented `MonitorId::get_position` on macOS.
- On macOS, `Window::get_current_monitor` now returns accurate values.
- Added `WindowBuilderExt::with_resize_increments` to macOS.
- **Breaking:** On X11, `WindowBuilderExt::with_resize_increments` and `WindowBuilderExt::with_base_size` now take `u32` values rather than `i32`.
- macOS keyboard handling has been overhauled, allowing for the use of dead keys, IME, etc. Right modifier keys are also no longer reported as being left.
- Added the `Window::set_ime_spot(x: i32, y: i32)` method, which is implemented on X11 and macOS.
- **Breaking**: `os::unix::WindowExt::send_xim_spot(x: i16, y: i16)` no longer exists. Switch to the new `Window::set_ime_spot(x: i32, y: i32)`, which has equivalent functionality.
- Fixed detection of `Pause` and `Scroll` keys on Windows.
- On Windows, alt-tabbing while the cursor is grabbed no longer makes it impossible to re-grab the cursor.
- On Windows, using `CursorState::Hide` when the cursor is grabbed now ungrabs the cursor first.
- Implemented `MouseCursor::NoneCursor` on Windows.
- Added `WindowBuilder::with_always_on_top` and `Window::set_always_on_top`. Implemented on Windows, macOS, and X11.
- On X11, `WindowBuilderExt` now has `with_class`, `with_override_redirect`, and `with_x11_window_type` to allow for more control over window creation. `WindowExt` additionally has `set_urgent`.
- More hints are set by default on X11, including `_NET_WM_PID` and `WM_CLIENT_MACHINE`. Note that prior to this, the `WM_CLASS` hint was automatically set to whatever value was passed to `with_title`. It's now set to the executable name to better conform to expectations and the specification; if this is undesirable, you must explicitly use `WindowBuilderExt::with_class`.
# Version 0.14.0 (2018-05-09)
- Created the `Copy`, `Paste` and `Cut` `VirtualKeyCode`s and added support for them on X11 and Wayland
- Fix `.with_decorations(false)` in macOS
- On Mac, `NSWindow` and supporting objects might be alive long after they were `closed` which resulted in apps consuming more heap then needed. Mainly it was affecting multi window applications. Not expecting any user visible change of behaviour after the fix.
- Fix regression of Window platform extensions for macOS where `NSFullSizeContentViewWindowMask` was not being correctly applied to `.fullsize_content_view`.
- Corrected `get_position` on Windows to be relative to the screen rather than to the taskbar.
- Corrected `Moved` event on Windows to use position values equivalent to those returned by `get_position`. It previously supplied client area positions instead of window positions, and would additionally interpret negative values as being very large (around `u16::MAX`).
- Implemented `Moved` event on macOS.
- On X11, the `Moved` event correctly use window positions rather than client area positions. Additionally, a stray `Moved` that unconditionally accompanied `Resized` with the client area position relative to the parent has been eliminated; `Moved` is still received alongside `Resized`, but now only once and always correctly.
- On Windows, implemented all variants of `DeviceEvent` other than `Text`. Mouse `DeviceEvent`s are now received even if the window isn't in the foreground.
- `DeviceId` on Windows is no longer a unit struct, and now contains a `u32`. For `WindowEvent`s, this will always be 0, but on `DeviceEvent`s it will be the handle to that device. `DeviceIdExt::get_persistent_identifier` can be used to acquire a unique identifier for that device that persists across replugs/reboots/etc.
- Corrected `run_forever` on X11 to stop discarding `Awakened` events.
- Various safety and correctness improvements to the X11 backend internals.
- Fixed memory leak on X11 every time the mouse entered the window.
- On X11, drag and drop now works reliably in release mode.
- Added `WindowBuilderExt::with_resize_increments` and `WindowBuilderExt::with_base_size` to X11, allowing for more optional hints to be set.
- Rework of the wayland backend, migrating it to use [Smithay's Client Toolkit](https://github.com/Smithay/client-toolkit).
- Added `WindowBuilder::with_window_icon` and `Window::set_window_icon`, finally making it possible to set the window icon on Windows and X11. The `icon_loading` feature can be enabled to allow for icons to be easily loaded; see example program `window_icon.rs` for usage.
- Windows additionally has `WindowBuilderExt::with_taskbar_icon` and `WindowExt::set_taskbar_icon`.
- On Windows, fix panic when trying to call `set_fullscreen(None)` on a window that has not been fullscreened prior.
# Version 0.13.1 (2018-04-26)
- Ensure necessary `x11-dl` version is used.
# Version 0.13.0 (2018-04-25)
- Implement `WindowBuilder::with_maximized`, `Window::set_fullscreen`, `Window::set_maximized` and `Window::set_decorations` for MacOS.
- Implement `WindowBuilder::with_maximized`, `Window::set_fullscreen`, `Window::set_maximized` and `Window::set_decorations` for Windows.
- On Windows, `WindowBuilder::with_fullscreen` no longer changing monitor display resolution.
- Overhauled X11 window geometry calculations. `get_position` and `set_position` are more universally accurate across different window managers, and `get_outer_size` actually works now.
- Fixed SIGSEGV/SIGILL crashes on macOS caused by stabilization of the `!` (never) type.
- Implement `WindowEvent::HiDPIFactorChanged` for macOS
- On X11, input methods now work completely out of the box, no longer requiring application developers to manually call `setlocale`. Additionally, when input methods are started, stopped, or restarted on the server end, it's correctly handled.
- Implemented `Refresh` event on Windows.
- Properly calculate the minimum and maximum window size on Windows, including window decorations.
- Map more `MouseCursor` variants to cursor icons on Windows.
- Corrected `get_position` on macOS to return outer frame position, not content area position.
- Corrected `set_position` on macOS to set outer frame position, not content area position.
- Added `get_inner_position` method to `Window`, which gets the position of the window's client area. This is implemented on all applicable platforms (all desktop platforms other than Wayland, where this isn't possible).
- **Breaking:** the `Closed` event has been replaced by `CloseRequested` and `Destroyed`. To migrate, you typically just need to replace all usages of `Closed` with `CloseRequested`; see example programs for more info. The exception is iOS, where `Closed` must be replaced by `Destroyed`.
# Version 0.12.0 (2018-04-06)
- Added subclass to macos windows so they can be made resizable even with no decorations.
- Dead keys now work properly on X11, no longer resulting in a panic.
- On X11, input method creation first tries to use the value from the user's `XMODIFIERS` environment variable, so application developers should no longer need to manually call `XSetLocaleModifiers`. If that fails, fallbacks are tried, which should prevent input method initialization from ever outright failing.
- Fixed thread safety issues with input methods on X11.
- Add support for `Touch` for win32 backend.
- Fixed `Window::get_inner_size` and friends to return the size in pixels instead of points when using HIDPI displays on OSX.
# Version 0.11.3 (2018-03-28)
- Added `set_min_dimensions` and `set_max_dimensions` methods to `Window`, and implemented on Windows, X11, Wayland, and OSX.
- On X11, dropping a `Window` actually closes it now, and clicking the window's × button (or otherwise having the WM signal to close it) will result in the window closing.
- Added `WindowBuilderExt` methods for macos: `with_titlebar_transparent`,
`with_title_hidden`, `with_titlebar_buttons_hidden`,
`with_fullsize_content_view`.
- Mapped X11 numpad keycodes (arrows, Home, End, PageUp, PageDown, Insert and Delete) to corresponding virtual keycodes
# Version 0.11.2 (2018-03-06)
- Impl `Hash`, `PartialEq`, and `Eq` for `events::ModifiersState`.
- Implement `MonitorId::get_hidpi_factor` for MacOS.
- Added method `os::macos::MonitorIdExt::get_nsscreen() -> *mut c_void` that gets a `NSScreen` object matching the monitor ID.
- Send `Awakened` event on Android when event loop is woken up.
# Version 0.11.1 (2018-02-19)
- Fixed windows not receiving mouse events when click-dragging the mouse outside the client area of a window, on Windows platforms.
- Added method `os::android::EventsLoopExt:set_suspend_callback(Option<Box<Fn(bool) -> ()>>)` that allows glutin to register a callback when a suspend event happens
# Version 0.11.0 (2018-02-09)
- Implement `MonitorId::get_dimensions` for Android.
- Added method `os::macos::WindowBuilderExt::with_movable_by_window_background(bool)` that allows to move a window without a titlebar - `with_decorations(false)`
- Implement `Window::set_fullscreen`, `Window::set_maximized` and `Window::set_decorations` for Wayland.
- Added `Caret` as VirtualKeyCode and support OSX ^-Key with german input.
# Version 0.10.1 (2018-02-05)
*Yanked*
# Version 0.10.0 (2017-12-27)
- Add support for `Touch` for emscripten backend.
- Added support for `DroppedFile`, `HoveredFile`, and `HoveredFileCancelled` to X11 backend.
- **Breaking:** `unix::WindowExt` no longer returns pointers for things that aren't actually pointers; `get_xlib_window` now returns `Option<std::os::raw::c_ulong>` and `get_xlib_screen_id` returns `Option<std::os::raw::c_int>`. Additionally, methods that previously returned `libc::c_void` have been changed to return `std::os::raw::c_void`, which are not interchangeable types, so users wanting the former will need to explicitly cast.
- Added `set_decorations` method to `Window` to allow decorations to be toggled after the window is built. Presently only implemented on X11.
- Raised the minimum supported version of Rust to 1.20 on MacOS due to usage of associated constants in new versions of cocoa and core-graphics.
- Added `modifiers` field to `MouseInput`, `MouseWheel`, and `CursorMoved` events to track the modifiers state (`ModifiersState`).
- Fixed the emscripten backend to return the size of the canvas instead of the size of the window.
# Version 0.9.0 (2017-12-01)
- Added event `WindowEvent::HiDPIFactorChanged`.
- Added method `MonitorId::get_hidpi_factor`.
- Deprecated `get_inner_size_pixels` and `get_inner_size_points` methods of `Window` in favor of
`get_inner_size`.
- **Breaking:** `EventsLoop` is `!Send` and `!Sync` because of platform-dependant constraints,
but `Window`, `WindowId`, `DeviceId` and `MonitorId` guaranteed to be `Send`.
- `MonitorId::get_position` now returns `(i32, i32)` instead of `(u32, u32)`.
- Rewrite of the wayland backend to use wayland-client-0.11
- Support for dead keys on wayland for keyboard utf8 input
- Monitor enumeration on Windows is now implemented using `EnumDisplayMonitors` instead of
`EnumDisplayDevices`. This changes the value returned by `MonitorId::get_name()`.
- On Windows added `MonitorIdExt::hmonitor` method
- Impl `Clone` for `EventsLoopProxy`
- `EventsLoop::get_primary_monitor()` on X11 will fallback to any available monitor if no primary is found
- Support for touch event on wayland
- `WindowEvent`s `MouseMoved`, `MouseEntered`, and `MouseLeft` have been renamed to
`CursorMoved`, `CursorEntered`, and `CursorLeft`.
- New `DeviceEvent`s added, `MouseMotion` and `MouseWheel`.
- Send `CursorMoved` event after `CursorEntered` and `Focused` events.
- Add support for `ModifiersState`, `MouseMove`, `MouseInput`, `MouseMotion` for emscripten backend.
# Version 0.8.3 (2017-10-11)
- Fixed issue of calls to `set_inner_size` blocking on Windows.
- Mapped `ISO_Left_Tab` to `VirtualKeyCode::Tab` to make the key work with modifiers
- Fixed the X11 backed on 32bit targets
# Version 0.8.2 (2017-09-28)
- Uniformize keyboard scancode values accross Wayland and X11 (#297).
- Internal rework of the wayland event loop
- Added method `os::linux::WindowExt::is_ready`
# Version 0.8.1 (2017-09-22)
- Added various methods to `os::linux::EventsLoopExt`, plus some hidden items necessary to make
glutin work.
# Version 0.8.0 (2017-09-21)
- Added `Window::set_maximized`, `WindowAttributes::maximized` and `WindowBuilder::with_maximized`.
- Added `Window::set_fullscreen`.
- Changed `with_fullscreen` to take a `Option<MonitorId>` instead of a `MonitorId`.
- Removed `MonitorId::get_native_identifer()` in favor of platform-specific traits in the `os`
module.
- Changed `get_available_monitors()` and `get_primary_monitor()` to be methods of `EventsLoop`
instead of stand-alone methods.
- Changed `EventsLoop` to be tied to a specific X11 or Wayland connection.
- Added a `os::linux::EventsLoopExt` trait that makes it possible to configure the connection.
- Fixed the emscripten code, which now compiles.
- Changed the X11 fullscreen code to use `xrandr` instead of `xxf86vm`.
- Fixed the Wayland backend to produce `Refresh` event after window creation.
- Changed the `Suspended` event to be outside of `WindowEvent`.
- Fixed the X11 backend sometimes reporting the wrong virtual key (#273).

60
Cargo.toml
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@@ -1,6 +1,6 @@
[package]
name = "winit"
version = "0.17.2"
version = "0.6.4"
authors = ["The winit contributors, Pierre Krieger <pierre.krieger1708@gmail.com>"]
description = "Cross-platform window creation library."
keywords = ["windowing"]
@@ -10,52 +10,34 @@ repository = "https://github.com/tomaka/winit"
documentation = "https://docs.rs/winit"
categories = ["gui"]
[package.metadata.docs.rs]
features = ["icon_loading"]
[features]
icon_loading = ["image"]
[dependencies]
lazy_static = "1"
lazy_static = "0.2.2"
libc = "0.2"
log = "0.4"
image = { version = "0.19", optional = true }
shared_library = "0.1.5"
[target.'cfg(target_os = "android")'.dependencies.android_glue]
version = "0.2"
[target.'cfg(target_os = "ios")'.dependencies]
objc = "0.2.3"
objc = "0.2"
[target.'cfg(target_os = "macos")'.dependencies]
objc = "0.2.3"
cocoa = "0.17"
core-foundation = "0.6"
core-graphics = "0.16"
objc = "0.2"
cgl = "0.2"
cocoa = "=0.5.2"
core-foundation = "0.2"
core-graphics = "0.4"
[target.'cfg(target_os = "windows")'.dependencies.winapi]
version = "0.3.5"
features = [
"combaseapi",
"dwmapi",
"hidusage",
"libloaderapi",
"objbase",
"processthreadsapi",
"shellapi",
"shellscalingapi",
"shobjidl_core",
"unknwnbase",
"windowsx",
"wingdi",
"winnt",
"winuser",
]
[target.'cfg(target_os = "windows")'.dependencies]
winapi = "0.2"
shell32-sys = "0.1"
gdi32-sys = "0.1"
user32-sys = "~0.1.2"
kernel32-sys = "0.2"
dwmapi-sys = "0.1"
[target.'cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd", target_os = "netbsd"))'.dependencies]
wayland-client = { version = "0.20.10", features = [ "dlopen", "egl", "cursor"] }
smithay-client-toolkit = "0.3.0"
x11-dl = "2.18.3"
parking_lot = "0.6"
percent-encoding = "1.0"
[target.'cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd"))'.dependencies]
wayland-client = { version = "0.8.6", features = ["dlopen"] }
wayland-kbd = "0.8.0"
wayland-window = "0.5.0"
x11-dl = "2.8"

32
README.md
View File

@@ -4,12 +4,12 @@
[![Docs.rs](https://docs.rs/winit/badge.svg)](https://docs.rs/winit)
[![Build Status](https://travis-ci.org/tomaka/winit.svg?branch=master)](https://travis-ci.org/tomaka/winit)
[![Build Status](https://travis-ci.org/tomaka/winit.png?branch=master)](https://travis-ci.org/tomaka/winit)
[![Build status](https://ci.appveyor.com/api/projects/status/5h87hj0g4q2xe3j9/branch/master?svg=true)](https://ci.appveyor.com/project/tomaka/winit/branch/master)
```toml
[dependencies]
winit = "0.17"
winit = "0.5"
```
## [Documentation](https://docs.rs/winit)
@@ -17,7 +17,7 @@ winit = "0.17"
## Usage
Winit is a window creation and management library. It can create windows and lets you handle
events (for example: the window being resized, a key being pressed, a mouse movement, etc.)
events (for example: the window being resized, a key being pressed, a mouse mouvement, etc.)
produced by window.
Winit is designed to be a low-level brick in a hierarchy of libraries. Consequently, in order to
@@ -28,29 +28,13 @@ another library.
extern crate winit;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let window = winit::Window::new(&events_loop).unwrap();
let window = winit::Window::new().unwrap();
events_loop.run_forever(|event| {
for event in window.wait_events() {
match event {
winit::Event::WindowEvent {
event: winit::WindowEvent::CloseRequested,
..
} => winit::ControlFlow::Break,
_ => winit::ControlFlow::Continue,
winit::Event::Closed => break,
_ => ()
}
});
}
}
```
### Platform-specific usage
#### Emscripten and WebAssembly
Building a binary will yield a `.js` file. In order to use it in an HTML file, you need to:
- Put a `<canvas id="my_id"></canvas>` element somewhere. A canvas corresponds to a winit "window".
- Write a Javascript code that creates a global variable named `Module`. Set `Module.canvas` to
the element of the `<canvas>` element (in the example you would retrieve it via `document.getElementById("my_id")`).
More information [here](https://kripken.github.io/emscripten-site/docs/api_reference/module.html).
- Make sure that you insert the `.js` file generated by Rust after the `Module` variable is created.

13
appveyor.yml
View File

@@ -1,19 +1,12 @@
environment:
matrix:
- TARGET: x86_64-pc-windows-msvc
CHANNEL: nightly
- TARGET: x86_64-pc-windows-msvc
CHANNEL: stable
- TARGET: x86_64-pc-windows-msvc
CHANNEL: 1.24.1
- TARGET: i686-pc-windows-msvc
CHANNEL: nightly
- TARGET: i686-pc-windows-gnu
CHANNEL: nightly
install:
- appveyor DownloadFile https://win.rustup.rs/ -FileName rustup-init.exe
- rustup-init -yv --default-toolchain %CHANNEL% --default-host %TARGET%
- SET PATH=%PATH%;%USERPROFILE%\.cargo\bin
- ps: Start-FileDownload "https://static.rust-lang.org/dist/rust-nightly-${env:TARGET}.exe"
- rust-nightly-%TARGET%.exe /VERYSILENT /NORESTART /DIR="C:\Program Files (x86)\Rust"
- SET PATH=%PATH%;C:\Program Files (x86)\Rust\bin
- SET PATH=%PATH%;C:\MinGW\bin
- rustc -V
- cargo -V

13
examples/cursor.rs
View File

@@ -1,19 +1,19 @@
extern crate winit;
use winit::{Event, ElementState, MouseCursor, WindowEvent, KeyboardInput, ControlFlow};
use winit::{Event, ElementState, MouseCursor, WindowEvent};
fn main() {
let mut events_loop = winit::EventsLoop::new();
let events_loop = winit::EventsLoop::new();
let window = winit::WindowBuilder::new().build(&events_loop).unwrap();
window.set_title("A fantastic window!");
let cursors = [MouseCursor::Default, MouseCursor::Crosshair, MouseCursor::Hand, MouseCursor::Arrow, MouseCursor::Move, MouseCursor::Text, MouseCursor::Wait, MouseCursor::Help, MouseCursor::Progress, MouseCursor::NotAllowed, MouseCursor::ContextMenu, MouseCursor::Cell, MouseCursor::VerticalText, MouseCursor::Alias, MouseCursor::Copy, MouseCursor::NoDrop, MouseCursor::Grab, MouseCursor::Grabbing, MouseCursor::AllScroll, MouseCursor::ZoomIn, MouseCursor::ZoomOut, MouseCursor::EResize, MouseCursor::NResize, MouseCursor::NeResize, MouseCursor::NwResize, MouseCursor::SResize, MouseCursor::SeResize, MouseCursor::SwResize, MouseCursor::WResize, MouseCursor::EwResize, MouseCursor::NsResize, MouseCursor::NeswResize, MouseCursor::NwseResize, MouseCursor::ColResize, MouseCursor::RowResize];
let cursors = [MouseCursor::Default, MouseCursor::Crosshair, MouseCursor::Hand, MouseCursor::Arrow, MouseCursor::Move, MouseCursor::Text, MouseCursor::Wait, MouseCursor::Help, MouseCursor::Progress, MouseCursor::NotAllowed, MouseCursor::ContextMenu, MouseCursor::NoneCursor, MouseCursor::Cell, MouseCursor::VerticalText, MouseCursor::Alias, MouseCursor::Copy, MouseCursor::NoDrop, MouseCursor::Grab, MouseCursor::Grabbing, MouseCursor::AllScroll, MouseCursor::ZoomIn, MouseCursor::ZoomOut, MouseCursor::EResize, MouseCursor::NResize, MouseCursor::NeResize, MouseCursor::NwResize, MouseCursor::SResize, MouseCursor::SeResize, MouseCursor::SwResize, MouseCursor::WResize, MouseCursor::EwResize, MouseCursor::NsResize, MouseCursor::NeswResize, MouseCursor::NwseResize, MouseCursor::ColResize, MouseCursor::RowResize];
let mut cursor_idx = 0;
events_loop.run_forever(|event| {
match event {
Event::WindowEvent { event: WindowEvent::KeyboardInput { input: KeyboardInput { state: ElementState::Pressed, .. }, .. }, .. } => {
Event::WindowEvent { event: WindowEvent::KeyboardInput(ElementState::Pressed, _, _, _), .. } => {
println!("Setting cursor to \"{:?}\"", cursors[cursor_idx]);
window.set_cursor(cursors[cursor_idx]);
if cursor_idx < cursors.len() - 1 {
@@ -22,11 +22,10 @@ fn main() {
cursor_idx = 0;
}
},
Event::WindowEvent { event: WindowEvent::CloseRequested, .. } => {
return ControlFlow::Break;
Event::WindowEvent { event: WindowEvent::Closed, .. } => {
events_loop.interrupt()
},
_ => ()
}
ControlFlow::Continue
});
}

38
examples/cursor_grab.rs
View File

@@ -1,38 +0,0 @@
extern crate winit;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let window = winit::WindowBuilder::new()
.with_title("Super Cursor Grab'n'Hide Simulator 9000")
.build(&events_loop)
.unwrap();
events_loop.run_forever(|event| {
if let winit::Event::WindowEvent { event, .. } = event {
use winit::WindowEvent::*;
match event {
CloseRequested => return winit::ControlFlow::Break,
KeyboardInput {
input: winit::KeyboardInput {
state: winit::ElementState::Released,
virtual_keycode: Some(key),
modifiers,
..
},
..
} => {
use winit::VirtualKeyCode::*;
match key {
Escape => return winit::ControlFlow::Break,
G => window.grab_cursor(!modifiers.shift).unwrap(),
H => window.hide_cursor(!modifiers.shift),
_ => (),
}
}
_ => (),
}
}
winit::ControlFlow::Continue
});
}

57
examples/fullscreen.rs
View File

@@ -1,14 +1,11 @@
extern crate winit;
use std::io::{self, Write};
use winit::{ControlFlow, Event, WindowEvent};
fn main() {
let mut events_loop = winit::EventsLoop::new();
// enumerating monitors
let monitor = {
for (num, monitor) in events_loop.get_available_monitors().enumerate() {
for (num, monitor) in winit::get_available_monitors().enumerate() {
println!("Monitor #{}: {:?}", num, monitor.get_name());
}
@@ -18,62 +15,32 @@ fn main() {
let mut num = String::new();
io::stdin().read_line(&mut num).unwrap();
let num = num.trim().parse().ok().expect("Please enter a number");
let monitor = events_loop.get_available_monitors().nth(num).expect("Please enter a valid ID");
let monitor = winit::get_available_monitors().nth(num).expect("Please enter a valid ID");
println!("Using {:?}", monitor.get_name());
monitor
};
let window = winit::WindowBuilder::new()
let events_loop = winit::EventsLoop::new();
let _window = winit::WindowBuilder::new()
.with_title("Hello world!")
.with_fullscreen(Some(monitor))
.with_fullscreen(monitor)
.build(&events_loop)
.unwrap();
let mut is_fullscreen = true;
let mut is_maximized = false;
let mut decorations = true;
events_loop.run_forever(|event| {
println!("{:?}", event);
match event {
Event::WindowEvent { event, .. } => match event {
WindowEvent::CloseRequested => return ControlFlow::Break,
WindowEvent::KeyboardInput {
input:
winit::KeyboardInput {
virtual_keycode: Some(virtual_code),
state,
..
},
..
} => match (virtual_code, state) {
(winit::VirtualKeyCode::Escape, _) => return ControlFlow::Break,
(winit::VirtualKeyCode::F, winit::ElementState::Pressed) => {
is_fullscreen = !is_fullscreen;
if !is_fullscreen {
window.set_fullscreen(None);
} else {
window.set_fullscreen(Some(window.get_current_monitor()));
}
}
(winit::VirtualKeyCode::M, winit::ElementState::Pressed) => {
is_maximized = !is_maximized;
window.set_maximized(is_maximized);
}
(winit::VirtualKeyCode::D, winit::ElementState::Pressed) => {
decorations = !decorations;
window.set_decorations(decorations);
}
_ => (),
},
_ => (),
winit::Event::WindowEvent { event, .. } => {
match event {
winit::WindowEvent::Closed => events_loop.interrupt(),
winit::WindowEvent::KeyboardInput(_, _, Some(winit::VirtualKeyCode::Escape), _) => events_loop.interrupt(),
_ => ()
}
},
_ => {}
}
ControlFlow::Continue
});
}

42
examples/grabbing.rs Normal file
View File

@@ -0,0 +1,42 @@
extern crate winit;
use winit::{WindowEvent, ElementState};
fn main() {
let events_loop = winit::EventsLoop::new();
let window = winit::WindowBuilder::new().build(&events_loop).unwrap();
window.set_title("winit - Cursor grabbing test");
let mut grabbed = false;
events_loop.run_forever(|event| {
println!("{:?}", event);
match event {
winit::Event::WindowEvent { event, .. } => {
match event {
WindowEvent::KeyboardInput(ElementState::Pressed, _, _, _) => {
if grabbed {
grabbed = false;
window.set_cursor_state(winit::CursorState::Normal)
.ok().expect("could not ungrab mouse cursor");
} else {
grabbed = true;
window.set_cursor_state(winit::CursorState::Grab)
.ok().expect("could not grab mouse cursor");
}
},
WindowEvent::Closed => events_loop.interrupt(),
a @ WindowEvent::MouseMoved(_, _) => {
println!("{:?}", a);
},
_ => (),
}
},
}
});
}

74
examples/handling_close.rs
View File

@@ -1,74 +0,0 @@
extern crate winit;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let _window = winit::WindowBuilder::new()
.with_title("Your faithful window")
.build(&events_loop)
.unwrap();
let mut close_requested = false;
events_loop.run_forever(|event| {
use winit::WindowEvent::*;
use winit::ElementState::Released;
use winit::VirtualKeyCode::{N, Y};
match event {
winit::Event::WindowEvent { event, .. } => match event {
CloseRequested => {
// `CloseRequested` is sent when the close button on the window is pressed (or
// through whatever other mechanisms the window manager provides for closing a
// window). If you don't handle this event, the close button won't actually do
// anything.
// A common thing to do here is prompt the user if they have unsaved work.
// Creating a proper dialog box for that is far beyond the scope of this
// example, so here we'll just respond to the Y and N keys.
println!("Are you ready to bid your window farewell? [Y/N]");
close_requested = true;
// In applications where you can safely close the window without further
// action from the user, this is generally where you'd handle cleanup before
// closing the window. How to close the window is detailed in the handler for
// the Y key.
}
KeyboardInput {
input:
winit::KeyboardInput {
virtual_keycode: Some(virtual_code),
state: Released,
..
},
..
} => match virtual_code {
Y => {
if close_requested {
// This is where you'll want to do any cleanup you need.
println!("Buh-bye!");
// For a single-window application like this, you'd normally just
// break out of the event loop here. If you wanted to keep running the
// event loop (i.e. if it's a multi-window application), you need to
// drop the window. That closes it, and results in `Destroyed` being
// sent.
return winit::ControlFlow::Break;
}
}
N => {
if close_requested {
println!("Your window will continue to stay by your side.");
close_requested = false;
}
}
_ => (),
},
_ => (),
},
_ => (),
}
winit::ControlFlow::Continue
});
}

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15
examples/min_max_size.rs
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@@ -1,23 +1,20 @@
extern crate winit;
use winit::dpi::LogicalSize;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let events_loop = winit::EventsLoop::new();
let window = winit::WindowBuilder::new()
let _window = winit::WindowBuilder::new()
.with_min_dimensions(400, 200)
.with_max_dimensions(800, 400)
.build(&events_loop)
.unwrap();
window.set_min_dimensions(Some(LogicalSize::new(400.0, 200.0)));
window.set_max_dimensions(Some(LogicalSize::new(800.0, 400.0)));
events_loop.run_forever(|event| {
println!("{:?}", event);
match event {
winit::Event::WindowEvent { event: winit::WindowEvent::CloseRequested, .. } => winit::ControlFlow::Break,
_ => winit::ControlFlow::Continue,
winit::Event::WindowEvent { event: winit::WindowEvent::Closed, .. } => events_loop.interrupt(),
_ => ()
}
});
}

7
examples/monitor_list.rs
View File

@@ -1,7 +0,0 @@
extern crate winit;
fn main() {
let event_loop = winit::EventsLoop::new();
let window = winit::WindowBuilder::new().build(&event_loop).unwrap();
println!("{:#?}\nPrimary: {:#?}", window.get_available_monitors(), window.get_primary_monitor());
}

42
examples/multiwindow.rs
View File

@@ -1,33 +1,33 @@
extern crate winit;
use std::collections::HashMap;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let events_loop = winit::EventsLoop::new();
let mut windows = HashMap::new();
for _ in 0..3 {
let window = winit::Window::new(&events_loop).unwrap();
windows.insert(window.id(), window);
}
let window1 = winit::Window::new(&events_loop).unwrap();
let window2 = winit::Window::new(&events_loop).unwrap();
let window3 = winit::Window::new(&events_loop).unwrap();
let mut num_windows = 3;
events_loop.run_forever(|event| {
match event {
winit::Event::WindowEvent {
event: winit::WindowEvent::CloseRequested,
window_id,
} => {
println!("Window {:?} has received the signal to close", window_id);
// This drops the window, causing it to close.
windows.remove(&window_id);
if windows.is_empty() {
return winit::ControlFlow::Break;
winit::Event::WindowEvent { event: winit::WindowEvent::Closed, window_id } => {
if window_id == window1.id() {
println!("Window 1 has been closed")
} else if window_id == window2.id() {
println!("Window 2 has been closed")
} else if window_id == window3.id() {
println!("Window 3 has been closed");
} else {
unreachable!()
}
}
num_windows -= 1;
if num_windows == 0 {
events_loop.interrupt();
}
},
_ => (),
}
winit::ControlFlow::Continue
})
}

29
examples/proxy.rs
View File

@@ -1,29 +0,0 @@
extern crate winit;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let _window = winit::WindowBuilder::new()
.with_title("A fantastic window!")
.build(&events_loop)
.unwrap();
let proxy = events_loop.create_proxy();
std::thread::spawn(move || {
// Wake up the `events_loop` once every second.
loop {
std::thread::sleep(std::time::Duration::from_secs(1));
proxy.wakeup().unwrap();
}
});
events_loop.run_forever(|event| {
println!("{:?}", event);
match event {
winit::Event::WindowEvent { event: winit::WindowEvent::CloseRequested, .. } =>
winit::ControlFlow::Break,
_ => winit::ControlFlow::Continue,
}
});
}

38
examples/resizable.rs
View File

@@ -1,38 +0,0 @@
extern crate winit;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let mut resizable = false;
let window = winit::WindowBuilder::new()
.with_title("Hit space to toggle resizability.")
.with_dimensions((400, 200).into())
.with_resizable(resizable)
.build(&events_loop)
.unwrap();
events_loop.run_forever(|event| {
match event {
winit::Event::WindowEvent { event, .. } => match event {
winit::WindowEvent::CloseRequested => return winit::ControlFlow::Break,
winit::WindowEvent::KeyboardInput {
input:
winit::KeyboardInput {
virtual_keycode: Some(winit::VirtualKeyCode::Space),
state: winit::ElementState::Released,
..
},
..
} => {
resizable = !resizable;
println!("Resizable: {}", resizable);
window.set_resizable(resizable);
}
_ => (),
},
_ => (),
};
winit::ControlFlow::Continue
});
}

6
examples/transparent.rs
View File

@@ -1,7 +1,7 @@
extern crate winit;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let events_loop = winit::EventsLoop::new();
let window = winit::WindowBuilder::new().with_decorations(false)
.with_transparency(true)
@@ -13,8 +13,8 @@ fn main() {
println!("{:?}", event);
match event {
winit::Event::WindowEvent { event: winit::WindowEvent::CloseRequested, .. } => winit::ControlFlow::Break,
_ => winit::ControlFlow::Continue,
winit::Event::WindowEvent { event: winit::WindowEvent::Closed, .. } => events_loop.interrupt(),
_ => ()
}
});
}

11
examples/window.rs
View File

@@ -1,9 +1,9 @@
extern crate winit;
fn main() {
let mut events_loop = winit::EventsLoop::new();
let events_loop = winit::EventsLoop::new();
let _window = winit::WindowBuilder::new()
let window = winit::WindowBuilder::new()
.with_title("A fantastic window!")
.build(&events_loop)
.unwrap();
@@ -12,11 +12,8 @@ fn main() {
println!("{:?}", event);
match event {
winit::Event::WindowEvent {
event: winit::WindowEvent::CloseRequested,
..
} => winit::ControlFlow::Break,
_ => winit::ControlFlow::Continue,
winit::Event::WindowEvent { event: winit::WindowEvent::Closed, .. } => events_loop.interrupt(),
_ => ()
}
});
}

95
examples/window_icon.rs
View File

@@ -1,95 +0,0 @@
// Heads up: you need to compile this example with `--features icon_loading`.
// `Icon::from_path` won't be available otherwise, though for your own applications, you could use
// `Icon::from_rgba` if you don't want to depend on the `image` crate.
extern crate winit;
#[cfg(feature = "icon_loading")]
extern crate image;
use winit::Icon;
#[cfg(feature = "icon_loading")]
fn main() {
// You'll have to choose an icon size at your own discretion. On X11, the desired size varies
// by WM, and on Windows, you still have to account for screen scaling. Here we use 32px,
// since it seems to work well enough in most cases. Be careful about going too high, or
// you'll be bitten by the low-quality downscaling built into the WM.
let path = concat!(env!("CARGO_MANIFEST_DIR"), "/examples/icon.png");
// While `Icon::from_path` is the most straightforward, you have a few other options. If you
// want to use the `include_bytes` macro, then pass the result to `Icon::from_bytes`. See the
// docs for the full list of options (you'll have to generate the docs with the `icon_loading`
// feature enabled).
let icon = Icon::from_path(path).expect("Failed to open icon");
let mut events_loop = winit::EventsLoop::new();
let window = winit::WindowBuilder::new()
.with_title("An iconic window!")
// At present, this only does anything on Windows and X11, so if you want to save load
// time, you can put icon loading behind a function that returns `None` on other platforms.
.with_window_icon(Some(icon))
.build(&events_loop)
.unwrap();
events_loop.run_forever(|event| {
if let winit::Event::WindowEvent { event, .. } = event {
use winit::WindowEvent::*;
match event {
CloseRequested => return winit::ControlFlow::Break,
DroppedFile(path) => {
use image::GenericImage;
let icon_image = image::open(path).expect("Failed to open window icon");
let (width, height) = icon_image.dimensions();
const DESIRED_SIZE: u32 = 32;
let (new_width, new_height) = if width == height {
(DESIRED_SIZE, DESIRED_SIZE)
} else {
// Note that this will never divide by zero, due to the previous condition.
let aspect_adjustment = DESIRED_SIZE as f64
/ std::cmp::max(width, height) as f64;
(
(width as f64 * aspect_adjustment) as u32,
(height as f64 * aspect_adjustment) as u32,
)
};
// By scaling the icon ourselves, we get higher-quality filtering and save
// some memory.
let icon = image::imageops::resize(
&icon_image,
new_width,
new_height,
image::FilterType::Lanczos3,
);
let (offset_x, offset_y) = (
(DESIRED_SIZE - new_width) / 2,
(DESIRED_SIZE - new_height) / 2,
);
let mut canvas = image::ImageBuffer::new(DESIRED_SIZE, DESIRED_SIZE);
image::imageops::replace(
&mut canvas,
&icon,
offset_x,
offset_y,
);
window.set_window_icon(Some(canvas.into()));
},
_ => (),
}
}
winit::ControlFlow::Continue
});
}
#[cfg(not(feature = "icon_loading"))]
fn main() {
print!(
r#"This example requires the `icon_loading` feature:
cargo run --example window_icon --features icon_loading
"#);
}

101
src/api_transition.rs Normal file
View File

@@ -0,0 +1,101 @@
//! This temporary module generates types that wrap around the old API (winit v5 and below) and
//! expose the new API (winit v6 and above).
//!
//! This is temporary so that existing backends can smoothly transition. After all implementations
//! have finished transitionning, this module should disappear.
macro_rules! gen_api_transition {
() => {
pub struct EventsLoop {
windows: ::std::sync::Mutex<Vec<::std::sync::Arc<Window>>>,
interrupted: ::std::sync::atomic::AtomicBool,
}
impl EventsLoop {
pub fn new() -> EventsLoop {
EventsLoop {
windows: ::std::sync::Mutex::new(vec![]),
interrupted: ::std::sync::atomic::AtomicBool::new(false),
}
}
pub fn interrupt(&self) {
self.interrupted.store(true, ::std::sync::atomic::Ordering::Relaxed);
}
pub fn poll_events<F>(&self, mut callback: F)
where F: FnMut(::Event)
{
let mut windows = self.windows.lock().unwrap();
for window in windows.iter() {
for event in window.poll_events() {
callback(::Event::WindowEvent {
window_id: ::WindowId(WindowId(&**window as *const Window as usize)),
event: event,
})
}
}
}
pub fn run_forever<F>(&self, mut callback: F)
where F: FnMut(::Event)
{
self.interrupted.store(false, ::std::sync::atomic::Ordering::Relaxed);
// Yeah that's a very bad implementation.
loop {
self.poll_events(|e| callback(e));
::std::thread::sleep_ms(5);
if self.interrupted.load(::std::sync::atomic::Ordering::Relaxed) {
break;
}
}
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WindowId(usize);
pub struct Window2 {
pub window: ::std::sync::Arc<Window>,
events_loop: ::std::sync::Weak<EventsLoop>,
}
impl ::std::ops::Deref for Window2 {
type Target = Window;
#[inline]
fn deref(&self) -> &Window {
&*self.window
}
}
impl Window2 {
pub fn new(events_loop: ::std::sync::Arc<EventsLoop>, window: &::WindowAttributes,
pl_attribs: &PlatformSpecificWindowBuilderAttributes)
-> Result<Window2, CreationError>
{
let win = ::std::sync::Arc::new(try!(Window::new(window, pl_attribs)));
events_loop.windows.lock().unwrap().push(win.clone());
Ok(Window2 {
window: win,
events_loop: ::std::sync::Arc::downgrade(&events_loop),
})
}
#[inline]
pub fn id(&self) -> WindowId {
WindowId(&*self.window as *const Window as usize)
}
}
impl Drop for Window2 {
fn drop(&mut self) {
if let Some(ev) = self.events_loop.upgrade() {
let mut windows = ev.windows.lock().unwrap();
windows.retain(|w| &**w as *const Window != &*self.window as *const _);
}
}
}
};
}

317
src/dpi.rs
View File

@@ -1,317 +0,0 @@
//! DPI is important, so read the docs for this module if you don't want to be confused.
//!
//! Originally, `winit` dealt entirely in physical pixels (excluding unintentional inconsistencies), but now all
//! window-related functions both produce and consume logical pixels. Monitor-related functions still use physical
//! pixels, as do any context-related functions in `glutin`.
//!
//! If you've never heard of these terms before, then you're not alone, and this documentation will explain the
//! concepts.
//!
//! Modern screens have a defined physical resolution, most commonly 1920x1080. Indepedent of that is the amount of
//! space the screen occupies, which is to say, the height and width in millimeters. The relationship between these two
//! measurements is the *pixel density*. Mobile screens require a high pixel density, as they're held close to the
//! eyes. Larger displays also require a higher pixel density, hence the growing presence of 1440p and 4K displays.
//!
//! So, this presents a problem. Let's say we want to render a square 100px button. It will occupy 100x100 of the
//! screen's pixels, which in many cases, seems perfectly fine. However, because this size doesn't account for the
//! screen's dimensions or pixel density, the button's size can vary quite a bit. On a 4K display, it would be unusably
//! small.
//!
//! That's a description of what happens when the button is 100x100 *physical* pixels. Instead, let's try using 100x100
//! *logical* pixels. To map logical pixels to physical pixels, we simply multiply by the DPI (dots per inch) factor.
//! On a "typical" desktop display, the DPI factor will be 1.0, so 100x100 logical pixels equates to 100x100 physical
//! pixels. However, a 1440p display may have a DPI factor of 1.25, so the button is rendered as 125x125 physical pixels.
//! Ideally, the button now has approximately the same perceived size across varying displays.
//!
//! Failure to account for the DPI factor can create a badly degraded user experience. Most notably, it can make users
//! feel like they have bad eyesight, which will potentially cause them to think about growing elderly, resulting in
//! them entering an existential panic. Once users enter that state, they will no longer be focused on your application.
//!
//! There are two ways to get the DPI factor:
//! - You can track the `WindowEvent::HiDpiFactorChanged` event of your windows. This event is sent any
//! time the DPI factor changes, be it because the window moved to another monitor, or because the
//! user changed the configuration of their screen.
//! - You can also retrieve the DPI factor of a monitor by calling
//! [`MonitorId::get_hidpi_factor`](../struct.MonitorId.html#method.get_hidpi_factor), or the
//! current DPI factor applied to a window by calling
//! [`Window::get_hidpi_factor`](../struct.Window.html#method.get_hidpi_factor), which is roughly equivalent
//! to `window.get_current_monitor().get_hidpi_factor()`.
//!
//! Depending on the platform, the window's actual DPI factor may only be known after
//! the event loop has started and your window has been drawn once. To properly handle these cases,
//! the most robust way is to monitor the `WindowEvent::HiDpiFactorChanged` event and dynamically
//! adapt your drawing logic to follow the DPI factor.
//!
//! Here's an overview of what sort of DPI factors you can expect, and where they come from:
//! - **Windows:** On Windows 8 and 10, per-monitor scaling is readily configured by users from the display settings.
//! While users are free to select any option they want, they're only given a selection of "nice" DPI factors, i.e.
//! 1.0, 1.25, 1.5... on Windows 7, the DPI factor is global and changing it requires logging out.
//! - **macOS:** The buzzword is "retina displays", which have a DPI factor of 2.0. Otherwise, the DPI factor is 1.0.
//! Intermediate DPI factors are never used, thus 1440p displays/etc. aren't properly supported. It's possible for any
//! display to use that 2.0 DPI factor, given the use of the command line.
//! - **X11:** On X11, we calcuate the DPI factor based on the millimeter dimensions provided by XRandR. This can
//! result in a wide range of possible values, including some interesting ones like 1.0833333333333333. This can be
//! overridden using the `WINIT_HIDPI_FACTOR` environment variable, though that's not recommended.
//! - **Wayland:** On Wayland, DPI factors are very much at the discretion of the user.
//! - **iOS:** DPI factors are both constant and device-specific on iOS.
//! - **Android:** This feature isn't yet implemented on Android, so the DPI factor will always be returned as 1.0.
//!
//! The window's logical size is conserved across DPI changes, resulting in the physical size changing instead. This
//! may be surprising on X11, but is quite standard elsewhere. Physical size changes produce a
//! [`Resized`](../enum.WindowEvent.html#variant.Resized) event, even on platforms where no resize actually occurs,
//! such as macOS and Wayland. As a result, it's not necessary to separately handle
//! [`HiDpiFactorChanged`](../enum.WindowEvent.html#variant.HiDpiFactorChanged) if you're only listening for size.
//!
//! Your GPU has no awareness of the concept of logical pixels, and unless you like wasting pixel density, your
//! framebuffer's size should be in physical pixels.
/// Checks that the DPI factor is a normal positive `f64`.
///
/// All functions that take a DPI factor assert that this will return `true`. If you're sourcing DPI factors from
/// anywhere other than winit, it's recommended to validate them using this function before passing them to winit;
/// otherwise, you risk panics.
#[inline]
pub fn validate_hidpi_factor(dpi_factor: f64) -> bool {
dpi_factor.is_sign_positive() && dpi_factor.is_normal()
}
/// A position represented in logical pixels.
///
/// The position is stored as floats, so please be careful. Casting floats to integers truncates the fractional part,
/// which can cause noticable issues. To help with that, an `Into<(i32, i32)>` implementation is provided which
/// does the rounding for you.
#[derive(Debug, Copy, Clone, PartialEq)]
pub struct LogicalPosition {
pub x: f64,
pub y: f64,
}
impl LogicalPosition {
#[inline]
pub fn new(x: f64, y: f64) -> Self {
LogicalPosition { x, y }
}
#[inline]
pub fn from_physical<T: Into<PhysicalPosition>>(physical: T, dpi_factor: f64) -> Self {
physical.into().to_logical(dpi_factor)
}
#[inline]
pub fn to_physical(&self, dpi_factor: f64) -> PhysicalPosition {
assert!(validate_hidpi_factor(dpi_factor));
let x = self.x * dpi_factor;
let y = self.y * dpi_factor;
PhysicalPosition::new(x, y)
}
}
impl From<(f64, f64)> for LogicalPosition {
#[inline]
fn from((x, y): (f64, f64)) -> Self {
Self::new(x, y)
}
}
impl From<(i32, i32)> for LogicalPosition {
#[inline]
fn from((x, y): (i32, i32)) -> Self {
Self::new(x as f64, y as f64)
}
}
impl Into<(f64, f64)> for LogicalPosition {
#[inline]
fn into(self) -> (f64, f64) {
(self.x, self.y)
}
}
impl Into<(i32, i32)> for LogicalPosition {
/// Note that this rounds instead of truncating.
#[inline]
fn into(self) -> (i32, i32) {
(self.x.round() as _, self.y.round() as _)
}
}
/// A position represented in physical pixels.
///
/// The position is stored as floats, so please be careful. Casting floats to integers truncates the fractional part,
/// which can cause noticable issues. To help with that, an `Into<(i32, i32)>` implementation is provided which
/// does the rounding for you.
#[derive(Debug, Copy, Clone, PartialEq)]
pub struct PhysicalPosition {
pub x: f64,
pub y: f64,
}
impl PhysicalPosition {
#[inline]
pub fn new(x: f64, y: f64) -> Self {
PhysicalPosition { x, y }
}
#[inline]
pub fn from_logical<T: Into<LogicalPosition>>(logical: T, dpi_factor: f64) -> Self {
logical.into().to_physical(dpi_factor)
}
#[inline]
pub fn to_logical(&self, dpi_factor: f64) -> LogicalPosition {
assert!(validate_hidpi_factor(dpi_factor));
let x = self.x / dpi_factor;
let y = self.y / dpi_factor;
LogicalPosition::new(x, y)
}
}
impl From<(f64, f64)> for PhysicalPosition {
#[inline]
fn from((x, y): (f64, f64)) -> Self {
Self::new(x, y)
}
}
impl From<(i32, i32)> for PhysicalPosition {
#[inline]
fn from((x, y): (i32, i32)) -> Self {
Self::new(x as f64, y as f64)
}
}
impl Into<(f64, f64)> for PhysicalPosition {
#[inline]
fn into(self) -> (f64, f64) {
(self.x, self.y)
}
}
impl Into<(i32, i32)> for PhysicalPosition {
/// Note that this rounds instead of truncating.
#[inline]
fn into(self) -> (i32, i32) {
(self.x.round() as _, self.y.round() as _)
}
}
/// A size represented in logical pixels.
///
/// The size is stored as floats, so please be careful. Casting floats to integers truncates the fractional part,
/// which can cause noticable issues. To help with that, an `Into<(u32, u32)>` implementation is provided which
/// does the rounding for you.
#[derive(Debug, Copy, Clone, PartialEq)]
pub struct LogicalSize {
pub width: f64,
pub height: f64,
}
impl LogicalSize {
#[inline]
pub fn new(width: f64, height: f64) -> Self {
LogicalSize { width, height }
}
#[inline]
pub fn from_physical<T: Into<PhysicalSize>>(physical: T, dpi_factor: f64) -> Self {
physical.into().to_logical(dpi_factor)
}
#[inline]
pub fn to_physical(&self, dpi_factor: f64) -> PhysicalSize {
assert!(validate_hidpi_factor(dpi_factor));
let width = self.width * dpi_factor;
let height = self.height * dpi_factor;
PhysicalSize::new(width, height)
}
}
impl From<(f64, f64)> for LogicalSize {
#[inline]
fn from((width, height): (f64, f64)) -> Self {
Self::new(width, height)
}
}
impl From<(u32, u32)> for LogicalSize {
#[inline]
fn from((width, height): (u32, u32)) -> Self {
Self::new(width as f64, height as f64)
}
}
impl Into<(f64, f64)> for LogicalSize {
#[inline]
fn into(self) -> (f64, f64) {
(self.width, self.height)
}
}
impl Into<(u32, u32)> for LogicalSize {
/// Note that this rounds instead of truncating.
#[inline]
fn into(self) -> (u32, u32) {
(self.width.round() as _, self.height.round() as _)
}
}
/// A size represented in physical pixels.
///
/// The size is stored as floats, so please be careful. Casting floats to integers truncates the fractional part,
/// which can cause noticable issues. To help with that, an `Into<(u32, u32)>` implementation is provided which
/// does the rounding for you.
#[derive(Debug, Copy, Clone, PartialEq)]
pub struct PhysicalSize {
pub width: f64,
pub height: f64,
}
impl PhysicalSize {
#[inline]
pub fn new(width: f64, height: f64) -> Self {
PhysicalSize { width, height }
}
#[inline]
pub fn from_logical<T: Into<LogicalSize>>(logical: T, dpi_factor: f64) -> Self {
logical.into().to_physical(dpi_factor)
}
#[inline]
pub fn to_logical(&self, dpi_factor: f64) -> LogicalSize {
assert!(validate_hidpi_factor(dpi_factor));
let width = self.width / dpi_factor;
let height = self.height / dpi_factor;
LogicalSize::new(width, height)
}
}
impl From<(f64, f64)> for PhysicalSize {
#[inline]
fn from((width, height): (f64, f64)) -> Self {
Self::new(width, height)
}
}
impl From<(u32, u32)> for PhysicalSize {
#[inline]
fn from((width, height): (u32, u32)) -> Self {
Self::new(width as f64, height as f64)
}
}
impl Into<(f64, f64)> for PhysicalSize {
#[inline]
fn into(self) -> (f64, f64) {
(self.width, self.height)
}
}
impl Into<(u32, u32)> for PhysicalSize {
/// Note that this rounds instead of truncating.
#[inline]
fn into(self) -> (u32, u32) {
(self.width.round() as _, self.height.round() as _)
}
}

181
src/events.rs
View File

@@ -1,50 +1,31 @@
use std::path::PathBuf;
use WindowId;
use {DeviceId, LogicalPosition, LogicalSize, WindowId};
/// Describes a generic event.
#[derive(Clone, Debug)]
pub enum Event {
WindowEvent {
window_id: WindowId,
event: WindowEvent,
},
DeviceEvent {
device_id: DeviceId,
event: DeviceEvent,
},
Awakened,
/// The application has been suspended or resumed.
///
/// The parameter is true if app was suspended, and false if it has been resumed.
Suspended(bool),
}
}
/// Describes an event from a `Window`.
#[derive(Clone, Debug)]
pub enum WindowEvent {
/// The size of the window has changed. Contains the client area's new dimensions.
Resized(LogicalSize),
// TODO: remove ; can break the lib internally so be careful
Awakened,
/// The position of the window has changed. Contains the window's new position.
Moved(LogicalPosition),
/// The size of the window has changed.
Resized(u32, u32),
/// The window has been requested to close.
CloseRequested,
/// The position of the window has changed.
Moved(i32, i32),
/// The window has been destroyed.
Destroyed,
/// The window has been closed.
Closed,
/// A file has been dropped into the window.
DroppedFile(PathBuf),
/// A file is being hovered over the window.
HoveredFile(PathBuf),
/// A file was hovered, but has exited the window.
HoveredFileCancelled,
/// The window received a unicode character.
ReceivedCharacter(char),
@@ -54,124 +35,44 @@ pub enum WindowEvent {
Focused(bool),
/// An event from the keyboard has been received.
KeyboardInput { device_id: DeviceId, input: KeyboardInput },
KeyboardInput(ElementState, ScanCode, Option<VirtualKeyCode>, ModifiersState),
/// The cursor has moved on the window.
CursorMoved {
device_id: DeviceId,
/// (x,y) coords in pixels relative to the top-left corner of the window. Because the range of this data is
/// limited by the display area and it may have been transformed by the OS to implement effects such as cursor
/// acceleration, it should not be used to implement non-cursor-like interactions such as 3D camera control.
position: LogicalPosition,
modifiers: ModifiersState
},
///
/// The parameter are the (x,y) coords in pixels relative to the top-left corner of the window.
MouseMoved(i32, i32),
/// The cursor has entered the window.
CursorEntered { device_id: DeviceId },
MouseEntered,
/// The cursor has left the window.
CursorLeft { device_id: DeviceId },
MouseLeft,
/// A mouse wheel movement or touchpad scroll occurred.
MouseWheel { device_id: DeviceId, delta: MouseScrollDelta, phase: TouchPhase, modifiers: ModifiersState },
/// An mouse button press has been received.
MouseInput { device_id: DeviceId, state: ElementState, button: MouseButton, modifiers: ModifiersState },
MouseWheel(MouseScrollDelta, TouchPhase),
/// An event from the mouse has been received.
MouseInput(ElementState, MouseButton),
/// Touchpad pressure event.
///
/// At the moment, only supported on Apple forcetouch-capable macbooks.
/// The parameters are: pressure level (value between 0 and 1 representing how hard the touchpad
/// is being pressed) and stage (integer representing the click level).
TouchpadPressure { device_id: DeviceId, pressure: f32, stage: i64 },
/// Motion on some analog axis. May report data redundant to other, more specific events.
AxisMotion { device_id: DeviceId, axis: AxisId, value: f64 },
TouchpadPressure(f32, i64),
/// The window needs to be redrawn.
Refresh,
/// App has been suspended or resumed.
///
/// The parameter is true if app was suspended, and false if it has been resumed.
Suspended(bool),
/// Touch event has been received
Touch(Touch),
/// The DPI factor of the window has changed.
///
/// The following user actions can cause DPI changes:
///
/// * Changing the display's resolution.
/// * Changing the display's DPI factor (e.g. in Control Panel on Windows).
/// * Moving the window to a display with a different DPI factor.
///
/// For more information about DPI in general, see the [`dpi`](dpi/index.html) module.
HiDpiFactorChanged(f64),
Touch(Touch)
}
/// Represents raw hardware events that are not associated with any particular window.
///
/// Useful for interactions that diverge significantly from a conventional 2D GUI, such as 3D camera or first-person
/// game controls. Many physical actions, such as mouse movement, can produce both device and window events. Because
/// window events typically arise from virtual devices (corresponding to GUI cursors and keyboard focus) the device IDs
/// may not match.
///
/// Note that these events are delivered regardless of input focus.
#[derive(Clone, Debug)]
pub enum DeviceEvent {
Added,
Removed,
/// Change in physical position of a pointing device.
///
/// This represents raw, unfiltered physical motion. Not to be confused with `WindowEvent::CursorMoved`.
MouseMotion {
/// (x, y) change in position in unspecified units.
///
/// Different devices may use different units.
delta: (f64, f64),
},
/// Physical scroll event
MouseWheel {
delta: MouseScrollDelta,
},
/// Motion on some analog axis. This event will be reported for all arbitrary input devices
/// that winit supports on this platform, including mouse devices. If the device is a mouse
/// device then this will be reported alongside the MouseMotion event.
Motion { axis: AxisId, value: f64 },
Button { button: ButtonId, state: ElementState },
Key(KeyboardInput),
Text { codepoint: char },
}
/// Describes a keyboard input event.
#[derive(Debug, Clone, Copy)]
pub struct KeyboardInput {
/// Identifies the physical key pressed
///
/// This should not change if the user adjusts the host's keyboard map. Use when the physical location of the
/// key is more important than the key's host GUI semantics, such as for movement controls in a first-person
/// game.
pub scancode: ScanCode,
pub state: ElementState,
/// Identifies the semantic meaning of the key
///
/// Use when the semantics of the key are more important than the physical location of the key, such as when
/// implementing appropriate behavior for "page up."
pub virtual_keycode: Option<VirtualKeyCode>,
/// Modifier keys active at the time of this input.
///
/// This is tracked internally to avoid tracking errors arising from modifier key state changes when events from
/// this device are not being delivered to the application, e.g. due to keyboard focus being elsewhere.
pub modifiers: ModifiersState
}
/// Describes touch-screen input state.
#[derive(Debug, Hash, PartialEq, Eq, Clone, Copy)]
pub enum TouchPhase {
Started,
@@ -180,6 +81,7 @@ pub enum TouchPhase {
Cancelled
}
#[derive(Debug, Clone, Copy)]
/// Represents touch event
///
/// Every time user touches screen new Start event with some finger id is generated.
@@ -195,32 +97,21 @@ pub enum TouchPhase {
/// as previously received End event is a new finger and has nothing to do with an old one.
///
/// Touch may be cancelled if for example window lost focus.
#[derive(Debug, Clone, Copy)]
pub struct Touch {
pub device_id: DeviceId,
pub phase: TouchPhase,
pub location: LogicalPosition,
pub location: (f64,f64),
/// unique identifier of a finger.
pub id: u64
}
/// Hardware-dependent keyboard scan code.
pub type ScanCode = u32;
pub type ScanCode = u8;
/// Identifier for a specific analog axis on some device.
pub type AxisId = u32;
/// Identifier for a specific button on some device.
pub type ButtonId = u32;
/// Describes the input state of a key.
#[derive(Debug, Hash, PartialEq, Eq, Clone, Copy)]
pub enum ElementState {
Pressed,
Released,
}
/// Describes a button of a mouse controller.
#[derive(Debug, Hash, PartialEq, Eq, Clone, Copy)]
pub enum MouseButton {
Left,
@@ -229,7 +120,6 @@ pub enum MouseButton {
Other(u8),
}
/// Describes a difference in the mouse scroll wheel state.
#[derive(Debug, Clone, Copy, PartialEq)]
pub enum MouseScrollDelta {
/// Amount in lines or rows to scroll in the horizontal
@@ -244,12 +134,10 @@ pub enum MouseScrollDelta {
/// Scroll events are expressed as a PixelDelta if
/// supported by the device (eg. a touchpad) and
/// platform.
PixelDelta(LogicalPosition),
PixelDelta(f32, f32)
}
/// Symbolic name for a keyboard key.
#[derive(Debug, Hash, PartialEq, Eq, Clone, Copy)]
#[repr(u32)]
pub enum VirtualKeyCode {
/// The '1' key over the letters.
Key1,
@@ -349,8 +237,6 @@ pub enum VirtualKeyCode {
/// The "Compose" key on Linux.
Compose,
Caret,
Numlock,
Numpad0,
Numpad1,
@@ -385,6 +271,7 @@ pub enum VirtualKeyCode {
LAlt,
LBracket,
LControl,
LMenu,
LShift,
LWin,
Mail,
@@ -409,6 +296,7 @@ pub enum VirtualKeyCode {
RAlt,
RBracket,
RControl,
RMenu,
RShift,
RWin,
Semicolon,
@@ -431,15 +319,12 @@ pub enum VirtualKeyCode {
WebSearch,
WebStop,
Yen,
Copy,
Paste,
Cut,
}
/// Represents the current state of the keyboard modifiers
///
/// Each field of this struct represents a modifier and is `true` if this modifier is active.
#[derive(Default, Debug, Hash, PartialEq, Eq, Clone, Copy)]
#[derive(Default, Debug, Clone, Copy)]
pub struct ModifiersState {
/// The "shift" key
pub shift: bool,

170
src/icon.rs
View File

@@ -1,170 +0,0 @@
use std::{fmt, mem};
use std::error::Error;
#[cfg(feature = "icon_loading")]
use std::io::{BufRead, Seek};
#[cfg(feature = "icon_loading")]
use std::path::Path;
#[cfg(feature = "icon_loading")]
use image;
#[repr(C)]
#[derive(Debug)]
pub(crate) struct Pixel {
pub(crate) r: u8,
pub(crate) g: u8,
pub(crate) b: u8,
pub(crate) a: u8,
}
pub(crate) const PIXEL_SIZE: usize = mem::size_of::<Pixel>();
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
/// An error produced when using `Icon::from_rgba` with invalid arguments.
pub enum BadIcon {
/// Produced when the length of the `rgba` argument isn't divisible by 4, thus `rgba` can't be
/// safely interpreted as 32bpp RGBA pixels.
ByteCountNotDivisibleBy4 {
byte_count: usize,
},
/// Produced when the number of pixels (`rgba.len() / 4`) isn't equal to `width * height`.
/// At least one of your arguments is incorrect.
DimensionsVsPixelCount {
width: u32,
height: u32,
width_x_height: usize,
pixel_count: usize,
},
}
impl fmt::Display for BadIcon {
fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
let msg = match self {
&BadIcon::ByteCountNotDivisibleBy4 { byte_count } => format!(
"The length of the `rgba` argument ({:?}) isn't divisible by 4, making it impossible to interpret as 32bpp RGBA pixels.",
byte_count,
),
&BadIcon::DimensionsVsPixelCount {
width,
height,
width_x_height,
pixel_count,
} => format!(
"The specified dimensions ({:?}x{:?}) don't match the number of pixels supplied by the `rgba` argument ({:?}). For those dimensions, the expected pixel count is {:?}.",
width, height, pixel_count, width_x_height,
),
};
write!(formatter, "{}", msg)
}
}
impl Error for BadIcon {
fn description(&self) -> &str {
"A valid icon cannot be created from these arguments"
}
fn cause(&self) -> Option<&Error> {
Some(self)
}
}
#[derive(Debug, Clone, PartialEq, Eq)]
/// An icon used for the window titlebar, taskbar, etc.
///
/// Enabling the `icon_loading` feature provides you with several convenience methods for creating
/// an `Icon` from any format supported by the [image](https://github.com/PistonDevelopers/image)
/// crate.
pub struct Icon {
pub(crate) rgba: Vec<u8>,
pub(crate) width: u32,
pub(crate) height: u32,
}
impl Icon {
/// Creates an `Icon` from 32bpp RGBA data.
///
/// The length of `rgba` must be divisible by 4, and `width * height` must equal
/// `rgba.len() / 4`. Otherwise, this will return a `BadIcon` error.
pub fn from_rgba(rgba: Vec<u8>, width: u32, height: u32) -> Result<Self, BadIcon> {
if rgba.len() % PIXEL_SIZE != 0 {
return Err(BadIcon::ByteCountNotDivisibleBy4 { byte_count: rgba.len() });
}
let pixel_count = rgba.len() / PIXEL_SIZE;
if pixel_count != (width * height) as usize {
Err(BadIcon::DimensionsVsPixelCount {
width,
height,
width_x_height: (width * height) as usize,
pixel_count,
})
} else {
Ok(Icon { rgba, width, height })
}
}
#[cfg(feature = "icon_loading")]
/// Loads an `Icon` from the path of an image on the filesystem.
///
/// Requires the `icon_loading` feature.
pub fn from_path<P: AsRef<Path>>(path: P) -> image::ImageResult<Self> {
image::open(path).map(Into::into)
}
#[cfg(feature = "icon_loading")]
/// Loads an `Icon` from anything implementing `BufRead` and `Seek`.
///
/// Requires the `icon_loading` feature.
pub fn from_reader<R: BufRead + Seek>(
reader: R,
format: image::ImageFormat,
) -> image::ImageResult<Self> {
image::load(reader, format).map(Into::into)
}
#[cfg(feature = "icon_loading")]
/// Loads an `Icon` from the unprocessed bytes of an image file.
/// Uses heuristics to determine format.
///
/// Requires the `icon_loading` feature.
pub fn from_bytes(bytes: &[u8]) -> image::ImageResult<Self> {
image::load_from_memory(bytes).map(Into::into)
}
#[cfg(feature = "icon_loading")]
/// Loads an `Icon` from the unprocessed bytes of an image.
///
/// Requires the `icon_loading` feature.
pub fn from_bytes_with_format(
bytes: &[u8],
format: image::ImageFormat,
) -> image::ImageResult<Self> {
image::load_from_memory_with_format(bytes, format).map(Into::into)
}
}
#[cfg(feature = "icon_loading")]
/// Requires the `icon_loading` feature.
impl From<image::DynamicImage> for Icon {
fn from(image: image::DynamicImage) -> Self {
use image::{GenericImage, Pixel};
let (width, height) = image.dimensions();
let mut rgba = Vec::with_capacity((width * height) as usize * PIXEL_SIZE);
for (_, _, pixel) in image.pixels() {
rgba.extend_from_slice(&pixel.to_rgba().data);
}
Icon { rgba, width, height }
}
}
#[cfg(feature = "icon_loading")]
/// Requires the `icon_loading` feature.
impl From<image::RgbaImage> for Icon {
fn from(buf: image::RgbaImage) -> Self {
let (width, height) = buf.dimensions();
let mut rgba = Vec::with_capacity((width * height) as usize * PIXEL_SIZE);
for (_, _, pixel) in buf.enumerate_pixels() {
rgba.extend_from_slice(&pixel.data);
}
Icon { rgba, width, height }
}
}

304
src/lib.rs
View File

@@ -1,4 +1,4 @@
//! Winit allows you to build a window on as many platforms as possible.
//! Winit allows you to build a window on as many platforms as possible.
//!
//! # Building a window
//!
@@ -15,7 +15,7 @@
//! - Calling `Window::new(&events_loop)`.
//! - Calling `let builder = WindowBuilder::new()` then `builder.build(&events_loop)`.
//!
//! The first way is the simplest way and will give you default values for everything.
//! The first way is the simpliest way and will give you default values for everything.
//!
//! The second way allows you to customize the way your window will look and behave by modifying
//! the fields of the `WindowBuilder` object before you create the window.
@@ -25,28 +25,25 @@
//! Once a window has been created, it will *generate events*. For example whenever the user moves
//! the window, resizes the window, moves the mouse, etc. an event is generated.
//!
//! The events generated by a window can be retrieved from the `EventsLoop` the window was created
//! The events generated by a window can be retreived from the `EventsLoop` the window was created
//! with.
//!
//! There are two ways to do so. The first is to call `events_loop.poll_events(...)`, which will
//! retrieve all the events pending on the windows and immediately return after no new event is
//! retreive all the events pending on the windows and immediately return after no new event is
//! available. You usually want to use this method in application that render continuously on the
//! screen, such as video games.
//!
//! ```no_run
//! use winit::{Event, WindowEvent};
//! use winit::dpi::LogicalSize;
//! use winit::Event;
//! use winit::WindowEvent;
//! # use winit::EventsLoop;
//! # let mut events_loop = EventsLoop::new();
//! # let events_loop = EventsLoop::new();
//!
//! loop {
//! events_loop.poll_events(|event| {
//! match event {
//! Event::WindowEvent {
//! event: WindowEvent::Resized(LogicalSize { width, height }),
//! ..
//! } => {
//! println!("The window was resized to {}x{}", width, height);
//! Event::WindowEvent { event: WindowEvent::Resized(w, h), .. } => {
//! println!("The window was resized to {}x{}", w, h);
//! },
//! _ => ()
//! }
@@ -55,20 +52,21 @@
//! ```
//!
//! The second way is to call `events_loop.run_forever(...)`. As its name tells, it will run
//! forever unless it is stopped by returning `ControlFlow::Break`.
//! forever unless it is stopped by calling `events_loop.interrupt()`.
//!
//! ```no_run
//! use winit::{ControlFlow, Event, WindowEvent};
//! use winit::Event;
//! use winit::WindowEvent;
//! # use winit::EventsLoop;
//! # let mut events_loop = EventsLoop::new();
//! # let events_loop = EventsLoop::new();
//!
//! events_loop.run_forever(|event| {
//! match event {
//! Event::WindowEvent { event: WindowEvent::CloseRequested, .. } => {
//! println!("The close button was pressed; stopping");
//! ControlFlow::Break
//! Event::WindowEvent { event: WindowEvent::Closed, .. } => {
//! println!("The window was closed ; stopping");
//! events_loop.interrupt();
//! },
//! _ => ControlFlow::Continue,
//! _ => ()
//! }
//! });
//! ```
@@ -80,48 +78,58 @@
//! # Drawing on the window
//!
//! Winit doesn't provide any function that allows drawing on a window. However it allows you to
//! retrieve the raw handle of the window (see the `os` module for that), which in turn allows you
//! retreive the raw handle of the window (see the `os` module for that), which in turn allows you
//! to create an OpenGL/Vulkan/DirectX/Metal/etc. context that will draw on the window.
//!
#[allow(unused_imports)]
#[macro_use]
extern crate lazy_static;
extern crate libc;
#[macro_use]
extern crate log;
#[cfg(feature = "icon_loading")]
extern crate image;
extern crate shared_library;
extern crate libc;
#[cfg(target_os = "windows")]
extern crate winapi;
#[cfg(target_os = "windows")]
extern crate kernel32;
#[cfg(target_os = "windows")]
extern crate shell32;
#[cfg(target_os = "windows")]
extern crate gdi32;
#[cfg(target_os = "windows")]
extern crate user32;
#[cfg(target_os = "windows")]
extern crate dwmapi;
#[cfg(any(target_os = "macos", target_os = "ios"))]
#[macro_use]
extern crate objc;
#[cfg(target_os = "macos")]
extern crate cgl;
#[cfg(target_os = "macos")]
extern crate cocoa;
#[cfg(target_os = "macos")]
extern crate core_foundation;
#[cfg(target_os = "macos")]
extern crate core_graphics;
#[cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "netbsd", target_os = "openbsd"))]
#[cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd"))]
extern crate x11_dl;
#[cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "netbsd", target_os = "openbsd"))]
extern crate parking_lot;
#[cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "netbsd", target_os = "openbsd"))]
extern crate percent_encoding;
#[cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "netbsd", target_os = "openbsd"))]
extern crate smithay_client_toolkit as sctk;
#[cfg(any(target_os = "linux", target_os = "freebsd", target_os = "dragonfly", target_os = "openbsd"))]
#[macro_use(wayland_env,declare_handler)]
extern crate wayland_client;
use std::sync::Arc;
pub(crate) use dpi::*; // TODO: Actually change the imports throughout the codebase.
pub use events::*;
pub use window::{AvailableMonitorsIter, MonitorId};
pub use icon::*;
pub use window::{AvailableMonitorsIter, MonitorId, get_available_monitors, get_primary_monitor};
pub use native_monitor::NativeMonitorId;
#[macro_use]
mod api_transition;
pub mod dpi;
mod events;
mod icon;
mod platform;
mod events;
mod window;
pub mod os;
@@ -131,22 +139,25 @@ pub mod os;
/// # Example
///
/// ```no_run
/// use winit::{Event, EventsLoop, Window, WindowEvent, ControlFlow};
/// use winit::Event;
/// use winit::EventsLoop;
/// use winit::Window;
/// use winit::WindowEvent;
///
/// let mut events_loop = EventsLoop::new();
/// let events_loop = EventsLoop::new();
/// let window = Window::new(&events_loop).unwrap();
///
/// events_loop.run_forever(|event| {
/// match event {
/// Event::WindowEvent { event: WindowEvent::CloseRequested, .. } => {
/// ControlFlow::Break
/// Event::WindowEvent { event: WindowEvent::Closed, .. } => {
/// events_loop.interrupt();
/// },
/// _ => ControlFlow::Continue,
/// _ => ()
/// }
/// });
/// ```
pub struct Window {
window: platform::Window,
window: platform::Window2,
}
/// Identifier of a window. Unique for each window.
@@ -158,136 +169,42 @@ pub struct Window {
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WindowId(platform::WindowId);
/// Identifier of an input device.
///
/// Whenever you receive an event arising from a particular input device, this event contains a `DeviceId` which
/// identifies its origin. Note that devices may be virtual (representing an on-screen cursor and keyboard focus) or
/// physical. Virtual devices typically aggregate inputs from multiple physical devices.
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct DeviceId(platform::DeviceId);
/// Provides a way to retrieve events from the system and from the windows that were registered to
/// the events loop.
///
/// An `EventsLoop` can be seen more or less as a "context". Calling `EventsLoop::new()`
/// initializes everything that will be required to create windows. For example on Linux creating
/// an events loop opens a connection to the X or Wayland server.
///
/// To wake up an `EventsLoop` from a another thread, see the `EventsLoopProxy` docs.
///
/// Note that the `EventsLoop` cannot be shared accross threads (due to platform-dependant logic
/// forbiding it), as such it is neither `Send` nor `Sync`. If you need cross-thread access, the
/// `Window` created from this `EventsLoop` _can_ be sent to an other thread, and the
/// `EventsLoopProxy` allows you to wakeup an `EventsLoop` from an other thread.
/// Provides a way to retreive events from the windows that were registered to it.
// TODO: document usage in multiple threads
pub struct EventsLoop {
events_loop: platform::EventsLoop,
_marker: ::std::marker::PhantomData<*mut ()> // Not Send nor Sync
}
/// Returned by the user callback given to the `EventsLoop::run_forever` method.
///
/// Indicates whether the `run_forever` method should continue or complete.
#[derive(Copy, Clone, Debug, PartialEq, Eq)]
pub enum ControlFlow {
/// Continue looping and waiting for events.
Continue,
/// Break from the event loop.
Break,
events_loop: Arc<platform::EventsLoop>,
}
impl EventsLoop {
/// Builds a new events loop.
///
/// Usage will result in display backend initialisation, this can be controlled on linux
/// using an environment variable `WINIT_UNIX_BACKEND`. Legal values are `x11` and `wayland`.
/// If it is not set, winit will try to connect to a wayland connection, and if it fails will
/// fallback on x11. If this variable is set with any other value, winit will panic.
pub fn new() -> EventsLoop {
EventsLoop {
events_loop: platform::EventsLoop::new(),
_marker: ::std::marker::PhantomData,
events_loop: Arc::new(platform::EventsLoop::new()),
}
}
/// Returns the list of all the monitors available on the system.
///
// Note: should be replaced with `-> impl Iterator` once stable.
#[inline]
pub fn get_available_monitors(&self) -> AvailableMonitorsIter {
let data = self.events_loop.get_available_monitors();
AvailableMonitorsIter{ data: data.into_iter() }
}
/// Returns the primary monitor of the system.
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
MonitorId { inner: self.events_loop.get_primary_monitor() }
}
/// Fetches all the events that are pending, calls the callback function for each of them,
/// and returns.
#[inline]
pub fn poll_events<F>(&mut self, callback: F)
pub fn poll_events<F>(&self, callback: F)
where F: FnMut(Event)
{
self.events_loop.poll_events(callback)
}
/// Calls `callback` every time an event is received. If no event is available, sleeps the
/// current thread and waits for an event. If the callback returns `ControlFlow::Break` then
/// `run_forever` will immediately return.
///
/// # Danger!
///
/// The callback is run after *every* event, so if its execution time is non-trivial the event queue may not empty
/// at a sufficient rate. Rendering in the callback with vsync enabled **will** cause significant lag.
/// Runs forever until `interrupt()` is called. Whenever an event happens, calls the callback.
#[inline]
pub fn run_forever<F>(&mut self, callback: F)
where F: FnMut(Event) -> ControlFlow
pub fn run_forever<F>(&self, callback: F)
where F: FnMut(Event)
{
self.events_loop.run_forever(callback)
}
/// Creates an `EventsLoopProxy` that can be used to wake up the `EventsLoop` from another
/// thread.
pub fn create_proxy(&self) -> EventsLoopProxy {
EventsLoopProxy {
events_loop_proxy: self.events_loop.create_proxy(),
}
}
}
/// Used to wake up the `EventsLoop` from another thread.
#[derive(Clone)]
pub struct EventsLoopProxy {
events_loop_proxy: platform::EventsLoopProxy,
}
impl EventsLoopProxy {
/// Wake up the `EventsLoop` from which this proxy was created.
///
/// This causes the `EventsLoop` to emit an `Awakened` event.
///
/// Returns an `Err` if the associated `EventsLoop` no longer exists.
pub fn wakeup(&self) -> Result<(), EventsLoopClosed> {
self.events_loop_proxy.wakeup()
}
}
/// The error that is returned when an `EventsLoopProxy` attempts to wake up an `EventsLoop` that
/// no longer exists.
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub struct EventsLoopClosed;
impl std::fmt::Display for EventsLoopClosed {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
write!(f, "{}", std::error::Error::description(self))
}
}
impl std::error::Error for EventsLoopClosed {
fn description(&self) -> &str {
"Tried to wake up a closed `EventsLoop`"
/// If we called `run_forever()`, stops the process of waiting for events.
// TODO: what if we're waiting from multiple threads?
#[inline]
pub fn interrupt(&self) {
self.events_loop.interrupt()
}
}
@@ -302,7 +219,7 @@ pub struct WindowBuilder {
}
/// Error that can happen while creating a window or a headless renderer.
#[derive(Debug, Clone)]
#[derive(Debug)]
pub enum CreationError {
OsError(String),
/// TODO: remove this error
@@ -330,7 +247,6 @@ impl std::error::Error for CreationError {
}
}
/// Describes the appearance of the mouse cursor.
#[derive(Debug, Copy, Clone, PartialEq)]
pub enum MouseCursor {
/// The platform-dependent default cursor.
@@ -357,6 +273,7 @@ pub enum MouseCursor {
/// Cursor showing that something cannot be done.
NotAllowed,
ContextMenu,
NoneCursor,
Cell,
VerticalText,
Alias,
@@ -386,51 +303,52 @@ pub enum MouseCursor {
RowResize,
}
impl Default for MouseCursor {
fn default() -> Self {
MouseCursor::Default
}
/// Describes how glutin handles the cursor.
#[derive(Debug, Copy, Clone, PartialEq)]
pub enum CursorState {
/// Normal cursor behavior.
Normal,
/// The cursor will be invisible when over the window.
Hide,
/// Grabs the mouse cursor. The cursor's motion will be confined to this
/// window and the window has exclusive access to further events regarding
/// the cursor.
///
/// This is useful for first-person cameras for example.
Grab,
}
/// Attributes to use when creating a window.
#[derive(Debug, Clone)]
#[derive(Clone)]
pub struct WindowAttributes {
/// The dimensions of the window. If this is `None`, some platform-specific dimensions will be
/// used.
///
/// The default is `None`.
pub dimensions: Option<LogicalSize>,
pub dimensions: Option<(u32, u32)>,
/// The minimum dimensions a window can be, If this is `None`, the window will have no minimum dimensions (aside from reserved).
///
/// The default is `None`.
pub min_dimensions: Option<LogicalSize>,
pub min_dimensions: Option<(u32, u32)>,
/// The maximum dimensions a window can be, If this is `None`, the maximum will have no maximum or will be set to the primary monitor's dimensions by the platform.
///
/// The default is `None`.
pub max_dimensions: Option<LogicalSize>,
pub max_dimensions: Option<(u32, u32)>,
/// Whether the window is resizable or not.
///
/// The default is `true`.
pub resizable: bool,
/// Whether the window should be set as fullscreen upon creation.
/// If `Some`, the window will be in fullscreen mode with the given monitor.
///
/// The default is `None`.
pub fullscreen: Option<MonitorId>,
pub monitor: Option<platform::MonitorId>,
/// The title of the window in the title bar.
///
/// The default is `"winit window"`.
/// The default is `"glutin window"`.
pub title: String,
/// Whether the window should be maximized upon creation.
///
/// The default is `false`.
pub maximized: bool,
/// Whether the window should be immediately visible upon creation.
///
/// The default is `true`.
@@ -447,18 +365,8 @@ pub struct WindowAttributes {
/// The default is `true`.
pub decorations: bool,
/// Whether the window should always be on top of other windows.
///
/// The default is `false`.
pub always_on_top: bool,
/// The window icon.
///
/// The default is `None`.
pub window_icon: Option<Icon>,
/// [iOS only] Enable multitouch,
/// see [multipleTouchEnabled](https://developer.apple.com/documentation/uikit/uiview/1622519-multipletouchenabled)
/// [iOS only] Enable multitouch, see [UIView#multipleTouchEnabled]
/// (https://developer.apple.com/library/ios/documentation/UIKit/Reference/UIView_Class/#//apple_ref/occ/instp/UIView/multipleTouchEnabled)
pub multitouch: bool,
}
@@ -469,16 +377,28 @@ impl Default for WindowAttributes {
dimensions: None,
min_dimensions: None,
max_dimensions: None,
resizable: true,
title: "winit window".to_owned(),
maximized: false,
fullscreen: None,
monitor: None,
title: "glutin window".to_owned(),
visible: true,
transparent: false,
decorations: true,
always_on_top: false,
window_icon: None,
multitouch: false,
}
}
}
mod native_monitor {
/// Native platform identifier for a monitor. Different platforms use fundamentally different types
/// to represent a monitor ID.
#[derive(Clone, PartialEq, Eq)]
pub enum NativeMonitorId {
/// Cocoa and X11 use a numeric identifier to represent a monitor.
Numeric(u32),
/// Win32 uses a Unicode string to represent a monitor.
Name(String),
/// Other platforms (Android) don't support monitor identification.
Unavailable
}
}

13
src/os/android.rs
View File

@@ -1,22 +1,9 @@
#![cfg(any(target_os = "android"))]
use std::os::raw::c_void;
use EventsLoop;
use Window;
use WindowBuilder;
/// Additional methods on `EventsLoop` that are specific to Android.
pub trait EventsLoopExt {
/// Makes it possible for glutin to register a callback when a suspend event happens on Android
fn set_suspend_callback(&self, cb: Option<Box<Fn(bool) -> ()>>);
}
impl EventsLoopExt for EventsLoop {
fn set_suspend_callback(&self, cb: Option<Box<Fn(bool) -> ()>>) {
self.events_loop.set_suspend_callback(cb);
}
}
/// Additional methods on `Window` that are specific to Android.
pub trait WindowExt {
fn get_native_window(&self) -> *const c_void;

59
src/os/ios.rs
View File

@@ -1,59 +0,0 @@
#![cfg(target_os = "ios")]
use std::os::raw::c_void;
use {MonitorId, Window, WindowBuilder};
/// Additional methods on `Window` that are specific to iOS.
pub trait WindowExt {
/// Returns a pointer to the `UIWindow` that is used by this window.
///
/// The pointer will become invalid when the `Window` is destroyed.
fn get_uiwindow(&self) -> *mut c_void;
/// Returns a pointer to the `UIView` that is used by this window.
///
/// The pointer will become invalid when the `Window` is destroyed.
fn get_uiview(&self) -> *mut c_void;
}
impl WindowExt for Window {
#[inline]
fn get_uiwindow(&self) -> *mut c_void {
self.window.get_uiwindow() as _
}
#[inline]
fn get_uiview(&self) -> *mut c_void {
self.window.get_uiview() as _
}
}
/// Additional methods on `WindowBuilder` that are specific to iOS.
pub trait WindowBuilderExt {
/// Sets the root view class used by the `Window`, otherwise a barebones `UIView` is provided.
///
/// The class will be initialized by calling `[root_view initWithFrame:CGRect]`
fn with_root_view_class(self, root_view_class: *const c_void) -> WindowBuilder;
}
impl WindowBuilderExt for WindowBuilder {
#[inline]
fn with_root_view_class(mut self, root_view_class: *const c_void) -> WindowBuilder {
self.platform_specific.root_view_class = unsafe { &*(root_view_class as *const _) };
self
}
}
/// Additional methods on `MonitorId` that are specific to iOS.
pub trait MonitorIdExt {
/// Returns a pointer to the `UIScreen` that is used by this monitor.
fn get_uiscreen(&self) -> *mut c_void;
}
impl MonitorIdExt for MonitorId {
#[inline]
fn get_uiscreen(&self) -> *mut c_void {
self.inner.get_uiscreen() as _
}
}

88
src/os/macos.rs Normal file → Executable file
View File

@@ -3,7 +3,7 @@
use std::convert::From;
use std::os::raw::c_void;
use cocoa::appkit::NSApplicationActivationPolicy;
use {LogicalSize, MonitorId, Window, WindowBuilder};
use {Window, WindowBuilder};
/// Additional methods on `Window` that are specific to MacOS.
pub trait WindowExt {
@@ -61,99 +61,15 @@ impl From<ActivationPolicy> for NSApplicationActivationPolicy {
}
/// Additional methods on `WindowBuilder` that are specific to MacOS.
///
/// **Note:** Properties dealing with the titlebar will be overwritten by the `with_decorations` method
/// on the base `WindowBuilder`:
///
/// - `with_titlebar_transparent`
/// - `with_title_hidden`
/// - `with_titlebar_hidden`
/// - `with_titlebar_buttons_hidden`
/// - `with_fullsize_content_view`
pub trait WindowBuilderExt {
/// Sets the activation policy for the window being built.
fn with_activation_policy(self, activation_policy: ActivationPolicy) -> WindowBuilder;
/// Enables click-and-drag behavior for the entire window, not just the titlebar.
fn with_movable_by_window_background(self, movable_by_window_background: bool) -> WindowBuilder;
/// Makes the titlebar transparent and allows the content to appear behind it.
fn with_titlebar_transparent(self, titlebar_transparent: bool) -> WindowBuilder;
/// Hides the window title.
fn with_title_hidden(self, title_hidden: bool) -> WindowBuilder;
/// Hides the window titlebar.
fn with_titlebar_hidden(self, titlebar_hidden: bool) -> WindowBuilder;
/// Hides the window titlebar buttons.
fn with_titlebar_buttons_hidden(self, titlebar_buttons_hidden: bool) -> WindowBuilder;
/// Makes the window content appear behind the titlebar.
fn with_fullsize_content_view(self, fullsize_content_view: bool) -> WindowBuilder;
/// Build window with `resizeIncrements` property. Values must not be 0.
fn with_resize_increments(self, increments: LogicalSize) -> WindowBuilder;
}
impl WindowBuilderExt for WindowBuilder {
/// Sets the activation policy for the window being built
#[inline]
fn with_activation_policy(mut self, activation_policy: ActivationPolicy) -> WindowBuilder {
self.platform_specific.activation_policy = activation_policy;
self
}
#[inline]
fn with_movable_by_window_background(mut self, movable_by_window_background: bool) -> WindowBuilder {
self.platform_specific.movable_by_window_background = movable_by_window_background;
self
}
#[inline]
fn with_titlebar_transparent(mut self, titlebar_transparent: bool) -> WindowBuilder {
self.platform_specific.titlebar_transparent = titlebar_transparent;
self
}
#[inline]
fn with_titlebar_hidden(mut self, titlebar_hidden: bool) -> WindowBuilder {
self.platform_specific.titlebar_hidden = titlebar_hidden;
self
}
#[inline]
fn with_titlebar_buttons_hidden(mut self, titlebar_buttons_hidden: bool) -> WindowBuilder {
self.platform_specific.titlebar_buttons_hidden = titlebar_buttons_hidden;
self
}
#[inline]
fn with_title_hidden(mut self, title_hidden: bool) -> WindowBuilder {
self.platform_specific.title_hidden = title_hidden;
self
}
#[inline]
fn with_fullsize_content_view(mut self, fullsize_content_view: bool) -> WindowBuilder {
self.platform_specific.fullsize_content_view = fullsize_content_view;
self
}
#[inline]
fn with_resize_increments(mut self, increments: LogicalSize) -> WindowBuilder {
self.platform_specific.resize_increments = Some(increments.into());
self
}
}
/// Additional methods on `MonitorId` that are specific to MacOS.
pub trait MonitorIdExt {
/// Returns the identifier of the monitor for Cocoa.
fn native_id(&self) -> u32;
/// Returns a pointer to the NSScreen representing this monitor.
fn get_nsscreen(&self) -> Option<*mut c_void>;
}
impl MonitorIdExt for MonitorId {
#[inline]
fn native_id(&self) -> u32 {
self.inner.get_native_identifier()
}
fn get_nsscreen(&self) -> Option<*mut c_void> {
self.inner.get_nsscreen().map(|s| s as *mut c_void)
}
}

2
src/os/mod.rs
View File

@@ -3,7 +3,6 @@
//! Contains the follow modules:
//!
//! - `android`
//! - `ios`
//! - `macos`
//! - `unix`
//! - `windows`
@@ -11,7 +10,6 @@
//! However only the module corresponding to the platform you're compiling to will be available.
//!
pub mod android;
pub mod ios;
pub mod macos;
pub mod unix;
pub mod windows;

227
src/os/unix.rs
View File

@@ -1,145 +1,91 @@
#![cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "netbsd", target_os = "openbsd"))]
#![cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd"))]
use std::os::raw;
use std::ptr;
use std::sync::Arc;
use {
EventsLoop,
LogicalSize,
MonitorId,
Window,
WindowBuilder,
};
use platform::{
EventsLoop as LinuxEventsLoop,
Window as LinuxWindow,
};
use std::ptr;
use libc;
use Window;
use platform::Window2 as LinuxWindow;
use platform::{UnixBackend, UNIX_BACKEND};
use WindowBuilder;
use platform::x11::XConnection;
use platform::x11::ffi::XVisualInfo;
// TODO: stupid hack so that glutin can do its work
#[doc(hidden)]
use wayland_client::protocol::wl_display::WlDisplay;
use wayland_client::protocol::wl_surface::WlSurface;
pub use platform::x11;
pub use platform::XNotSupported;
pub use platform::x11::util::WindowType as XWindowType;
/// Additional methods on `EventsLoop` that are specific to Linux.
pub trait EventsLoopExt {
/// Builds a new `EventsLoop` that is forced to use X11.
fn new_x11() -> Result<Self, XNotSupported>
where Self: Sized;
/// Builds a new `EventsLoop` that is forced to use Wayland.
fn new_wayland() -> Self
where Self: Sized;
/// True if the `EventsLoop` uses Wayland.
fn is_wayland(&self) -> bool;
/// True if the `EventsLoop` uses X11.
fn is_x11(&self) -> bool;
#[doc(hidden)]
fn get_xlib_xconnection(&self) -> Option<Arc<XConnection>>;
}
impl EventsLoopExt for EventsLoop {
#[inline]
fn new_x11() -> Result<Self, XNotSupported> {
LinuxEventsLoop::new_x11().map(|ev|
EventsLoop {
events_loop: ev,
_marker: ::std::marker::PhantomData,
}
)
}
#[inline]
fn new_wayland() -> Self {
EventsLoop {
events_loop: match LinuxEventsLoop::new_wayland() {
Ok(e) => e,
Err(_) => panic!() // TODO: propagate
},
_marker: ::std::marker::PhantomData,
}
}
#[inline]
fn is_wayland(&self) -> bool {
self.events_loop.is_wayland()
}
#[inline]
fn is_x11(&self) -> bool {
!self.events_loop.is_wayland()
}
#[inline]
#[doc(hidden)]
fn get_xlib_xconnection(&self) -> Option<Arc<XConnection>> {
self.events_loop.x_connection().cloned()
// TODO: do not expose XConnection
pub fn get_x11_xconnection() -> Option<Arc<XConnection>> {
match *UNIX_BACKEND {
UnixBackend::X(ref connec) => Some(connec.clone()),
_ => None,
}
}
/// Additional methods on `Window` that are specific to Unix.
pub trait WindowExt {
/// Returns the ID of the `Window` xlib object that is used by this window.
/// Returns a pointer to the `Window` object of xlib that is used by this window.
///
/// Returns `None` if the window doesn't use xlib (if it uses wayland for example).
fn get_xlib_window(&self) -> Option<raw::c_ulong>;
///
/// The pointer will become invalid when the glutin `Window` is destroyed.
fn get_xlib_window(&self) -> Option<*mut libc::c_void>;
/// Returns a pointer to the `Display` object of xlib that is used by this window.
///
/// Returns `None` if the window doesn't use xlib (if it uses wayland for example).
///
/// The pointer will become invalid when the glutin `Window` is destroyed.
fn get_xlib_display(&self) -> Option<*mut raw::c_void>;
fn get_xlib_display(&self) -> Option<*mut libc::c_void>;
fn get_xlib_screen_id(&self) -> Option<raw::c_int>;
fn get_xlib_screen_id(&self) -> Option<*mut libc::c_void>;
#[doc(hidden)]
fn get_xlib_xconnection(&self) -> Option<Arc<XConnection>>;
/// Set window urgency hint (`XUrgencyHint`). Only relevant on X.
fn set_urgent(&self, is_urgent: bool);
/// This function returns the underlying `xcb_connection_t` of an xlib `Display`.
///
/// Returns `None` if the window doesn't use xlib (if it uses wayland for example).
///
/// The pointer will become invalid when the glutin `Window` is destroyed.
fn get_xcb_connection(&self) -> Option<*mut raw::c_void>;
fn get_xcb_connection(&self) -> Option<*mut libc::c_void>;
/// Returns a pointer to the `wl_surface` object of wayland that is used by this window.
///
/// Returns `None` if the window doesn't use wayland (if it uses xlib for example).
///
/// The pointer will become invalid when the glutin `Window` is destroyed.
fn get_wayland_surface(&self) -> Option<*mut raw::c_void>;
fn get_wayland_surface(&self) -> Option<*mut libc::c_void>;
/// Returns a pointer to the `wl_display` object of wayland that is used by this window.
///
/// Returns `None` if the window doesn't use wayland (if it uses xlib for example).
///
/// The pointer will become invalid when the glutin `Window` is destroyed.
fn get_wayland_display(&self) -> Option<*mut raw::c_void>;
fn get_wayland_display(&self) -> Option<*mut libc::c_void>;
/// Check if the window is ready for drawing
/// Returns a reference to the `WlSurface` object of wayland that is used by this window.
///
/// It is a remnant of a previous implementation detail for the
/// wayland backend, and is no longer relevant.
/// For use with the `wayland-client` crate.
///
/// Always return true.
#[deprecated]
fn is_ready(&self) -> bool;
/// **This function is not part of winit's public API.**
///
/// Returns `None` if the window doesn't use wayland (if it uses xlib for example).
fn get_wayland_client_surface(&self) -> Option<&WlSurface>;
/// Returns a pointer to the `WlDisplay` object of wayland that is used by this window.
///
/// For use with the `wayland-client` crate.
///
/// **This function is not part of winit's public API.**
///
/// Returns `None` if the window doesn't use wayland (if it uses xlib for example).
fn get_wayland_client_display(&self) -> Option<&WlDisplay>;
}
impl WindowExt for Window {
#[inline]
fn get_xlib_window(&self) -> Option<raw::c_ulong> {
fn get_xlib_window(&self) -> Option<*mut libc::c_void> {
match self.window {
LinuxWindow::X(ref w) => Some(w.get_xlib_window()),
_ => None
@@ -147,23 +93,20 @@ impl WindowExt for Window {
}
#[inline]
fn get_xlib_display(&self) -> Option<*mut raw::c_void> {
fn get_xlib_display(&self) -> Option<*mut libc::c_void> {
match self.window {
LinuxWindow::X(ref w) => Some(w.get_xlib_display()),
_ => None
}
}
#[inline]
fn get_xlib_screen_id(&self) -> Option<raw::c_int> {
fn get_xlib_screen_id(&self) -> Option<*mut libc::c_void> {
match self.window {
LinuxWindow::X(ref w) => Some(w.get_xlib_screen_id()),
_ => None
}
}
#[inline]
#[doc(hidden)]
fn get_xlib_xconnection(&self) -> Option<Arc<XConnection>> {
match self.window {
LinuxWindow::X(ref w) => Some(w.get_xlib_xconnection()),
@@ -171,8 +114,7 @@ impl WindowExt for Window {
}
}
#[inline]
fn get_xcb_connection(&self) -> Option<*mut raw::c_void> {
fn get_xcb_connection(&self) -> Option<*mut libc::c_void> {
match self.window {
LinuxWindow::X(ref w) => Some(w.get_xcb_connection()),
_ => None
@@ -180,49 +122,39 @@ impl WindowExt for Window {
}
#[inline]
fn set_urgent(&self, is_urgent: bool) {
if let LinuxWindow::X(ref w) = self.window {
w.set_urgent(is_urgent);
}
fn get_wayland_surface(&self) -> Option<*mut libc::c_void> {
use wayland_client::Proxy;
self.get_wayland_client_surface().map(|p| p.ptr() as *mut _)
}
#[inline]
fn get_wayland_display(&self) -> Option<*mut libc::c_void> {
use wayland_client::Proxy;
self.get_wayland_client_display().map(|p| p.ptr() as *mut _)
}
#[inline]
fn get_wayland_surface(&self) -> Option<*mut raw::c_void> {
fn get_wayland_client_surface(&self) -> Option<&WlSurface> {
match self.window {
LinuxWindow::Wayland(ref w) => Some(w.get_surface().c_ptr() as *mut _),
LinuxWindow::Wayland(ref w) => Some(w.get_surface()),
_ => None
}
}
#[inline]
fn get_wayland_display(&self) -> Option<*mut raw::c_void> {
fn get_wayland_client_display(&self) -> Option<&WlDisplay> {
match self.window {
LinuxWindow::Wayland(ref w) => Some(w.get_display().c_ptr() as *mut _),
LinuxWindow::Wayland(ref w) => Some(w.get_display()),
_ => None
}
}
#[inline]
fn is_ready(&self) -> bool {
true
}
}
/// Additional methods on `WindowBuilder` that are specific to Unix.
pub trait WindowBuilderExt {
fn with_x11_visual<T>(self, visual_infos: *const T) -> WindowBuilder;
fn with_x11_screen(self, screen_id: i32) -> WindowBuilder;
/// Build window with `WM_CLASS` hint; defaults to the name of the binary. Only relevant on X11.
fn with_class(self, class: String, instance: String) -> WindowBuilder;
/// Build window with override-redirect flag; defaults to false. Only relevant on X11.
fn with_override_redirect(self, override_redirect: bool) -> WindowBuilder;
/// Build window with `_NET_WM_WINDOW_TYPE` hint; defaults to `Normal`. Only relevant on X11.
fn with_x11_window_type(self, x11_window_type: XWindowType) -> WindowBuilder;
/// Build window with resize increment hint. Only implemented on X11.
fn with_resize_increments(self, increments: LogicalSize) -> WindowBuilder;
/// Build window with base size hint. Only implemented on X11.
fn with_base_size(self, base_size: LogicalSize) -> WindowBuilder;
}
impl WindowBuilderExt for WindowBuilder {
@@ -239,47 +171,4 @@ impl WindowBuilderExt for WindowBuilder {
self.platform_specific.screen_id = Some(screen_id);
self
}
#[inline]
fn with_class(mut self, instance: String, class: String) -> WindowBuilder {
self.platform_specific.class = Some((instance, class));
self
}
#[inline]
fn with_override_redirect(mut self, override_redirect: bool) -> WindowBuilder {
self.platform_specific.override_redirect = override_redirect;
self
}
#[inline]
fn with_x11_window_type(mut self, x11_window_type: XWindowType) -> WindowBuilder {
self.platform_specific.x11_window_type = x11_window_type;
self
}
#[inline]
fn with_resize_increments(mut self, increments: LogicalSize) -> WindowBuilder {
self.platform_specific.resize_increments = Some(increments.into());
self
}
#[inline]
fn with_base_size(mut self, base_size: LogicalSize) -> WindowBuilder {
self.platform_specific.base_size = Some(base_size.into());
self
}
}
/// Additional methods on `MonitorId` that are specific to Linux.
pub trait MonitorIdExt {
/// Returns the inner identifier of the monitor.
fn native_id(&self) -> u32;
}
impl MonitorIdExt for MonitorId {
#[inline]
fn native_id(&self) -> u32 {
self.inner.get_native_identifier()
}
}

102
src/os/windows.rs
View File

@@ -1,117 +1,37 @@
#![cfg(target_os = "windows")]
use std::os::raw::c_void;
use libc;
use winapi::shared::windef::HWND;
use {DeviceId, EventsLoop, Icon, MonitorId, Window, WindowBuilder};
use platform::EventsLoop as WindowsEventsLoop;
/// Additional methods on `EventsLoop` that are specific to Windows.
pub trait EventsLoopExt {
/// By default, winit on Windows will attempt to enable process-wide DPI awareness. If that's
/// undesirable, you can create an `EventsLoop` using this function instead.
fn new_dpi_unaware() -> Self where Self: Sized;
}
impl EventsLoopExt for EventsLoop {
#[inline]
fn new_dpi_unaware() -> Self {
EventsLoop {
events_loop: WindowsEventsLoop::with_dpi_awareness(false),
_marker: ::std::marker::PhantomData,
}
}
}
use Window;
use WindowBuilder;
use winapi;
/// Additional methods on `Window` that are specific to Windows.
pub trait WindowExt {
/// Returns the native handle that is used by this window.
/// Returns a pointer to the `Window` object of xlib that is used by this window.
///
/// The pointer will become invalid when the native window was destroyed.
/// Returns `None` if the window doesn't use xlib (if it uses wayland for example).
///
/// The pointer will become invalid when the glutin `Window` is destroyed.
fn get_hwnd(&self) -> *mut libc::c_void;
/// This sets `ICON_BIG`. A good ceiling here is 256x256.
fn set_taskbar_icon(&self, taskbar_icon: Option<Icon>);
}
impl WindowExt for Window {
#[inline]
fn get_hwnd(&self) -> *mut libc::c_void {
self.window.hwnd() as *mut _
}
#[inline]
fn set_taskbar_icon(&self, taskbar_icon: Option<Icon>) {
self.window.set_taskbar_icon(taskbar_icon)
self.window.platform_window()
}
}
/// Additional methods on `WindowBuilder` that are specific to Windows.
pub trait WindowBuilderExt {
/// Sets a parent to the window to be created.
fn with_parent_window(self, parent: HWND) -> WindowBuilder;
/// This sets `ICON_BIG`. A good ceiling here is 256x256.
fn with_taskbar_icon(self, taskbar_icon: Option<Icon>) -> WindowBuilder;
/// This sets `WS_EX_NOREDIRECTIONBITMAP`.
fn with_no_redirection_bitmap(self, flag: bool) -> WindowBuilder;
fn with_parent_window(self, parent: winapi::HWND) -> WindowBuilder;
}
impl WindowBuilderExt for WindowBuilder {
/// Sets a parent to the window to be created
#[inline]
fn with_parent_window(mut self, parent: HWND) -> WindowBuilder {
fn with_parent_window(mut self, parent: winapi::HWND) -> WindowBuilder {
self.platform_specific.parent = Some(parent);
self
}
#[inline]
fn with_taskbar_icon(mut self, taskbar_icon: Option<Icon>) -> WindowBuilder {
self.platform_specific.taskbar_icon = taskbar_icon;
self
}
#[inline]
fn with_no_redirection_bitmap(mut self, flag: bool) -> WindowBuilder {
self.platform_specific.no_redirection_bitmap = flag;
self
}
}
/// Additional methods on `MonitorId` that are specific to Windows.
pub trait MonitorIdExt {
/// Returns the name of the monitor adapter specific to the Win32 API.
fn native_id(&self) -> String;
/// Returns the handle of the monitor - `HMONITOR`.
fn hmonitor(&self) -> *mut c_void;
}
impl MonitorIdExt for MonitorId {
#[inline]
fn native_id(&self) -> String {
self.inner.get_native_identifier()
}
#[inline]
fn hmonitor(&self) -> *mut c_void {
self.inner.get_hmonitor() as *mut _
}
}
/// Additional methods on `DeviceId` that are specific to Windows.
pub trait DeviceIdExt {
/// Returns an identifier that persistently refers to this specific device.
///
/// Will return `None` if the device is no longer available.
fn get_persistent_identifier(&self) -> Option<String>;
}
impl DeviceIdExt for DeviceId {
#[inline]
fn get_persistent_identifier(&self) -> Option<String> {
self.0.get_persistent_identifier()
}
}

461
src/platform/android/mod.rs
View File

@@ -2,203 +2,43 @@
extern crate android_glue;
mod ffi;
use std::cell::RefCell;
use std::collections::VecDeque;
use std::fmt;
use std::os::raw::c_void;
use libc;
use std::ffi::{CString};
use std::sync::mpsc::{Receiver, channel};
use {
CreationError,
Event,
LogicalPosition,
LogicalSize,
MouseCursor,
PhysicalPosition,
PhysicalSize,
WindowAttributes,
WindowEvent,
WindowId as RootWindowId,
};
use std::os::raw::c_void;
use {CreationError, WindowEvent as Event, MouseCursor};
use CreationError::OsError;
use events::ElementState::{Pressed, Released};
use events::{Touch, TouchPhase};
use window::MonitorId as RootMonitorId;
pub struct EventsLoop {
event_rx: Receiver<android_glue::Event>,
suspend_callback: RefCell<Option<Box<Fn(bool) -> ()>>>,
}
use std::collections::VecDeque;
#[derive(Clone)]
pub struct EventsLoopProxy;
use CursorState;
use WindowAttributes;
use native_monitor::NativeMonitorId;
impl EventsLoop {
pub fn new() -> EventsLoop {
let (tx, rx) = channel();
android_glue::add_sender(tx);
EventsLoop {
event_rx: rx,
suspend_callback: Default::default(),
}
}
#[inline]
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
let mut rb = VecDeque::with_capacity(1);
rb.push_back(MonitorId);
rb
}
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
MonitorId
}
pub fn poll_events<F>(&mut self, mut callback: F)
where F: FnMut(::Event)
{
while let Ok(event) = self.event_rx.try_recv() {
let e = match event{
android_glue::Event::EventMotion(motion) => {
let dpi_factor = MonitorId.get_hidpi_factor();
let location = LogicalPosition::from_physical(
(motion.x as f64, motion.y as f64),
dpi_factor,
);
Some(Event::WindowEvent {
window_id: RootWindowId(WindowId),
event: WindowEvent::Touch(Touch {
phase: match motion.action {
android_glue::MotionAction::Down => TouchPhase::Started,
android_glue::MotionAction::Move => TouchPhase::Moved,
android_glue::MotionAction::Up => TouchPhase::Ended,
android_glue::MotionAction::Cancel => TouchPhase::Cancelled,
},
location,
id: motion.pointer_id as u64,
device_id: DEVICE_ID,
}),
})
},
android_glue::Event::InitWindow => {
// The activity went to foreground.
if let Some(cb) = self.suspend_callback.borrow().as_ref() {
(*cb)(false);
}
Some(Event::Suspended(false))
},
android_glue::Event::TermWindow => {
// The activity went to background.
if let Some(cb) = self.suspend_callback.borrow().as_ref() {
(*cb)(true);
}
Some(Event::Suspended(true))
},
android_glue::Event::WindowResized |
android_glue::Event::ConfigChanged => {
// Activity Orientation changed or resized.
let native_window = unsafe { android_glue::get_native_window() };
if native_window.is_null() {
None
} else {
let dpi_factor = MonitorId.get_hidpi_factor();
let physical_size = MonitorId.get_dimensions();
let size = LogicalSize::from_physical(physical_size, dpi_factor);
Some(Event::WindowEvent {
window_id: RootWindowId(WindowId),
event: WindowEvent::Resized(size),
})
}
},
android_glue::Event::WindowRedrawNeeded => {
// The activity needs to be redrawn.
Some(Event::WindowEvent {
window_id: RootWindowId(WindowId),
event: WindowEvent::Refresh,
})
}
android_glue::Event::Wake => {
Some(Event::Awakened)
}
_ => {
None
}
};
if let Some(event) = e {
callback(event);
}
};
}
pub fn set_suspend_callback(&self, cb: Option<Box<Fn(bool) -> ()>>) {
*self.suspend_callback.borrow_mut() = cb;
}
pub fn run_forever<F>(&mut self, mut callback: F)
where F: FnMut(::Event) -> ::ControlFlow,
{
// Yeah that's a very bad implementation.
loop {
let mut control_flow = ::ControlFlow::Continue;
self.poll_events(|e| {
if let ::ControlFlow::Break = callback(e) {
control_flow = ::ControlFlow::Break;
}
});
if let ::ControlFlow::Break = control_flow {
break;
}
::std::thread::sleep(::std::time::Duration::from_millis(5));
}
}
pub fn create_proxy(&self) -> EventsLoopProxy {
EventsLoopProxy
}
}
impl EventsLoopProxy {
pub fn wakeup(&self) -> Result<(), ::EventsLoopClosed> {
android_glue::wake_event_loop();
Ok(())
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WindowId;
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct DeviceId;
gen_api_transition!();
pub struct Window {
native_window: *const c_void,
event_rx: Receiver<android_glue::Event>,
}
#[derive(Clone)]
pub struct MonitorId;
impl fmt::Debug for MonitorId {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
#[derive(Debug)]
struct MonitorId {
name: Option<String>,
dimensions: PhysicalSize,
position: PhysicalPosition,
hidpi_factor: f64,
}
mod ffi;
let monitor_id_proxy = MonitorId {
name: self.get_name(),
dimensions: self.get_dimensions(),
position: self.get_position(),
hidpi_factor: self.get_hidpi_factor(),
};
#[inline]
pub fn get_available_monitors() -> VecDeque<MonitorId> {
let mut rb = VecDeque::new();
rb.push_back(MonitorId);
rb
}
monitor_id_proxy.fmt(f)
}
#[inline]
pub fn get_primary_monitor() -> MonitorId {
MonitorId
}
impl MonitorId {
@@ -208,25 +48,13 @@ impl MonitorId {
}
#[inline]
pub fn get_dimensions(&self) -> PhysicalSize {
unsafe {
let window = android_glue::get_native_window();
(
ffi::ANativeWindow_getWidth(window) as f64,
ffi::ANativeWindow_getHeight(window) as f64,
).into()
}
pub fn get_native_identifier(&self) -> NativeMonitorId {
NativeMonitorId::Unavailable
}
#[inline]
pub fn get_position(&self) -> PhysicalPosition {
// Android assumes single screen
(0, 0).into()
}
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
1.0
pub fn get_dimensions(&self) -> (u32, u32) {
unimplemented!()
}
}
@@ -235,20 +63,94 @@ pub struct PlatformSpecificWindowBuilderAttributes;
#[derive(Clone, Default)]
pub struct PlatformSpecificHeadlessBuilderAttributes;
pub struct PollEventsIterator<'a> {
window: &'a Window,
}
impl<'a> Iterator for PollEventsIterator<'a> {
type Item = Event;
fn next(&mut self) -> Option<Event> {
match self.window.event_rx.try_recv() {
Ok(android_glue::Event::EventMotion(motion)) => {
Some(Event::Touch(Touch {
phase: match motion.action {
android_glue::MotionAction::Down => TouchPhase::Started,
android_glue::MotionAction::Move => TouchPhase::Moved,
android_glue::MotionAction::Up => TouchPhase::Ended,
android_glue::MotionAction::Cancel => TouchPhase::Cancelled,
},
location: (motion.x as f64, motion.y as f64),
id: motion.pointer_id as u64,
}))
},
Ok(android_glue::Event::InitWindow) => {
// The activity went to foreground.
Some(Event::Suspended(false))
},
Ok(android_glue::Event::TermWindow) => {
// The activity went to background.
Some(Event::Suspended(true))
},
Ok(android_glue::Event::WindowResized) |
Ok(android_glue::Event::ConfigChanged) => {
// Activity Orientation changed or resized.
self.window.get_inner_size().map(|s| Event::Resized(s.0, s.1))
},
Ok(android_glue::Event::WindowRedrawNeeded) => {
// The activity needs to be redrawn.
Some(Event::Refresh)
}
_ => {
None
}
}
}
}
pub struct WaitEventsIterator<'a> {
window: &'a Window,
}
impl<'a> Iterator for WaitEventsIterator<'a> {
type Item = Event;
#[inline]
fn next(&mut self) -> Option<Event> {
loop {
// calling poll_events()
if let Some(ev) = self.window.poll_events().next() {
return Some(ev);
}
// TODO: Implement a proper way of sleeping on the event queue
// timer::sleep(Duration::milliseconds(16));
}
}
}
impl Window {
pub fn new(_: &EventsLoop, win_attribs: WindowAttributes,
_: PlatformSpecificWindowBuilderAttributes)
pub fn new(win_attribs: &WindowAttributes, _: &PlatformSpecificWindowBuilderAttributes)
-> Result<Window, CreationError>
{
use std::{mem, ptr};
// not implemented
assert!(win_attribs.min_dimensions.is_none());
assert!(win_attribs.max_dimensions.is_none());
let native_window = unsafe { android_glue::get_native_window() };
if native_window.is_null() {
return Err(OsError(format!("Android's native window is null")));
}
let (tx, rx) = channel();
android_glue::add_sender(tx);
android_glue::set_multitouch(win_attribs.multitouch);
Ok(Window {
native_window: native_window as *const _,
event_rx: rx,
})
}
@@ -257,156 +159,117 @@ impl Window {
self.native_window
}
#[inline]
pub fn is_closed(&self) -> bool {
false
}
#[inline]
pub fn set_title(&self, _: &str) {
// N/A
}
#[inline]
pub fn show(&self) {
// N/A
}
#[inline]
pub fn hide(&self) {
// N/A
}
#[inline]
pub fn get_position(&self) -> Option<LogicalPosition> {
// N/A
pub fn get_position(&self) -> Option<(i32, i32)> {
None
}
#[inline]
pub fn get_inner_position(&self) -> Option<LogicalPosition> {
// N/A
None
pub fn set_position(&self, _x: i32, _y: i32) {
}
#[inline]
pub fn set_position(&self, _position: LogicalPosition) {
// N/A
}
pub fn get_inner_size(&self) -> Option<(u32, u32)> {
let native_window = unsafe { android_glue::get_native_window() };
#[inline]
pub fn set_min_dimensions(&self, _dimensions: Option<LogicalSize>) {
// N/A
}
#[inline]
pub fn set_max_dimensions(&self, _dimensions: Option<LogicalSize>) {
// N/A
}
#[inline]
pub fn set_resizable(&self, _resizable: bool) {
// N/A
}
#[inline]
pub fn get_inner_size(&self) -> Option<LogicalSize> {
if self.native_window.is_null() {
if native_window.is_null() {
None
} else {
let dpi_factor = self.get_hidpi_factor();
let physical_size = self.get_current_monitor().get_dimensions();
Some(LogicalSize::from_physical(physical_size, dpi_factor))
Some((
unsafe { ffi::ANativeWindow_getWidth(native_window as *const _) } as u32,
unsafe { ffi::ANativeWindow_getHeight(native_window as *const _) } as u32
))
}
}
#[inline]
pub fn get_outer_size(&self) -> Option<LogicalSize> {
pub fn get_outer_size(&self) -> Option<(u32, u32)> {
self.get_inner_size()
}
#[inline]
pub fn set_inner_size(&self, _size: LogicalSize) {
// N/A
pub fn set_inner_size(&self, _x: u32, _y: u32) {
}
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
self.get_current_monitor().get_hidpi_factor()
pub fn create_window_proxy(&self) -> WindowProxy {
WindowProxy
}
#[inline]
pub fn poll_events(&self) -> PollEventsIterator {
PollEventsIterator {
window: self
}
}
#[inline]
pub fn wait_events(&self) -> WaitEventsIterator {
WaitEventsIterator {
window: self
}
}
#[inline]
pub fn platform_display(&self) -> *mut libc::c_void {
unimplemented!();
}
#[inline]
pub fn platform_window(&self) -> *mut libc::c_void {
unimplemented!()
}
#[inline]
pub fn set_window_resize_callback(&mut self, _: Option<fn(u32, u32)>) {
}
#[inline]
pub fn set_cursor(&self, _: MouseCursor) {
// N/A
}
#[inline]
pub fn grab_cursor(&self, _grab: bool) -> Result<(), String> {
Err("Cursor grabbing is not possible on Android.".to_owned())
pub fn set_cursor_state(&self, state: CursorState) -> Result<(), String> {
Ok(())
}
#[inline]
pub fn hide_cursor(&self, _hide: bool) {
// N/A
pub fn hidpi_factor(&self) -> f32 {
1.0
}
#[inline]
pub fn set_cursor_position(&self, _position: LogicalPosition) -> Result<(), String> {
Err("Setting cursor position is not possible on Android.".to_owned())
}
#[inline]
pub fn set_maximized(&self, _maximized: bool) {
// N/A
// Android has single screen maximized apps so nothing to do
}
#[inline]
pub fn set_fullscreen(&self, _monitor: Option<RootMonitorId>) {
// N/A
// Android has single screen maximized apps so nothing to do
}
#[inline]
pub fn set_decorations(&self, _decorations: bool) {
// N/A
}
#[inline]
pub fn set_always_on_top(&self, _always_on_top: bool) {
// N/A
}
#[inline]
pub fn set_window_icon(&self, _icon: Option<::Icon>) {
// N/A
}
#[inline]
pub fn set_ime_spot(&self, _spot: LogicalPosition) {
// N/A
}
#[inline]
pub fn get_current_monitor(&self) -> RootMonitorId {
RootMonitorId { inner: MonitorId }
}
#[inline]
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
let mut rb = VecDeque::with_capacity(1);
rb.push_back(MonitorId);
rb
}
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
MonitorId
}
#[inline]
pub fn id(&self) -> WindowId {
WindowId
pub fn set_cursor_position(&self, x: i32, y: i32) -> Result<(), ()> {
unimplemented!();
}
}
unsafe impl Send for Window {}
unsafe impl Sync for Window {}
// Constant device ID, to be removed when this backend is updated to report real device IDs.
const DEVICE_ID: ::DeviceId = ::DeviceId(DeviceId);
#[derive(Clone)]
pub struct WindowProxy;
impl WindowProxy {
#[inline]
pub fn wakeup_event_loop(&self) {
android_glue::wake_event_loop();
}
}

314
src/platform/emscripten/ffi.rs
View File

@@ -1,314 +0,0 @@
#![allow(dead_code, non_camel_case_types, non_snake_case)]
use std::os::raw::{c_int, c_char, c_void, c_ulong, c_double, c_long, c_ushort};
#[cfg(test)]
use std::mem;
pub type EM_BOOL = c_int;
pub type EM_UTF8 = c_char;
pub type EMSCRIPTEN_RESULT = c_int;
pub const EM_TRUE: EM_BOOL = 1;
pub const EM_FALSE: EM_BOOL = 0;
// values for EMSCRIPTEN_RESULT
pub const EMSCRIPTEN_RESULT_SUCCESS: c_int = 0;
pub const EMSCRIPTEN_RESULT_DEFERRED: c_int = 1;
pub const EMSCRIPTEN_RESULT_NOT_SUPPORTED: c_int = -1;
pub const EMSCRIPTEN_RESULT_FAILED_NOT_DEFERRED: c_int = -2;
pub const EMSCRIPTEN_RESULT_INVALID_TARGET: c_int = -3;
pub const EMSCRIPTEN_RESULT_UNKNOWN_TARGET: c_int = -4;
pub const EMSCRIPTEN_RESULT_INVALID_PARAM: c_int = -5;
pub const EMSCRIPTEN_RESULT_FAILED: c_int = -6;
pub const EMSCRIPTEN_RESULT_NO_DATA: c_int = -7;
// values for EMSCRIPTEN EVENT
pub const EMSCRIPTEN_EVENT_KEYPRESS: c_int = 1;
pub const EMSCRIPTEN_EVENT_KEYDOWN: c_int = 2;
pub const EMSCRIPTEN_EVENT_KEYUP: c_int = 3;
pub const EMSCRIPTEN_EVENT_CLICK: c_int = 4;
pub const EMSCRIPTEN_EVENT_MOUSEDOWN: c_int = 5;
pub const EMSCRIPTEN_EVENT_MOUSEUP: c_int = 6;
pub const EMSCRIPTEN_EVENT_DBLCLICK: c_int = 7;
pub const EMSCRIPTEN_EVENT_MOUSEMOVE: c_int = 8;
pub const EMSCRIPTEN_EVENT_WHEEL: c_int = 9;
pub const EMSCRIPTEN_EVENT_RESIZE: c_int = 10;
pub const EMSCRIPTEN_EVENT_SCROLL: c_int = 11;
pub const EMSCRIPTEN_EVENT_BLUR: c_int = 12;
pub const EMSCRIPTEN_EVENT_FOCUS: c_int = 13;
pub const EMSCRIPTEN_EVENT_FOCUSIN: c_int = 14;
pub const EMSCRIPTEN_EVENT_FOCUSOUT: c_int = 15;
pub const EMSCRIPTEN_EVENT_DEVICEORIENTATION: c_int = 16;
pub const EMSCRIPTEN_EVENT_DEVICEMOTION: c_int = 17;
pub const EMSCRIPTEN_EVENT_ORIENTATIONCHANGE: c_int = 18;
pub const EMSCRIPTEN_EVENT_FULLSCREENCHANGE: c_int = 19;
pub const EMSCRIPTEN_EVENT_POINTERLOCKCHANGE: c_int = 20;
pub const EMSCRIPTEN_EVENT_VISIBILITYCHANGE: c_int = 21;
pub const EMSCRIPTEN_EVENT_TOUCHSTART: c_int = 22;
pub const EMSCRIPTEN_EVENT_TOUCHEND: c_int = 23;
pub const EMSCRIPTEN_EVENT_TOUCHMOVE: c_int = 24;
pub const EMSCRIPTEN_EVENT_TOUCHCANCEL: c_int = 25;
pub const EMSCRIPTEN_EVENT_GAMEPADCONNECTED: c_int = 26;
pub const EMSCRIPTEN_EVENT_GAMEPADDISCONNECTED: c_int = 27;
pub const EMSCRIPTEN_EVENT_BEFOREUNLOAD: c_int = 28;
pub const EMSCRIPTEN_EVENT_BATTERYCHARGINGCHANGE: c_int = 29;
pub const EMSCRIPTEN_EVENT_BATTERYLEVELCHANGE: c_int = 30;
pub const EMSCRIPTEN_EVENT_WEBGLCONTEXTLOST: c_int = 31;
pub const EMSCRIPTEN_EVENT_WEBGLCONTEXTRESTORED: c_int = 32;
pub const EMSCRIPTEN_EVENT_MOUSEENTER: c_int = 33;
pub const EMSCRIPTEN_EVENT_MOUSELEAVE: c_int = 34;
pub const EMSCRIPTEN_EVENT_MOUSEOVER: c_int = 35;
pub const EMSCRIPTEN_EVENT_MOUSEOUT: c_int = 36;
pub const EMSCRIPTEN_EVENT_CANVASRESIZED: c_int = 37;
pub const EMSCRIPTEN_EVENT_POINTERLOCKERROR: c_int = 38;
pub const EM_HTML5_SHORT_STRING_LEN_BYTES: usize = 32;
pub const DOM_KEY_LOCATION_STANDARD: c_ulong = 0x00;
pub const DOM_KEY_LOCATION_LEFT: c_ulong = 0x01;
pub const DOM_KEY_LOCATION_RIGHT: c_ulong = 0x02;
pub const DOM_KEY_LOCATION_NUMPAD: c_ulong = 0x03;
pub type em_callback_func = Option<unsafe extern "C" fn()>;
pub type em_key_callback_func = Option<unsafe extern "C" fn(
eventType: c_int,
keyEvent: *const EmscriptenKeyboardEvent,
userData: *mut c_void) -> EM_BOOL>;
pub type em_mouse_callback_func = Option<unsafe extern "C" fn(
eventType: c_int,
mouseEvent: *const EmscriptenMouseEvent,
userData: *mut c_void) -> EM_BOOL>;
pub type em_pointerlockchange_callback_func = Option<unsafe extern "C" fn(
eventType: c_int,
pointerlockChangeEvent: *const EmscriptenPointerlockChangeEvent,
userData: *mut c_void) -> EM_BOOL>;
pub type em_fullscreenchange_callback_func = Option<unsafe extern "C" fn(
eventType: c_int,
fullscreenChangeEvent: *const EmscriptenFullscreenChangeEvent,
userData: *mut c_void) -> EM_BOOL>;
pub type em_touch_callback_func = Option<unsafe extern "C" fn(
eventType: c_int,
touchEvent: *const EmscriptenTouchEvent,
userData: *mut c_void) -> EM_BOOL>;
#[repr(C)]
pub struct EmscriptenFullscreenChangeEvent {
pub isFullscreen: c_int,
pub fullscreenEnabled: c_int,
pub nodeName: [c_char; 128usize],
pub id: [c_char; 128usize],
pub elementWidth: c_int,
pub elementHeight: c_int,
pub screenWidth: c_int,
pub screenHeight: c_int,
}
#[test]
fn bindgen_test_layout_EmscriptenFullscreenChangeEvent() {
assert_eq!(mem::size_of::<EmscriptenFullscreenChangeEvent>(), 280usize);
assert_eq!(mem::align_of::<EmscriptenFullscreenChangeEvent>(), 4usize);
}
#[repr(C)]
#[derive(Debug, Copy)]
pub struct EmscriptenKeyboardEvent {
pub key: [c_char; 32usize],
pub code: [c_char; 32usize],
pub location: c_ulong,
pub ctrlKey: c_int,
pub shiftKey: c_int,
pub altKey: c_int,
pub metaKey: c_int,
pub repeat: c_int,
pub locale: [c_char; 32usize],
pub charValue: [c_char; 32usize],
pub charCode: c_ulong,
pub keyCode: c_ulong,
pub which: c_ulong,
}
#[test]
fn bindgen_test_layout_EmscriptenKeyboardEvent() {
assert_eq!(mem::size_of::<EmscriptenKeyboardEvent>(), 184usize);
assert_eq!(mem::align_of::<EmscriptenKeyboardEvent>(), 8usize);
}
impl Clone for EmscriptenKeyboardEvent {
fn clone(&self) -> Self { *self }
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct EmscriptenMouseEvent {
pub timestamp: f64,
pub screenX: c_long,
pub screenY: c_long,
pub clientX: c_long,
pub clientY: c_long,
pub ctrlKey: c_int,
pub shiftKey: c_int,
pub altKey: c_int,
pub metaKey: c_int,
pub button: c_ushort,
pub buttons: c_ushort,
pub movementX: c_long,
pub movementY: c_long,
pub targetX: c_long,
pub targetY: c_long,
pub canvasX: c_long,
pub canvasY: c_long,
pub padding: c_long,
}
#[test]
fn bindgen_test_layout_EmscriptenMouseEvent() {
assert_eq!(mem::size_of::<EmscriptenMouseEvent>(), 120usize);
assert_eq!(mem::align_of::<EmscriptenMouseEvent>(), 8usize);
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct EmscriptenTouchPoint {
pub identifier: c_long,
pub screenX: c_long,
pub screenY: c_long,
pub clientX: c_long,
pub clientY: c_long,
pub pageX: c_long,
pub pageY: c_long,
pub isChanged: c_int,
pub onTarget: c_int,
pub targetX: c_long,
pub targetY: c_long,
pub canvasX: c_long,
pub canvasY: c_long,
}
#[test]
fn bindgen_test_layout_EmscriptenTouchPoint() {
assert_eq!(mem::size_of::<EmscriptenTouchPoint>(), 96usize);
assert_eq!(mem::align_of::<EmscriptenTouchPoint>(), 8usize);
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct EmscriptenTouchEvent {
pub numTouches: c_int,
pub ctrlKey: c_int,
pub shiftKey: c_int,
pub altKey: c_int,
pub metaKey: c_int,
pub touches: [EmscriptenTouchPoint; 32usize],
}
#[test]
fn bindgen_test_layout_EmscriptenTouchEvent() {
assert_eq!(mem::size_of::<EmscriptenTouchEvent>(), 3096usize);
assert_eq!(mem::align_of::<EmscriptenTouchEvent>(), 8usize);
}
#[repr(C)]
pub struct EmscriptenPointerlockChangeEvent {
pub isActive: c_int,
pub nodeName: [c_char; 128usize],
pub id: [c_char; 128usize],
}
#[test]
fn bindgen_test_layout_EmscriptenPointerlockChangeEvent() {
assert_eq!(mem::size_of::<EmscriptenPointerlockChangeEvent>(), 260usize);
assert_eq!(mem::align_of::<EmscriptenPointerlockChangeEvent>(), 4usize);
}
extern "C" {
pub fn emscripten_set_canvas_size(
width: c_int, height: c_int)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_get_canvas_size(
width: *mut c_int, height: *mut c_int,
is_fullscreen: *mut c_int)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_set_element_css_size(
target: *const c_char, width: c_double,
height: c_double) -> EMSCRIPTEN_RESULT;
pub fn emscripten_get_element_css_size(
target: *const c_char, width: *mut c_double,
height: *mut c_double) -> EMSCRIPTEN_RESULT;
pub fn emscripten_request_pointerlock(
target: *const c_char, deferUntilInEventHandler: EM_BOOL)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_exit_pointerlock() -> EMSCRIPTEN_RESULT;
pub fn emscripten_request_fullscreen(
target: *const c_char, deferUntilInEventHandler: EM_BOOL)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_exit_fullscreen() -> EMSCRIPTEN_RESULT;
pub fn emscripten_set_keydown_callback(
target: *const c_char, userData: *mut c_void,
useCapture: EM_BOOL, callback: em_key_callback_func)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_set_keyup_callback(
target: *const c_char, userData: *mut c_void,
useCapture: EM_BOOL, callback: em_key_callback_func)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_set_mousemove_callback(
target: *const c_char, user_data: *mut c_void,
use_capture: EM_BOOL, callback: em_mouse_callback_func)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_set_mousedown_callback(
target: *const c_char, user_data: *mut c_void,
use_capture: EM_BOOL, callback: em_mouse_callback_func)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_set_mouseup_callback(
target: *const c_char, user_data: *mut c_void,
use_capture: EM_BOOL, callback: em_mouse_callback_func)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_hide_mouse();
pub fn emscripten_get_device_pixel_ratio() -> f64;
pub fn emscripten_set_pointerlockchange_callback(
target: *const c_char, userData: *mut c_void, useCapture: EM_BOOL,
callback: em_pointerlockchange_callback_func) -> EMSCRIPTEN_RESULT;
pub fn emscripten_set_fullscreenchange_callback(
target: *const c_char, userData: *mut c_void, useCapture: EM_BOOL,
callback: em_fullscreenchange_callback_func) -> EMSCRIPTEN_RESULT;
pub fn emscripten_asm_const(code: *const c_char);
pub fn emscripten_set_main_loop(
func: em_callback_func, fps: c_int, simulate_infinite_loop: EM_BOOL);
pub fn emscripten_cancel_main_loop();
pub fn emscripten_set_touchstart_callback(
target: *const c_char, userData: *mut c_void,
useCapture: c_int, callback: em_touch_callback_func)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_set_touchend_callback(
target: *const c_char, userData: *mut c_void,
useCapture: c_int, callback: em_touch_callback_func)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_set_touchmove_callback(
target: *const c_char, userData: *mut c_void,
useCapture: c_int, callback: em_touch_callback_func)
-> EMSCRIPTEN_RESULT;
pub fn emscripten_set_touchcancel_callback(
target: *const c_char, userData: *mut c_void,
useCapture: c_int, callback: em_touch_callback_func)
-> EMSCRIPTEN_RESULT;
}

1119
src/platform/emscripten/mod.rs
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73
src/platform/ios/ffi.rs
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@@ -1,17 +1,20 @@
#![allow(non_camel_case_types, non_snake_case, non_upper_case_globals)]
use std::ffi::CString;
use std::os::raw::*;
use objc::runtime::Object;
use libc;
use objc::runtime::{ Object, Class };
#[allow(non_camel_case_types)]
pub type id = *mut Object;
#[allow(non_camel_case_types)]
#[allow(non_upper_case_globals)]
pub const nil: id = 0 as id;
pub type CFStringRef = *const c_void;
pub type CFStringRef = *const libc::c_void;
pub type CFTimeInterval = f64;
pub type Boolean = u32;
#[allow(non_upper_case_globals)]
pub const kCFRunLoopRunHandledSource: i32 = 4;
#[cfg(target_pointer_width = "32")]
@@ -19,6 +22,11 @@ pub type CGFloat = f32;
#[cfg(target_pointer_width = "64")]
pub type CGFloat = f64;
#[cfg(target_pointer_width = "32")]
pub type NSUInteger = u32;
#[cfg(target_pointer_width = "64")]
pub type NSUInteger = u64;
#[repr(C)]
#[derive(Debug, Clone)]
pub struct CGPoint {
@@ -30,14 +38,14 @@ pub struct CGPoint {
#[derive(Debug, Clone)]
pub struct CGRect {
pub origin: CGPoint,
pub size: CGSize,
pub size: CGSize
}
#[repr(C)]
#[derive(Debug, Clone)]
pub struct CGSize {
pub width: CGFloat,
pub height: CGFloat,
pub height: CGFloat
}
#[link(name = "UIKit", kind = "framework")]
@@ -47,51 +55,33 @@ extern {
pub static kCFRunLoopDefaultMode: CFStringRef;
// int UIApplicationMain ( int argc, char *argv[], NSString *principalClassName, NSString *delegateClassName );
pub fn UIApplicationMain(
argc: c_int,
argv: *const c_char,
principalClassName: id,
delegateClassName: id,
) -> c_int;
pub fn UIApplicationMain(argc: libc::c_int, argv: *const libc::c_char, principalClassName: id, delegateClassName: id) -> libc::c_int;
// SInt32 CFRunLoopRunInMode ( CFStringRef mode, CFTimeInterval seconds, Boolean returnAfterSourceHandled );
pub fn CFRunLoopRunInMode(
mode: CFStringRef,
seconds: CFTimeInterval,
returnAfterSourceHandled: Boolean,
) -> i32;
pub fn CFRunLoopRunInMode(mode: CFStringRef, seconds: CFTimeInterval, returnAfterSourceHandled: Boolean) -> i32;
}
extern {
pub fn setjmp(env: *mut c_void) -> c_int;
pub fn longjmp(env: *mut c_void, val: c_int) -> !;
pub fn setjmp(env: *mut libc::c_void) -> libc::c_int;
pub fn longjmp(env: *mut libc::c_void, val: libc::c_int);
}
// values taken from "setjmp.h" header in xcode iPhoneOS/iPhoneSimulator SDK
#[cfg(any(target_arch = "x86_64"))]
pub const JBLEN: usize = (9 * 2) + 3 + 16;
#[cfg(any(target_arch = "x86"))]
pub const JBLEN: usize = 18;
#[cfg(target_arch = "arm")]
pub const JBLEN: usize = 10 + 16 + 2;
#[cfg(target_arch = "aarch64")]
pub const JBLEN: usize = (14 + 8 + 2) * 2;
pub type JmpBuf = [c_int; JBLEN];
pub trait NSString: Sized {
pub trait NSString {
unsafe fn alloc(_: Self) -> id {
msg_send![class!(NSString), alloc]
msg_send![class("NSString"), alloc]
}
unsafe fn initWithUTF8String_(self, c_string: *const c_char) -> id;
#[allow(non_snake_case)]
unsafe fn initWithUTF8String_(self, c_string: *const i8) -> id;
#[allow(non_snake_case)]
unsafe fn stringByAppendingString_(self, other: id) -> id;
unsafe fn init_str(self, string: &str) -> Self;
unsafe fn UTF8String(self) -> *const c_char;
#[allow(non_snake_case)]
unsafe fn UTF8String(self) -> *const libc::c_char;
}
impl NSString for id {
unsafe fn initWithUTF8String_(self, c_string: *const c_char) -> id {
unsafe fn initWithUTF8String_(self, c_string: *const i8) -> id {
msg_send![self, initWithUTF8String:c_string as id]
}
@@ -104,7 +94,14 @@ impl NSString for id {
self.initWithUTF8String_(cstring.as_ptr())
}
unsafe fn UTF8String(self) -> *const c_char {
unsafe fn UTF8String(self) -> *const libc::c_char {
msg_send![self, UTF8String]
}
}
#[inline]
pub fn class(name: &str) -> *mut Class {
unsafe {
::std::mem::transmute(Class::get(name))
}
}

901
src/platform/ios/mod.rs
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2
src/platform/linux/dlopen.rs
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@@ -1,4 +1,4 @@
#![cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "netbsd", target_os = "openbsd"))]
#![cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd"))]
#![allow(dead_code)]
use std::os::raw::{c_void, c_char, c_int};

512
src/platform/linux/mod.rs
View File

@@ -1,79 +1,95 @@
#![cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "netbsd", target_os = "openbsd"))]
#![cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd"))]
use std::collections::VecDeque;
use std::{env, mem};
use std::ffi::CStr;
use std::os::raw::*;
use std::sync::Arc;
use parking_lot::Mutex;
use sctk::reexports::client::ConnectError;
use CreationError;
use CursorState;
use MouseCursor;
use libc;
use {
CreationError,
EventsLoopClosed,
Icon,
MouseCursor,
ControlFlow,
WindowAttributes,
};
use dpi::{LogicalPosition, LogicalSize, PhysicalPosition, PhysicalSize};
use window::MonitorId as RootMonitorId;
use self::x11::{XConnection, XError};
use self::x11::XConnection;
use self::x11::XError;
use self::x11::XNotSupported;
use self::x11::ffi::XVisualInfo;
pub use self::x11::XNotSupported;
mod dlopen;
pub mod wayland;
pub mod x11;
/// Environment variable specifying which backend should be used on unix platform.
///
/// Legal values are x11 and wayland. If this variable is set only the named backend
/// will be tried by winit. If it is not set, winit will try to connect to a wayland connection,
/// and if it fails will fallback on x11.
///
/// If this variable is set with any other value, winit will panic.
const BACKEND_PREFERENCE_ENV_VAR: &str = "WINIT_UNIX_BACKEND";
#[derive(Clone, Default)]
pub struct PlatformSpecificWindowBuilderAttributes {
pub visual_infos: Option<XVisualInfo>,
pub screen_id: Option<i32>,
pub resize_increments: Option<(u32, u32)>,
pub base_size: Option<(u32, u32)>,
pub class: Option<(String, String)>,
pub override_redirect: bool,
pub x11_window_type: x11::util::WindowType,
}
pub enum UnixBackend {
X(Arc<XConnection>),
Wayland(Arc<wayland::WaylandContext>),
Error(XNotSupported),
}
lazy_static!(
pub static ref X11_BACKEND: Mutex<Result<Arc<XConnection>, XNotSupported>> = {
Mutex::new(XConnection::new(Some(x_error_callback)).map(Arc::new))
pub static ref UNIX_BACKEND: UnixBackend = {
if let Some(ctxt) = wayland::WaylandContext::init() {
UnixBackend::Wayland(Arc::new(ctxt))
} else {
match XConnection::new(Some(x_error_callback)) {
Ok(x) => UnixBackend::X(Arc::new(x)),
Err(e) => UnixBackend::Error(e),
}
}
};
);
pub enum Window {
X(x11::Window),
Wayland(wayland::Window),
pub enum Window2 {
#[doc(hidden)]
X(x11::Window2),
#[doc(hidden)]
Wayland(wayland::Window)
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum WindowId {
#[doc(hidden)]
X(x11::WindowId),
Wayland(wayland::WindowId),
#[doc(hidden)]
Wayland(wayland::WindowId)
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum DeviceId {
X(x11::DeviceId),
Wayland(wayland::DeviceId),
}
#[derive(Debug, Clone)]
#[derive(Clone)]
pub enum MonitorId {
#[doc(hidden)]
X(x11::MonitorId),
#[doc(hidden)]
Wayland(wayland::MonitorId),
#[doc(hidden)]
None,
}
#[inline]
pub fn get_available_monitors() -> VecDeque<MonitorId> {
match *UNIX_BACKEND {
UnixBackend::Wayland(ref ctxt) => wayland::get_available_monitors(ctxt)
.into_iter()
.map(MonitorId::Wayland)
.collect(),
UnixBackend::X(ref connec) => x11::get_available_monitors(connec)
.into_iter()
.map(MonitorId::X)
.collect(),
UnixBackend::Error(_) => { let mut d = VecDeque::new(); d.push_back(MonitorId::None); d},
}
}
#[inline]
pub fn get_primary_monitor() -> MonitorId {
match *UNIX_BACKEND {
UnixBackend::Wayland(ref ctxt) => MonitorId::Wayland(wayland::get_primary_monitor(ctxt)),
UnixBackend::X(ref connec) => MonitorId::X(x11::get_primary_monitor(connec)),
UnixBackend::Error(_) => MonitorId::None,
}
}
impl MonitorId {
@@ -82,296 +98,188 @@ impl MonitorId {
match self {
&MonitorId::X(ref m) => m.get_name(),
&MonitorId::Wayland(ref m) => m.get_name(),
&MonitorId::None => None,
}
}
#[inline]
pub fn get_native_identifier(&self) -> u32 {
pub fn get_native_identifier(&self) -> ::native_monitor::NativeMonitorId {
match self {
&MonitorId::X(ref m) => m.get_native_identifier(),
&MonitorId::Wayland(ref m) => m.get_native_identifier(),
&MonitorId::None => unimplemented!() // FIXME:
}
}
#[inline]
pub fn get_dimensions(&self) -> PhysicalSize {
pub fn get_dimensions(&self) -> (u32, u32) {
match self {
&MonitorId::X(ref m) => m.get_dimensions(),
&MonitorId::Wayland(ref m) => m.get_dimensions(),
}
}
#[inline]
pub fn get_position(&self) -> PhysicalPosition {
match self {
&MonitorId::X(ref m) => m.get_position(),
&MonitorId::Wayland(ref m) => m.get_position(),
}
}
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
match self {
&MonitorId::X(ref m) => m.get_hidpi_factor(),
&MonitorId::Wayland(ref m) => m.get_hidpi_factor() as f64,
&MonitorId::None => (800, 600), // FIXME:
}
}
}
impl Window {
impl Window2 {
#[inline]
pub fn new(
events_loop: &EventsLoop,
attribs: WindowAttributes,
pl_attribs: PlatformSpecificWindowBuilderAttributes,
) -> Result<Self, CreationError> {
match *events_loop {
EventsLoop::Wayland(ref events_loop) => {
wayland::Window::new(events_loop, attribs).map(Window::Wayland)
pub fn new(events_loop: ::std::sync::Arc<EventsLoop>, window: &::WindowAttributes,
pl_attribs: &PlatformSpecificWindowBuilderAttributes)
-> Result<Window2, CreationError>
{
match *UNIX_BACKEND {
UnixBackend::Wayland(ref ctxt) => {
if let EventsLoop::Wayland(ref evlp) = *events_loop {
wayland::Window::new(evlp, ctxt.clone(), window).map(Window2::Wayland)
} else {
// It is not possible to instanciate an EventsLoop not matching its backend
unreachable!()
}
},
EventsLoop::X(ref events_loop) => {
x11::Window::new(events_loop, attribs, pl_attribs).map(Window::X)
UnixBackend::X(ref connec) => {
x11::Window2::new(events_loop, connec, window, pl_attribs).map(Window2::X)
},
UnixBackend::Error(_) => {
// If the Backend is Error(), it is not possible to instanciate an EventsLoop at all,
// thus this function cannot be called!
unreachable!()
}
}
}
#[inline]
pub fn id(&self) -> WindowId {
match self {
&Window::X(ref w) => WindowId::X(w.id()),
&Window::Wayland(ref w) => WindowId::Wayland(w.id()),
&Window2::X(ref w) => WindowId::X(w.id()),
&Window2::Wayland(ref w) => WindowId::Wayland(w.id())
}
}
#[inline]
pub fn set_title(&self, title: &str) {
match self {
&Window::X(ref w) => w.set_title(title),
&Window::Wayland(ref w) => w.set_title(title),
&Window2::X(ref w) => w.set_title(title),
&Window2::Wayland(ref w) => w.set_title(title)
}
}
#[inline]
pub fn show(&self) {
match self {
&Window::X(ref w) => w.show(),
&Window::Wayland(ref w) => w.show(),
&Window2::X(ref w) => w.show(),
&Window2::Wayland(ref w) => w.show()
}
}
#[inline]
pub fn hide(&self) {
match self {
&Window::X(ref w) => w.hide(),
&Window::Wayland(ref w) => w.hide(),
&Window2::X(ref w) => w.hide(),
&Window2::Wayland(ref w) => w.hide()
}
}
#[inline]
pub fn get_position(&self) -> Option<LogicalPosition> {
pub fn get_position(&self) -> Option<(i32, i32)> {
match self {
&Window::X(ref w) => w.get_position(),
&Window::Wayland(ref w) => w.get_position(),
&Window2::X(ref w) => w.get_position(),
&Window2::Wayland(ref w) => w.get_position()
}
}
#[inline]
pub fn get_inner_position(&self) -> Option<LogicalPosition> {
pub fn set_position(&self, x: i32, y: i32) {
match self {
&Window::X(ref m) => m.get_inner_position(),
&Window::Wayland(ref m) => m.get_inner_position(),
&Window2::X(ref w) => w.set_position(x, y),
&Window2::Wayland(ref w) => w.set_position(x, y)
}
}
#[inline]
pub fn set_position(&self, position: LogicalPosition) {
pub fn get_inner_size(&self) -> Option<(u32, u32)> {
match self {
&Window::X(ref w) => w.set_position(position),
&Window::Wayland(ref w) => w.set_position(position),
&Window2::X(ref w) => w.get_inner_size(),
&Window2::Wayland(ref w) => w.get_inner_size()
}
}
#[inline]
pub fn get_inner_size(&self) -> Option<LogicalSize> {
pub fn get_outer_size(&self) -> Option<(u32, u32)> {
match self {
&Window::X(ref w) => w.get_inner_size(),
&Window::Wayland(ref w) => w.get_inner_size(),
&Window2::X(ref w) => w.get_outer_size(),
&Window2::Wayland(ref w) => w.get_outer_size()
}
}
#[inline]
pub fn get_outer_size(&self) -> Option<LogicalSize> {
pub fn set_inner_size(&self, x: u32, y: u32) {
match self {
&Window::X(ref w) => w.get_outer_size(),
&Window::Wayland(ref w) => w.get_outer_size(),
}
}
#[inline]
pub fn set_inner_size(&self, size: LogicalSize) {
match self {
&Window::X(ref w) => w.set_inner_size(size),
&Window::Wayland(ref w) => w.set_inner_size(size),
}
}
#[inline]
pub fn set_min_dimensions(&self, dimensions: Option<LogicalSize>) {
match self {
&Window::X(ref w) => w.set_min_dimensions(dimensions),
&Window::Wayland(ref w) => w.set_min_dimensions(dimensions),
}
}
#[inline]
pub fn set_max_dimensions(&self, dimensions: Option<LogicalSize>) {
match self {
&Window::X(ref w) => w.set_max_dimensions(dimensions),
&Window::Wayland(ref w) => w.set_max_dimensions(dimensions),
}
}
#[inline]
pub fn set_resizable(&self, resizable: bool) {
match self {
&Window::X(ref w) => w.set_resizable(resizable),
&Window::Wayland(ref w) => w.set_resizable(resizable),
&Window2::X(ref w) => w.set_inner_size(x, y),
&Window2::Wayland(ref w) => w.set_inner_size(x, y)
}
}
#[inline]
pub fn set_cursor(&self, cursor: MouseCursor) {
match self {
&Window::X(ref w) => w.set_cursor(cursor),
&Window::Wayland(ref w) => w.set_cursor(cursor)
&Window2::X(ref w) => w.set_cursor(cursor),
&Window2::Wayland(ref w) => w.set_cursor(cursor)
}
}
#[inline]
pub fn grab_cursor(&self, grab: bool) -> Result<(), String> {
pub fn set_cursor_state(&self, state: CursorState) -> Result<(), String> {
match self {
&Window::X(ref window) => window.grab_cursor(grab),
&Window::Wayland(ref window) => window.grab_cursor(grab),
&Window2::X(ref w) => w.set_cursor_state(state),
&Window2::Wayland(ref w) => w.set_cursor_state(state)
}
}
#[inline]
pub fn hide_cursor(&self, hide: bool) {
match self {
&Window::X(ref window) => window.hide_cursor(hide),
&Window::Wayland(ref window) => window.hide_cursor(hide),
}
}
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
pub fn hidpi_factor(&self) -> f32 {
match self {
&Window::X(ref w) => w.get_hidpi_factor(),
&Window::Wayland(ref w) => w.hidpi_factor() as f64,
&Window2::X(ref w) => w.hidpi_factor(),
&Window2::Wayland(ref w) => w.hidpi_factor()
}
}
#[inline]
pub fn set_cursor_position(&self, position: LogicalPosition) -> Result<(), String> {
pub fn set_cursor_position(&self, x: i32, y: i32) -> Result<(), ()> {
match self {
&Window::X(ref w) => w.set_cursor_position(position),
&Window::Wayland(ref w) => w.set_cursor_position(position),
&Window2::X(ref w) => w.set_cursor_position(x, y),
&Window2::Wayland(ref w) => w.set_cursor_position(x, y)
}
}
#[inline]
pub fn set_maximized(&self, maximized: bool) {
pub fn platform_display(&self) -> *mut libc::c_void {
use wayland_client::Proxy;
match self {
&Window::X(ref w) => w.set_maximized(maximized),
&Window::Wayland(ref w) => w.set_maximized(maximized),
&Window2::X(ref w) => w.platform_display(),
&Window2::Wayland(ref w) => w.get_display().ptr() as *mut _
}
}
#[inline]
pub fn set_fullscreen(&self, monitor: Option<RootMonitorId>) {
pub fn platform_window(&self) -> *mut libc::c_void {
use wayland_client::Proxy;
match self {
&Window::X(ref w) => w.set_fullscreen(monitor),
&Window::Wayland(ref w) => w.set_fullscreen(monitor)
}
}
#[inline]
pub fn set_decorations(&self, decorations: bool) {
match self {
&Window::X(ref w) => w.set_decorations(decorations),
&Window::Wayland(ref w) => w.set_decorations(decorations)
}
}
#[inline]
pub fn set_always_on_top(&self, always_on_top: bool) {
match self {
&Window::X(ref w) => w.set_always_on_top(always_on_top),
&Window::Wayland(_) => (),
}
}
#[inline]
pub fn set_window_icon(&self, window_icon: Option<Icon>) {
match self {
&Window::X(ref w) => w.set_window_icon(window_icon),
&Window::Wayland(_) => (),
}
}
#[inline]
pub fn set_ime_spot(&self, position: LogicalPosition) {
match self {
&Window::X(ref w) => w.set_ime_spot(position),
&Window::Wayland(_) => (),
}
}
#[inline]
pub fn get_current_monitor(&self) -> RootMonitorId {
match self {
&Window::X(ref window) => RootMonitorId { inner: MonitorId::X(window.get_current_monitor()) },
&Window::Wayland(ref window) => RootMonitorId { inner: MonitorId::Wayland(window.get_current_monitor()) },
}
}
#[inline]
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
match self {
&Window::X(ref window) => window.get_available_monitors()
.into_iter()
.map(MonitorId::X)
.collect(),
&Window::Wayland(ref window) => window.get_available_monitors()
.into_iter()
.map(MonitorId::Wayland)
.collect(),
}
}
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
match self {
&Window::X(ref window) => MonitorId::X(window.get_primary_monitor()),
&Window::Wayland(ref window) => MonitorId::Wayland(window.get_primary_monitor()),
&Window2::X(ref w) => w.platform_window(),
&Window2::Wayland(ref w) => w.get_surface().ptr() as *mut _
}
}
}
unsafe extern "C" fn x_error_callback(
display: *mut x11::ffi::Display,
event: *mut x11::ffi::XErrorEvent,
) -> c_int {
let xconn_lock = X11_BACKEND.lock();
if let Ok(ref xconn) = *xconn_lock {
let mut buf: [c_char; 1024] = mem::uninitialized();
(xconn.xlib.XGetErrorText)(
display,
(*event).error_code as c_int,
buf.as_mut_ptr(),
buf.len() as c_int,
);
let description = CStr::from_ptr(buf.as_ptr()).to_string_lossy();
unsafe extern "C" fn x_error_callback(dpy: *mut x11::ffi::Display, event: *mut x11::ffi::XErrorEvent)
-> libc::c_int
{
use std::ffi::CStr;
if let UnixBackend::X(ref x) = *UNIX_BACKEND {
let mut buff: Vec<u8> = Vec::with_capacity(1024);
(x.xlib.XGetErrorText)(dpy, (*event).error_code as i32, buff.as_mut_ptr() as *mut libc::c_char, buff.capacity() as i32);
let description = CStr::from_ptr(buff.as_mut_ptr() as *const libc::c_char).to_string_lossy();
let error = XError {
description: description.into_owned(),
@@ -380,152 +288,58 @@ unsafe extern "C" fn x_error_callback(
minor_code: (*event).minor_code,
};
eprintln!("[winit X11 error] {:#?}", error);
*xconn.latest_error.lock() = Some(error);
*x.latest_error.lock().unwrap() = Some(error);
}
// Fun fact: this return value is completely ignored.
0
}
pub enum EventsLoop {
#[doc(hidden)]
Wayland(wayland::EventsLoop),
#[doc(hidden)]
X(x11::EventsLoop)
}
#[derive(Clone)]
pub enum EventsLoopProxy {
X(x11::EventsLoopProxy),
Wayland(wayland::EventsLoopProxy),
}
impl EventsLoop {
pub fn new() -> EventsLoop {
if let Ok(env_var) = env::var(BACKEND_PREFERENCE_ENV_VAR) {
match env_var.as_str() {
"x11" => {
// TODO: propagate
return EventsLoop::new_x11().expect("Failed to initialize X11 backend");
},
"wayland" => {
return EventsLoop::new_wayland()
.expect("Failed to initialize Wayland backend");
},
_ => panic!(
"Unknown environment variable value for {}, try one of `x11`,`wayland`",
BACKEND_PREFERENCE_ENV_VAR,
),
match *UNIX_BACKEND {
UnixBackend::Wayland(ref ctxt) => {
EventsLoop::Wayland(wayland::EventsLoop::new(ctxt.clone()))
},
UnixBackend::X(_) => {
EventsLoop::X(x11::EventsLoop::new())
},
UnixBackend::Error(_) => {
panic!("Attempted to create an EventsLoop while no backend was available.")
}
}
let wayland_err = match EventsLoop::new_wayland() {
Ok(event_loop) => return event_loop,
Err(err) => err,
};
let x11_err = match EventsLoop::new_x11() {
Ok(event_loop) => return event_loop,
Err(err) => err,
};
let err_string = format!(
r#"Failed to initialize any backend!
Wayland status: {:#?}
X11 status: {:#?}
"#,
wayland_err,
x11_err,
);
panic!(err_string);
}
pub fn new_wayland() -> Result<EventsLoop, ConnectError> {
wayland::EventsLoop::new()
.map(EventsLoop::Wayland)
}
pub fn new_x11() -> Result<EventsLoop, XNotSupported> {
X11_BACKEND
.lock()
.as_ref()
.map(Arc::clone)
.map(x11::EventsLoop::new)
.map(EventsLoop::X)
.map_err(|err| err.clone())
}
#[inline]
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
pub fn interrupt(&self) {
match *self {
EventsLoop::Wayland(ref evlp) => evlp
.get_available_monitors()
.into_iter()
.map(MonitorId::Wayland)
.collect(),
EventsLoop::X(ref evlp) => evlp
.x_connection()
.get_available_monitors()
.into_iter()
.map(MonitorId::X)
.collect(),
EventsLoop::Wayland(ref evlp) => evlp.interrupt(),
EventsLoop::X(ref evlp) => evlp.interrupt()
}
}
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
match *self {
EventsLoop::Wayland(ref evlp) => MonitorId::Wayland(evlp.get_primary_monitor()),
EventsLoop::X(ref evlp) => MonitorId::X(evlp.x_connection().get_primary_monitor()),
}
}
pub fn create_proxy(&self) -> EventsLoopProxy {
match *self {
EventsLoop::Wayland(ref evlp) => EventsLoopProxy::Wayland(evlp.create_proxy()),
EventsLoop::X(ref evlp) => EventsLoopProxy::X(evlp.create_proxy()),
}
}
pub fn poll_events<F>(&mut self, callback: F)
pub fn poll_events<F>(&self, callback: F)
where F: FnMut(::Event)
{
match *self {
EventsLoop::Wayland(ref mut evlp) => evlp.poll_events(callback),
EventsLoop::X(ref mut evlp) => evlp.poll_events(callback)
EventsLoop::Wayland(ref evlp) => evlp.poll_events(callback),
EventsLoop::X(ref evlp) => evlp.poll_events(callback)
}
}
pub fn run_forever<F>(&mut self, callback: F)
where F: FnMut(::Event) -> ControlFlow
pub fn run_forever<F>(&self, callback: F)
where F: FnMut(::Event)
{
match *self {
EventsLoop::Wayland(ref mut evlp) => evlp.run_forever(callback),
EventsLoop::X(ref mut evlp) => evlp.run_forever(callback)
}
}
#[inline]
pub fn is_wayland(&self) -> bool {
match *self {
EventsLoop::Wayland(_) => true,
EventsLoop::X(_) => false,
}
}
#[inline]
pub fn x_connection(&self) -> Option<&Arc<XConnection>> {
match *self {
EventsLoop::Wayland(_) => None,
EventsLoop::X(ref ev) => Some(ev.x_connection()),
}
}
}
impl EventsLoopProxy {
pub fn wakeup(&self) -> Result<(), EventsLoopClosed> {
match *self {
EventsLoopProxy::Wayland(ref proxy) => proxy.wakeup(),
EventsLoopProxy::X(ref proxy) => proxy.wakeup(),
EventsLoop::Wayland(ref evlp) => evlp.run_forever(callback),
EventsLoop::X(ref evlp) => evlp.run_forever(callback)
}
}
}

297
src/platform/linux/wayland/context.rs Normal file
View File

@@ -0,0 +1,297 @@
use std::collections::VecDeque;
use std::sync::{Arc, Mutex};
use wayland_client::{EnvHandler, default_connect, EventQueue, EventQueueHandle, Init, Proxy};
use wayland_client::protocol::{wl_compositor, wl_seat, wl_shell, wl_shm, wl_subcompositor,
wl_display, wl_registry, wl_output, wl_surface};
use super::wayland_window;
/*
* Registry and globals handling
*/
wayland_env!(InnerEnv,
compositor: wl_compositor::WlCompositor,
shell: wl_shell::WlShell,
shm: wl_shm::WlShm,
subcompositor: wl_subcompositor::WlSubcompositor
);
struct WaylandEnv {
registry: wl_registry::WlRegistry,
inner: EnvHandler<InnerEnv>,
monitors: Vec<OutputInfo>,
my_id: usize,
}
struct OutputInfo {
output: wl_output::WlOutput,
id: u32,
scale: f32,
pix_size: (u32, u32),
name: String
}
impl OutputInfo {
fn new(output: wl_output::WlOutput, id: u32) -> OutputInfo {
OutputInfo {
output: output,
id: id,
scale: 1.0,
pix_size: (0, 0),
name: "".into()
}
}
}
impl WaylandEnv {
fn new(registry: wl_registry::WlRegistry) -> WaylandEnv {
WaylandEnv {
registry: registry,
inner: EnvHandler::new(),
monitors: Vec::new(),
my_id: 0,
}
}
fn get_seat(&self) -> Option<wl_seat::WlSeat> {
for &(name, ref interface, version) in self.inner.globals() {
if interface == "wl_seat" {
if version < 5 {
panic!("Winit requires at least version 5 of the wl_seat global.");
}
let seat = self.registry.bind::<wl_seat::WlSeat>(5, name);
return Some(seat)
}
}
None
}
}
impl Init for WaylandEnv {
fn init(&mut self, evqh: &mut EventQueueHandle, index: usize) {
evqh.register::<_, WaylandEnv>(&self.registry, index);
self.my_id = index
}
}
impl wl_registry::Handler for WaylandEnv {
fn global(&mut self,
evqh: &mut EventQueueHandle,
registry: &wl_registry::WlRegistry,
name: u32,
interface: String,
version: u32)
{
if interface == "wl_output" {
// intercept outputs
// this "expect" cannot trigger (see https://github.com/vberger/wayland-client-rs/issues/69)
let output = self.registry.bind::<wl_output::WlOutput>(1, name);
evqh.register::<_, WaylandEnv>(&output, self.my_id);
self.monitors.push(OutputInfo::new(output, name));
}
self.inner.global(evqh, registry, name, interface, version);
}
fn global_remove(&mut self,
evqh: &mut EventQueueHandle,
registry: &wl_registry::WlRegistry,
name: u32)
{
// prune old monitors
self.monitors.retain(|m| m.id != name);
self.inner.global_remove(evqh, registry, name);
}
}
declare_handler!(WaylandEnv, wl_registry::Handler, wl_registry::WlRegistry);
impl wl_output::Handler for WaylandEnv {
fn geometry(&mut self,
_: &mut EventQueueHandle,
proxy: &wl_output::WlOutput,
_x: i32, _y: i32,
_physical_width: i32, _physical_height: i32,
_subpixel: wl_output::Subpixel,
make: String, model: String,
_transform: wl_output::Transform)
{
for m in self.monitors.iter_mut().filter(|m| m.output.equals(proxy)) {
m.name = format!("{} ({})", model, make);
break;
}
}
fn mode(&mut self,
_: &mut EventQueueHandle,
proxy: &wl_output::WlOutput,
flags: wl_output::Mode,
width: i32, height: i32,
_refresh: i32)
{
if flags.contains(wl_output::Current) {
for m in self.monitors.iter_mut().filter(|m| m.output.equals(proxy)) {
m.pix_size = (width as u32, height as u32);
break;
}
}
}
fn scale(&mut self,
_: &mut EventQueueHandle,
proxy: &wl_output::WlOutput,
factor: i32)
{
for m in self.monitors.iter_mut().filter(|m| m.output.equals(proxy)) {
m.scale = factor as f32;
break;
}
}
}
declare_handler!(WaylandEnv, wl_output::Handler, wl_output::WlOutput);
/*
* Main context struct
*/
pub struct WaylandContext {
pub display: wl_display::WlDisplay,
evq: Mutex<EventQueue>,
env_id: usize,
}
impl WaylandContext {
pub fn init() -> Option<WaylandContext> {
// attempt to connect to the wayland server
// this handles both "no libwayland" and "no compositor" cases
let (display, mut event_queue) = match default_connect() {
Ok(ret) => ret,
Err(_) => return None
};
// this "expect" cannot trigger (see https://github.com/vberger/wayland-client-rs/issues/69)
let registry = display.get_registry();
let env_id = event_queue.add_handler_with_init(WaylandEnv::new(registry));
// two syncs fully initialize
event_queue.sync_roundtrip().expect("Wayland connection unexpectedly lost");
event_queue.sync_roundtrip().expect("Wayland connection unexpectedly lost");
Some(WaylandContext {
evq: Mutex::new(event_queue),
display: display,
env_id: env_id
})
}
pub fn dispatch_pending(&self) {
let mut guard = self.evq.lock().unwrap();
guard.dispatch_pending().expect("Wayland connection unexpectedly lost");
}
pub fn dispatch(&self) {
let mut guard = self.evq.lock().unwrap();
guard.dispatch().expect("Wayland connection unexpectedly lost");
}
pub fn flush(&self) {
let _ = self.display.flush();
}
pub fn get_seat(&self) -> Option<wl_seat::WlSeat> {
let mut guard = self.evq.lock().unwrap();
let state = guard.state();
state.get_handler::<WaylandEnv>(self.env_id).get_seat()
}
pub fn with_output<F>(&self, id: MonitorId, f: F) where F: FnOnce(&wl_output::WlOutput) {
let mut guard = self.evq.lock().unwrap();
let state = guard.state();
let env = state.get_handler::<WaylandEnv>(self.env_id);
for m in env.monitors.iter().filter(|m| m.id == id.id) {
f(&m.output);
break
}
}
pub fn create_window<H: wayland_window::Handler>(&self)
-> (Arc<wl_surface::WlSurface>, wayland_window::DecoratedSurface<H>)
{
let mut guard = self.evq.lock().unwrap();
let mut state = guard.state();
let env = state.get_mut_handler::<WaylandEnv>(self.env_id);
// this "expect" cannot trigger (see https://github.com/vberger/wayland-client-rs/issues/69)
let surface = Arc::new(env.inner.compositor.create_surface());
let decorated = wayland_window::DecoratedSurface::new(
&*surface, 800, 600,
&env.inner.compositor,
&env.inner.subcompositor,
&env.inner.shm,
&env.inner.shell,
env.get_seat(),
false
).expect("Failed to create a tmpfile buffer.");
(surface, decorated)
}
}
/*
* Monitors API
*/
pub fn get_primary_monitor(ctxt: &Arc<WaylandContext>) -> MonitorId {
let mut guard = ctxt.evq.lock().unwrap();
let state = guard.state();
let env = state.get_handler::<WaylandEnv>(ctxt.env_id);
if let Some(ref monitor) = env.monitors.iter().next() {
MonitorId {
id: monitor.id,
ctxt: ctxt.clone()
}
} else {
panic!("No monitor is available.")
}
}
pub fn get_available_monitors(ctxt: &Arc<WaylandContext>) -> VecDeque<MonitorId> {
let mut guard = ctxt.evq.lock().unwrap();
let state = guard.state();
let env = state.get_handler::<WaylandEnv>(ctxt.env_id);
env.monitors.iter()
.map(|m| MonitorId { id: m.id, ctxt: ctxt.clone() })
.collect()
}
#[derive(Clone)]
pub struct MonitorId {
id: u32,
ctxt: Arc<WaylandContext>
}
impl MonitorId {
pub fn get_name(&self) -> Option<String> {
let mut guard = self.ctxt.evq.lock().unwrap();
let state = guard.state();
let env = state.get_handler::<WaylandEnv>(self.ctxt.env_id);
for m in env.monitors.iter().filter(|m| m.id == self.id) {
return Some(m.name.clone())
}
// if we reach here, this monitor does not exist any more
None
}
#[inline]
pub fn get_native_identifier(&self) -> ::native_monitor::NativeMonitorId {
::native_monitor::NativeMonitorId::Unavailable
}
pub fn get_dimensions(&self) -> (u32, u32) {
let mut guard = self.ctxt.evq.lock().unwrap();
let state = guard.state();
let env = state.get_handler::<WaylandEnv>(self.ctxt.env_id);
for m in env.monitors.iter().filter(|m| m.id == self.id) {
return m.pix_size
}
// if we reach here, this monitor does not exist any more
(0,0)
}
}

971
src/platform/linux/wayland/event_loop.rs
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File diff suppressed because it is too large Load Diff

265
src/platform/linux/wayland/keyboard.rs
View File

@@ -1,187 +1,87 @@
use std::sync::{Arc, Mutex};
use super::{make_wid, DeviceId, EventsLoopProxy, EventsLoopSink};
use sctk::keyboard::{
self, map_keyboard_auto_with_repeat, Event as KbEvent, KeyRepeatEvent, KeyRepeatKind,
};
use sctk::reexports::client::protocol::wl_keyboard;
use sctk::reexports::client::{NewProxy, Proxy};
use {ElementState, KeyboardInput, ModifiersState, VirtualKeyCode, WindowEvent};
use {VirtualKeyCode, ElementState, WindowEvent as Event};
pub fn init_keyboard(
keyboard: NewProxy<wl_keyboard::WlKeyboard>,
use events::ModifiersState;
use super::{wayland_kbd, EventsLoopSink, WindowId};
use wayland_client::EventQueueHandle;
use wayland_client::protocol::wl_keyboard;
pub struct KbdHandler {
sink: Arc<Mutex<EventsLoopSink>>,
events_loop_proxy: EventsLoopProxy,
) -> Proxy<wl_keyboard::WlKeyboard> {
// { variables to be captured by the closures
let target = Arc::new(Mutex::new(None));
let my_sink = sink.clone();
let repeat_sink = sink.clone();
let repeat_target = target.clone();
// }
let ret = map_keyboard_auto_with_repeat(
keyboard,
KeyRepeatKind::System,
move |evt: KbEvent, _| match evt {
KbEvent::Enter { surface, .. } => {
let wid = make_wid(&surface);
my_sink
.lock()
.unwrap()
.send_event(WindowEvent::Focused(true), wid);
*target.lock().unwrap() = Some(wid);
}
KbEvent::Leave { surface, .. } => {
let wid = make_wid(&surface);
my_sink
.lock()
.unwrap()
.send_event(WindowEvent::Focused(false), wid);
*target.lock().unwrap() = None;
}
KbEvent::Key {
modifiers,
rawkey,
keysym,
state,
utf8,
..
} => {
if let Some(wid) = *target.lock().unwrap() {
let state = match state {
wl_keyboard::KeyState::Pressed => ElementState::Pressed,
wl_keyboard::KeyState::Released => ElementState::Released,
};
let vkcode = key_to_vkey(rawkey, keysym);
let mut guard = my_sink.lock().unwrap();
guard.send_event(
WindowEvent::KeyboardInput {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
input: KeyboardInput {
state: state,
scancode: rawkey,
virtual_keycode: vkcode,
modifiers: modifiers.into(),
},
},
wid,
);
// send char event only on key press, not release
if let ElementState::Released = state {
return;
}
if let Some(txt) = utf8 {
for chr in txt.chars() {
guard.send_event(WindowEvent::ReceivedCharacter(chr), wid);
}
}
}
}
KbEvent::RepeatInfo { .. } => { /* Handled by smithay client toolkit */ }
},
move |repeat_event: KeyRepeatEvent, _| {
if let Some(wid) = *repeat_target.lock().unwrap() {
let state = ElementState::Pressed;
let vkcode = key_to_vkey(repeat_event.rawkey, repeat_event.keysym);
let mut guard = repeat_sink.lock().unwrap();
guard.send_event(
WindowEvent::KeyboardInput {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
input: KeyboardInput {
state: state,
scancode: repeat_event.rawkey,
virtual_keycode: vkcode,
modifiers: repeat_event.modifiers.into(),
},
},
wid,
);
if let Some(txt) = repeat_event.utf8 {
for chr in txt.chars() {
guard.send_event(WindowEvent::ReceivedCharacter(chr), wid);
}
}
events_loop_proxy.wakeup().unwrap();
}
},
);
pub target: Option<WindowId>
}
match ret {
Ok(keyboard) => keyboard,
Err((_, keyboard)) => {
// This is a fallback impl if libxkbcommon was not available
// This case should probably never happen, as most wayland
// compositors _need_ libxkbcommon anyway...
//
// In this case, we don't have the keymap information (it is
// supposed to be serialized by the compositor using libxkbcommon)
impl KbdHandler {
pub fn new(sink: Arc<Mutex<EventsLoopSink>>) -> KbdHandler {
KbdHandler { sink: sink, target: None }
}
}
// { variables to be captured by the closure
let mut target = None;
let my_sink = sink;
// }
keyboard.implement(move |evt, _| match evt {
wl_keyboard::Event::Enter { surface, .. } => {
let wid = make_wid(&surface);
my_sink
.lock()
.unwrap()
.send_event(WindowEvent::Focused(true), wid);
target = Some(wid);
}
wl_keyboard::Event::Leave { surface, .. } => {
let wid = make_wid(&surface);
my_sink
.lock()
.unwrap()
.send_event(WindowEvent::Focused(false), wid);
target = None;
}
wl_keyboard::Event::Key { key, state, .. } => {
if let Some(wid) = target {
let state = match state {
wl_keyboard::KeyState::Pressed => ElementState::Pressed,
wl_keyboard::KeyState::Released => ElementState::Released,
};
my_sink.lock().unwrap().send_event(
WindowEvent::KeyboardInput {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
input: KeyboardInput {
state: state,
scancode: key,
virtual_keycode: None,
modifiers: ModifiersState::default(),
},
},
wid,
);
impl wayland_kbd::Handler for KbdHandler {
fn key(&mut self,
_evqh: &mut EventQueueHandle,
_proxy: &wl_keyboard::WlKeyboard,
_serial: u32,
_time: u32,
mods: &wayland_kbd::ModifiersState,
rawkey: u32,
keysym: u32,
state: wl_keyboard::KeyState,
utf8: Option<String>)
{
if let Some(wid) = self.target {
let state = match state {
wl_keyboard::KeyState::Pressed => ElementState::Pressed,
wl_keyboard::KeyState::Released => ElementState::Released,
};
let vkcode = key_to_vkey(rawkey, keysym);
let mut guard = self.sink.lock().unwrap();
guard.send_event(
Event::KeyboardInput(
state,
rawkey as u8,
vkcode,
ModifiersState {
shift: mods.shift,
ctrl: mods.ctrl,
alt: mods.alt,
logo: mods.logo
}
),
wid
);
// send char event only on key press, not release
if let ElementState::Released = state { return }
if let Some(txt) = utf8 {
for chr in txt.chars() {
guard.send_event(Event::ReceivedCharacter(chr), wid);
}
_ => (),
})
}
}
}
}
fn key_to_vkey(rawkey: u32, keysym: u32) -> Option<VirtualKeyCode> {
match rawkey {
1 => Some(VirtualKeyCode::Escape),
2 => Some(VirtualKeyCode::Key1),
3 => Some(VirtualKeyCode::Key2),
4 => Some(VirtualKeyCode::Key3),
5 => Some(VirtualKeyCode::Key4),
6 => Some(VirtualKeyCode::Key5),
7 => Some(VirtualKeyCode::Key6),
8 => Some(VirtualKeyCode::Key7),
9 => Some(VirtualKeyCode::Key8),
1 => Some(VirtualKeyCode::Escape),
2 => Some(VirtualKeyCode::Key1),
3 => Some(VirtualKeyCode::Key2),
4 => Some(VirtualKeyCode::Key3),
5 => Some(VirtualKeyCode::Key4),
6 => Some(VirtualKeyCode::Key5),
7 => Some(VirtualKeyCode::Key6),
8 => Some(VirtualKeyCode::Key7),
9 => Some(VirtualKeyCode::Key8),
10 => Some(VirtualKeyCode::Key9),
11 => Some(VirtualKeyCode::Key0),
_ => keysym_to_vkey(keysym),
_ => keysym_to_vkey(keysym)
}
}
fn keysym_to_vkey(keysym: u32) -> Option<VirtualKeyCode> {
use sctk::keyboard::keysyms;
use super::wayland_kbd::keysyms;
match keysym {
// letters
keysyms::XKB_KEY_A | keysyms::XKB_KEY_a => Some(VirtualKeyCode::A),
@@ -211,15 +111,15 @@ fn keysym_to_vkey(keysym: u32) -> Option<VirtualKeyCode> {
keysyms::XKB_KEY_Y | keysyms::XKB_KEY_y => Some(VirtualKeyCode::Y),
keysyms::XKB_KEY_Z | keysyms::XKB_KEY_z => Some(VirtualKeyCode::Z),
// F--
keysyms::XKB_KEY_F1 => Some(VirtualKeyCode::F1),
keysyms::XKB_KEY_F2 => Some(VirtualKeyCode::F2),
keysyms::XKB_KEY_F3 => Some(VirtualKeyCode::F3),
keysyms::XKB_KEY_F4 => Some(VirtualKeyCode::F4),
keysyms::XKB_KEY_F5 => Some(VirtualKeyCode::F5),
keysyms::XKB_KEY_F6 => Some(VirtualKeyCode::F6),
keysyms::XKB_KEY_F7 => Some(VirtualKeyCode::F7),
keysyms::XKB_KEY_F8 => Some(VirtualKeyCode::F8),
keysyms::XKB_KEY_F9 => Some(VirtualKeyCode::F9),
keysyms::XKB_KEY_F1 => Some(VirtualKeyCode::F1),
keysyms::XKB_KEY_F2 => Some(VirtualKeyCode::F2),
keysyms::XKB_KEY_F3 => Some(VirtualKeyCode::F3),
keysyms::XKB_KEY_F4 => Some(VirtualKeyCode::F4),
keysyms::XKB_KEY_F5 => Some(VirtualKeyCode::F5),
keysyms::XKB_KEY_F6 => Some(VirtualKeyCode::F6),
keysyms::XKB_KEY_F7 => Some(VirtualKeyCode::F7),
keysyms::XKB_KEY_F8 => Some(VirtualKeyCode::F8),
keysyms::XKB_KEY_F9 => Some(VirtualKeyCode::F9),
keysyms::XKB_KEY_F10 => Some(VirtualKeyCode::F10),
keysyms::XKB_KEY_F11 => Some(VirtualKeyCode::F11),
keysyms::XKB_KEY_F12 => Some(VirtualKeyCode::F12),
@@ -280,6 +180,7 @@ fn keysym_to_vkey(keysym: u32) -> Option<VirtualKeyCode> {
keysyms::XKB_KEY_Alt_L => Some(VirtualKeyCode::LAlt),
// => Some(VirtualKeyCode::LBracket),
keysyms::XKB_KEY_Control_L => Some(VirtualKeyCode::LControl),
// => Some(VirtualKeyCode::LMenu),
keysyms::XKB_KEY_Shift_L => Some(VirtualKeyCode::LShift),
// => Some(VirtualKeyCode::LWin),
// => Some(VirtualKeyCode::Mail),
@@ -302,6 +203,7 @@ fn keysym_to_vkey(keysym: u32) -> Option<VirtualKeyCode> {
keysyms::XKB_KEY_Alt_R => Some(VirtualKeyCode::RAlt),
// => Some(VirtualKeyCode::RBracket),
keysyms::XKB_KEY_Control_R => Some(VirtualKeyCode::RControl),
// => Some(VirtualKeyCode::RMenu),
keysyms::XKB_KEY_Shift_R => Some(VirtualKeyCode::RShift),
// => Some(VirtualKeyCode::RWin),
keysyms::XKB_KEY_semicolon => Some(VirtualKeyCode::Semicolon),
@@ -311,7 +213,6 @@ fn keysym_to_vkey(keysym: u32) -> Option<VirtualKeyCode> {
// => Some(VirtualKeyCode::Subtract),
// => Some(VirtualKeyCode::Sysrq),
keysyms::XKB_KEY_Tab => Some(VirtualKeyCode::Tab),
keysyms::XKB_KEY_ISO_Left_Tab => Some(VirtualKeyCode::Tab),
// => Some(VirtualKeyCode::Underline),
// => Some(VirtualKeyCode::Unlabeled),
keysyms::XKB_KEY_XF86AudioLowerVolume => Some(VirtualKeyCode::VolumeDown),
@@ -325,21 +226,7 @@ fn keysym_to_vkey(keysym: u32) -> Option<VirtualKeyCode> {
// => Some(VirtualKeyCode::WebSearch),
// => Some(VirtualKeyCode::WebStop),
// => Some(VirtualKeyCode::Yen),
keysyms::XKB_KEY_XF86Copy => Some(VirtualKeyCode::Copy),
keysyms::XKB_KEY_XF86Paste => Some(VirtualKeyCode::Paste),
keysyms::XKB_KEY_XF86Cut => Some(VirtualKeyCode::Cut),
// fallback
_ => None,
}
}
impl From<keyboard::ModifiersState> for ModifiersState {
fn from(mods: keyboard::ModifiersState) -> ModifiersState {
ModifiersState {
shift: mods.shift,
ctrl: mods.ctrl,
alt: mods.alt,
logo: mods.logo,
}
_ => None
}
}

30
src/platform/linux/wayland/mod.rs
View File

@@ -1,25 +1,17 @@
#![cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd",
target_os = "netbsd", target_os = "openbsd"))]
#![cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd"))]
pub use self::window::Window;
pub use self::event_loop::{EventsLoop, EventsLoopProxy, EventsLoopSink, MonitorId};
pub use self::window::{Window, WindowId};
pub use self::event_loop::EventsLoop;
pub use self::context::{WaylandContext, MonitorId, get_available_monitors,
get_primary_monitor};
use sctk::reexports::client::protocol::wl_surface;
use sctk::reexports::client::Proxy;
use self::window::{make_wid, DecoratedHandler};
use self::event_loop::EventsLoopSink;
extern crate wayland_kbd;
extern crate wayland_window;
mod context;
mod event_loop;
mod pointer;
mod touch;
mod keyboard;
mod window;
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct DeviceId;
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WindowId(usize);
#[inline]
fn make_wid(s: &Proxy<wl_surface::WlSurface>) -> WindowId {
WindowId(s.c_ptr() as usize)
}

190
src/platform/linux/wayland/pointer.rs
View File

@@ -1,190 +0,0 @@
use std::sync::{Arc, Mutex};
use {ElementState, MouseButton, MouseScrollDelta, TouchPhase, WindowEvent};
use events::ModifiersState;
use super::DeviceId;
use super::event_loop::EventsLoopSink;
use super::window::WindowStore;
use sctk::reexports::client::{NewProxy, Proxy};
use sctk::reexports::client::protocol::wl_pointer::{self, Event as PtrEvent, WlPointer};
pub fn implement_pointer(
pointer: NewProxy<WlPointer>,
sink: Arc<Mutex<EventsLoopSink>>,
store: Arc<Mutex<WindowStore>>,
) -> Proxy<WlPointer> {
let mut mouse_focus = None;
let mut axis_buffer = None;
let mut axis_discrete_buffer = None;
let mut axis_state = TouchPhase::Ended;
pointer.implement(move |evt, pointer: Proxy<_>| {
let mut sink = sink.lock().unwrap();
let store = store.lock().unwrap();
match evt {
PtrEvent::Enter {
surface,
surface_x,
surface_y,
..
} => {
let wid = store.find_wid(&surface);
if let Some(wid) = wid {
mouse_focus = Some(wid);
sink.send_event(
WindowEvent::CursorEntered {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
},
wid,
);
sink.send_event(
WindowEvent::CursorMoved {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
position: (surface_x, surface_y).into(),
// TODO: replace dummy value with actual modifier state
modifiers: ModifiersState::default(),
},
wid,
);
}
}
PtrEvent::Leave { surface, .. } => {
mouse_focus = None;
let wid = store.find_wid(&surface);
if let Some(wid) = wid {
sink.send_event(
WindowEvent::CursorLeft {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
},
wid,
);
}
}
PtrEvent::Motion {
surface_x,
surface_y,
..
} => {
if let Some(wid) = mouse_focus {
sink.send_event(
WindowEvent::CursorMoved {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
position: (surface_x, surface_y).into(),
// TODO: replace dummy value with actual modifier state
modifiers: ModifiersState::default(),
},
wid,
);
}
}
PtrEvent::Button { button, state, .. } => {
if let Some(wid) = mouse_focus {
let state = match state {
wl_pointer::ButtonState::Pressed => ElementState::Pressed,
wl_pointer::ButtonState::Released => ElementState::Released,
};
let button = match button {
0x110 => MouseButton::Left,
0x111 => MouseButton::Right,
0x112 => MouseButton::Middle,
// TODO figure out the translation ?
_ => return,
};
sink.send_event(
WindowEvent::MouseInput {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
state: state,
button: button,
// TODO: replace dummy value with actual modifier state
modifiers: ModifiersState::default(),
},
wid,
);
}
}
PtrEvent::Axis { axis, value, .. } => {
if let Some(wid) = mouse_focus {
if pointer.version() < 5 {
let (mut x, mut y) = (0.0, 0.0);
// old seat compatibility
match axis {
// wayland vertical sign convention is the inverse of winit
wl_pointer::Axis::VerticalScroll => y -= value as f32,
wl_pointer::Axis::HorizontalScroll => x += value as f32,
}
sink.send_event(
WindowEvent::MouseWheel {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
delta: MouseScrollDelta::PixelDelta((x as f64, y as f64).into()),
phase: TouchPhase::Moved,
// TODO: replace dummy value with actual modifier state
modifiers: ModifiersState::default(),
},
wid,
);
} else {
let (mut x, mut y) = axis_buffer.unwrap_or((0.0, 0.0));
match axis {
// wayland vertical sign convention is the inverse of winit
wl_pointer::Axis::VerticalScroll => y -= value as f32,
wl_pointer::Axis::HorizontalScroll => x += value as f32,
}
axis_buffer = Some((x, y));
axis_state = match axis_state {
TouchPhase::Started | TouchPhase::Moved => TouchPhase::Moved,
_ => TouchPhase::Started,
}
}
}
}
PtrEvent::Frame => {
let axis_buffer = axis_buffer.take();
let axis_discrete_buffer = axis_discrete_buffer.take();
if let Some(wid) = mouse_focus {
if let Some((x, y)) = axis_discrete_buffer {
sink.send_event(
WindowEvent::MouseWheel {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
delta: MouseScrollDelta::LineDelta(x as f32, y as f32),
phase: axis_state,
// TODO: replace dummy value with actual modifier state
modifiers: ModifiersState::default(),
},
wid,
);
} else if let Some((x, y)) = axis_buffer {
sink.send_event(
WindowEvent::MouseWheel {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
delta: MouseScrollDelta::PixelDelta((x as f64, y as f64).into()),
phase: axis_state,
// TODO: replace dummy value with actual modifier state
modifiers: ModifiersState::default(),
},
wid,
);
}
}
}
PtrEvent::AxisSource { .. } => (),
PtrEvent::AxisStop { .. } => {
axis_state = TouchPhase::Ended;
}
PtrEvent::AxisDiscrete { axis, discrete } => {
let (mut x, mut y) = axis_discrete_buffer.unwrap_or((0, 0));
match axis {
// wayland vertical sign convention is the inverse of winit
wl_pointer::Axis::VerticalScroll => y -= discrete,
wl_pointer::Axis::HorizontalScroll => x += discrete,
}
axis_discrete_buffer = Some((x, y));
axis_state = match axis_state {
TouchPhase::Started | TouchPhase::Moved => TouchPhase::Moved,
_ => TouchPhase::Started,
}
}
}
})
}

93
src/platform/linux/wayland/touch.rs
View File

@@ -1,93 +0,0 @@
use std::sync::{Arc, Mutex};
use {TouchPhase, WindowEvent};
use super::{DeviceId, WindowId};
use super::event_loop::EventsLoopSink;
use super::window::WindowStore;
use sctk::reexports::client::{NewProxy, Proxy};
use sctk::reexports::client::protocol::wl_touch::{Event as TouchEvent, WlTouch};
struct TouchPoint {
wid: WindowId,
location: (f64, f64),
id: i32,
}
pub(crate) fn implement_touch(
touch: NewProxy<WlTouch>,
sink: Arc<Mutex<EventsLoopSink>>,
store: Arc<Mutex<WindowStore>>,
) -> Proxy<WlTouch> {
let mut pending_ids = Vec::new();
touch.implement(move |evt, _| {
let mut sink = sink.lock().unwrap();
let store = store.lock().unwrap();
match evt {
TouchEvent::Down {
surface, id, x, y, ..
} => {
let wid = store.find_wid(&surface);
if let Some(wid) = wid {
sink.send_event(
WindowEvent::Touch(::Touch {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
phase: TouchPhase::Started,
location: (x, y).into(),
id: id as u64,
}),
wid,
);
pending_ids.push(TouchPoint {
wid: wid,
location: (x, y),
id: id,
});
}
}
TouchEvent::Up { id, .. } => {
let idx = pending_ids.iter().position(|p| p.id == id);
if let Some(idx) = idx {
let pt = pending_ids.remove(idx);
sink.send_event(
WindowEvent::Touch(::Touch {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
phase: TouchPhase::Ended,
location: pt.location.into(),
id: id as u64,
}),
pt.wid,
);
}
}
TouchEvent::Motion { id, x, y, .. } => {
let pt = pending_ids.iter_mut().find(|p| p.id == id);
if let Some(pt) = pt {
pt.location = (x, y);
sink.send_event(
WindowEvent::Touch(::Touch {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
phase: TouchPhase::Moved,
location: (x, y).into(),
id: id as u64,
}),
pt.wid,
);
}
}
TouchEvent::Frame => (),
TouchEvent::Cancel => for pt in pending_ids.drain(..) {
sink.send_event(
WindowEvent::Touch(::Touch {
device_id: ::DeviceId(::platform::DeviceId::Wayland(DeviceId)),
phase: TouchPhase::Cancelled,
location: pt.location.into(),
id: pt.id as u64,
}),
pt.wid,
);
},
}
})
}

497
src/platform/linux/wayland/window.rs
View File

@@ -1,165 +1,87 @@
use std::collections::VecDeque;
use std::sync::{Arc, Mutex, Weak};
use std::sync::{Arc, Mutex};
use std::sync::atomic::AtomicBool;
use {CreationError, MouseCursor, WindowAttributes};
use dpi::{LogicalPosition, LogicalSize};
use wayland_client::{EventQueue, EventQueueHandle, Proxy};
use wayland_client::protocol::{wl_display,wl_surface,wl_shell_surface};
use {CreationError, MouseCursor, CursorState, WindowAttributes};
use platform::MonitorId as PlatformMonitorId;
use window::MonitorId as RootMonitorId;
use sctk::window::{BasicFrame, Event as WEvent, Window as SWindow};
use sctk::reexports::client::{Display, Proxy};
use sctk::reexports::client::protocol::{wl_seat, wl_surface, wl_output};
use sctk::reexports::client::protocol::wl_compositor::RequestsTrait as CompositorRequests;
use sctk::reexports::client::protocol::wl_surface::RequestsTrait as SurfaceRequests;
use sctk::output::OutputMgr;
use super::{make_wid, EventsLoop, MonitorId, WindowId};
use platform::platform::wayland::event_loop::{get_available_monitors, get_primary_monitor};
use super::{WaylandContext, EventsLoop};
use super::wayland_window;
use super::wayland_window::DecoratedSurface;
pub struct Window {
surface: Proxy<wl_surface::WlSurface>,
frame: Arc<Mutex<SWindow<BasicFrame>>>,
monitors: Arc<Mutex<MonitorList>>, // Monitors this window is currently on
outputs: OutputMgr, // Access to info for all monitors
size: Arc<Mutex<(u32, u32)>>,
kill_switch: (Arc<Mutex<bool>>, Arc<Mutex<bool>>),
display: Arc<Display>,
need_frame_refresh: Arc<Mutex<bool>>,
// the global wayland context
ctxt: Arc<WaylandContext>,
// the EventQueue of our EventsLoop
evq: Arc<Mutex<EventQueue>>,
// signal to advertize the EventsLoop when we are destroyed
cleanup_signal: Arc<AtomicBool>,
// our wayland surface
surface: Arc<wl_surface::WlSurface>,
// our current inner dimensions
size: Mutex<(u32, u32)>,
// the id of our DecoratedHandler in the EventQueue
decorated_id: usize
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WindowId(usize);
#[inline]
pub fn make_wid(s: &wl_surface::WlSurface) -> WindowId {
WindowId(s.ptr() as usize)
}
impl Window {
pub fn new(evlp: &EventsLoop, attributes: WindowAttributes) -> Result<Window, CreationError> {
let (width, height) = attributes.dimensions.map(Into::into).unwrap_or((800, 600));
// Create the window
let size = Arc::new(Mutex::new((width, height)));
pub fn new(evlp: &EventsLoop, ctxt: Arc<WaylandContext>, attributes: &WindowAttributes) -> Result<Window, CreationError>
{
let (width, height) = attributes.dimensions.unwrap_or((800,600));
// monitor tracking
let monitor_list = Arc::new(Mutex::new(MonitorList::new()));
let (surface, decorated) = ctxt.create_window::<DecoratedHandler>();
let surface = evlp.env.compositor.create_surface().unwrap().implement({
let list = monitor_list.clone();
let omgr = evlp.env.outputs.clone();
let window_store = evlp.store.clone();
move |event, surface: Proxy<wl_surface::WlSurface>| match event {
wl_surface::Event::Enter { output } => {
let dpi_change = list.lock().unwrap().add_output(MonitorId {
proxy: output,
mgr: omgr.clone(),
// init DecoratedSurface
let (evq, cleanup_signal) = evlp.get_window_init();
let decorated_id = {
let mut evq_guard = evq.lock().unwrap();
let decorated_id = evq_guard.add_handler_with_init(decorated);
{
// initialize the DecoratedHandler
let mut state = evq_guard.state();
let decorated = state.get_mut_handler::<DecoratedSurface<DecoratedHandler>>(decorated_id);
*(decorated.handler()) = Some(DecoratedHandler::new());
// set fullscreen if necessary
if let Some(PlatformMonitorId::Wayland(ref monitor_id)) = attributes.monitor {
ctxt.with_output(monitor_id.clone(), |output| {
decorated.set_fullscreen(
wl_shell_surface::FullscreenMethod::Default,
0,
Some(output)
)
});
if let Some(dpi) = dpi_change {
if surface.version() >= 3 {
// without version 3 we can't be dpi aware
window_store.lock().unwrap().dpi_change(&surface, dpi);
surface.set_buffer_scale(dpi);
}
}
},
wl_surface::Event::Leave { output } => {
let dpi_change = list.lock().unwrap().del_output(&output);
if let Some(dpi) = dpi_change {
if surface.version() >= 3 {
// without version 3 we can't be dpi aware
window_store.lock().unwrap().dpi_change(&surface, dpi);
surface.set_buffer_scale(dpi);
}
}
} else if attributes.decorations {
decorated.set_decorate(true);
}
// Finally, set the decorations size
decorated.resize(width as i32, height as i32);
}
});
let window_store = evlp.store.clone();
let my_surface = surface.clone();
let mut frame = SWindow::<BasicFrame>::init(
surface.clone(),
(width, height),
&evlp.env.compositor,
&evlp.env.subcompositor,
&evlp.env.shm,
&evlp.env.shell,
move |event, ()| match event {
WEvent::Configure { new_size, .. } => {
let mut store = window_store.lock().unwrap();
for window in &mut store.windows {
if window.surface.equals(&my_surface) {
window.newsize = new_size;
window.need_refresh = true;
*(window.need_frame_refresh.lock().unwrap()) = true;
return;
}
}
}
WEvent::Refresh => {
let store = window_store.lock().unwrap();
for window in &store.windows {
if window.surface.equals(&my_surface) {
*(window.need_frame_refresh.lock().unwrap()) = true;
return;
}
}
}
WEvent::Close => {
let mut store = window_store.lock().unwrap();
for window in &mut store.windows {
if window.surface.equals(&my_surface) {
window.closed = true;
return;
}
}
}
},
).unwrap();
for &(_, ref seat) in evlp.seats.lock().unwrap().iter() {
frame.new_seat(seat);
}
// Check for fullscreen requirements
if let Some(RootMonitorId {
inner: PlatformMonitorId::Wayland(ref monitor_id),
}) = attributes.fullscreen
{
frame.set_fullscreen(Some(&monitor_id.proxy));
} else if attributes.maximized {
frame.set_maximized();
}
frame.set_resizable(attributes.resizable);
// set decorations
frame.set_decorate(attributes.decorations);
// min-max dimensions
frame.set_min_size(attributes.min_dimensions.map(Into::into));
frame.set_max_size(attributes.max_dimensions.map(Into::into));
let kill_switch = Arc::new(Mutex::new(false));
let need_frame_refresh = Arc::new(Mutex::new(true));
let frame = Arc::new(Mutex::new(frame));
evlp.store.lock().unwrap().windows.push(InternalWindow {
closed: false,
newsize: None,
size: size.clone(),
need_refresh: false,
need_frame_refresh: need_frame_refresh.clone(),
surface: surface.clone(),
kill_switch: kill_switch.clone(),
frame: Arc::downgrade(&frame),
current_dpi: 1,
new_dpi: None,
});
evlp.evq.borrow_mut().sync_roundtrip().unwrap();
Ok(Window {
display: evlp.display.clone(),
decorated_id
};
let me = Window {
ctxt: ctxt,
evq: evq,
cleanup_signal: cleanup_signal,
surface: surface,
frame: frame,
monitors: monitor_list,
outputs: evlp.env.outputs.clone(),
size: size,
kill_switch: (kill_switch, evlp.cleanup_needed.clone()),
need_frame_refresh: need_frame_refresh,
})
size: Mutex::new((width, height)),
decorated_id: decorated_id
};
// register ourselves to the EventsLoop
evlp.register_window(me.decorated_id, me.surface.clone());
Ok(me)
}
#[inline]
@@ -168,7 +90,10 @@ impl Window {
}
pub fn set_title(&self, title: &str) {
self.frame.lock().unwrap().set_title(title.into());
let mut guard = self.evq.lock().unwrap();
let mut state = guard.state();
let decorated = state.get_mut_handler::<DecoratedSurface<DecoratedHandler>>(self.decorated_id);
decorated.set_title(title.into())
}
#[inline]
@@ -182,86 +107,34 @@ impl Window {
}
#[inline]
pub fn get_position(&self) -> Option<LogicalPosition> {
pub fn get_position(&self) -> Option<(i32, i32)> {
// Not possible with wayland
None
}
#[inline]
pub fn get_inner_position(&self) -> Option<LogicalPosition> {
// Not possible with wayland
None
}
#[inline]
pub fn set_position(&self, _pos: LogicalPosition) {
pub fn set_position(&self, _x: i32, _y: i32) {
// Not possible with wayland
}
pub fn get_inner_size(&self) -> Option<LogicalSize> {
Some(self.size.lock().unwrap().clone().into())
pub fn get_inner_size(&self) -> Option<(u32, u32)> {
Some(self.size.lock().unwrap().clone())
}
#[inline]
pub fn get_outer_size(&self) -> Option<LogicalSize> {
pub fn get_outer_size(&self) -> Option<(u32, u32)> {
let (w, h) = self.size.lock().unwrap().clone();
// let (w, h) = super::wayland_window::add_borders(w as i32, h as i32);
Some((w, h).into())
let (w, h) = super::wayland_window::add_borders(w as i32, h as i32);
Some((w as u32, h as u32))
}
#[inline]
// NOTE: This will only resize the borders, the contents must be updated by the user
pub fn set_inner_size(&self, size: LogicalSize) {
let (w, h) = size.into();
self.frame.lock().unwrap().resize(w, h);
*(self.size.lock().unwrap()) = (w, h);
}
#[inline]
pub fn set_min_dimensions(&self, dimensions: Option<LogicalSize>) {
self.frame.lock().unwrap().set_min_size(dimensions.map(Into::into));
}
#[inline]
pub fn set_max_dimensions(&self, dimensions: Option<LogicalSize>) {
self.frame.lock().unwrap().set_max_size(dimensions.map(Into::into));
}
#[inline]
pub fn set_resizable(&self, resizable: bool) {
self.frame.lock().unwrap().set_resizable(resizable);
}
#[inline]
pub fn hidpi_factor(&self) -> i32 {
self.monitors.lock().unwrap().compute_hidpi_factor()
}
pub fn set_decorations(&self, decorate: bool) {
self.frame.lock().unwrap().set_decorate(decorate);
*(self.need_frame_refresh.lock().unwrap()) = true;
}
pub fn set_maximized(&self, maximized: bool) {
if maximized {
self.frame.lock().unwrap().set_maximized();
} else {
self.frame.lock().unwrap().unset_maximized();
}
}
pub fn set_fullscreen(&self, monitor: Option<RootMonitorId>) {
if let Some(RootMonitorId {
inner: PlatformMonitorId::Wayland(ref monitor_id),
}) = monitor
{
self.frame
.lock()
.unwrap()
.set_fullscreen(Some(&monitor_id.proxy));
} else {
self.frame.lock().unwrap().unset_fullscreen();
}
pub fn set_inner_size(&self, x: u32, y: u32) {
let mut guard = self.evq.lock().unwrap();
let mut state = guard.state();
let mut decorated = state.get_mut_handler::<DecoratedSurface<DecoratedHandler>>(self.decorated_id);
decorated.resize(x as i32, y as i32);
}
#[inline]
@@ -270,189 +143,63 @@ impl Window {
}
#[inline]
pub fn hide_cursor(&self, _hide: bool) {
// TODO: This isn't possible on Wayland yet
pub fn set_cursor_state(&self, state: CursorState) -> Result<(), String> {
use CursorState::{Grab, Normal, Hide};
// TODO : not yet possible on wayland to grab cursor
match state {
Grab => Err("Cursor cannot be grabbed on wayland yet.".to_string()),
Hide => Err("Cursor cannot be hidden on wayland yet.".to_string()),
Normal => Ok(())
}
}
#[inline]
pub fn grab_cursor(&self, _grab: bool) -> Result<(), String> {
Err("Cursor grabbing is not yet possible on Wayland.".to_owned())
pub fn hidpi_factor(&self) -> f32 {
// TODO
1.0
}
#[inline]
pub fn set_cursor_position(&self, _pos: LogicalPosition) -> Result<(), String> {
Err("Setting the cursor position is not yet possible on Wayland.".to_owned())
pub fn set_cursor_position(&self, _x: i32, _y: i32) -> Result<(), ()> {
// TODO: not yet possible on wayland
Err(())
}
pub fn get_display(&self) -> &Display {
&*self.display
pub fn get_display(&self) -> &wl_display::WlDisplay {
&self.ctxt.display
}
pub fn get_surface(&self) -> &Proxy<wl_surface::WlSurface> {
pub fn get_surface(&self) -> &wl_surface::WlSurface {
&self.surface
}
pub fn get_current_monitor(&self) -> MonitorId {
// we don't know how much each monitor sees us so...
// just return the most recent one ?
let guard = self.monitors.lock().unwrap();
guard.monitors.last().unwrap().clone()
}
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
get_available_monitors(&self.outputs)
}
pub fn get_primary_monitor(&self) -> MonitorId {
get_primary_monitor(&self.outputs)
}
}
impl Drop for Window {
fn drop(&mut self) {
*(self.kill_switch.0.lock().unwrap()) = true;
*(self.kill_switch.1.lock().unwrap()) = true;
self.surface.destroy();
self.cleanup_signal.store(true, ::std::sync::atomic::Ordering::Relaxed);
}
}
/*
* Internal store for windows
*/
struct InternalWindow {
surface: Proxy<wl_surface::WlSurface>,
newsize: Option<(u32, u32)>,
size: Arc<Mutex<(u32, u32)>>,
need_refresh: bool,
need_frame_refresh: Arc<Mutex<bool>>,
closed: bool,
kill_switch: Arc<Mutex<bool>>,
frame: Weak<Mutex<SWindow<BasicFrame>>>,
current_dpi: i32,
new_dpi: Option<i32>
pub struct DecoratedHandler {
newsize: Option<(u32, u32)>
}
pub struct WindowStore {
windows: Vec<InternalWindow>,
impl DecoratedHandler {
fn new() -> DecoratedHandler { DecoratedHandler { newsize: None }}
pub fn take_newsize(&mut self) -> Option<(u32, u32)> {
self.newsize.take()
}
}
impl WindowStore {
pub fn new() -> WindowStore {
WindowStore {
windows: Vec::new(),
}
}
pub fn find_wid(&self, surface: &Proxy<wl_surface::WlSurface>) -> Option<WindowId> {
for window in &self.windows {
if surface.equals(&window.surface) {
return Some(make_wid(surface));
}
}
None
}
pub fn cleanup(&mut self) -> Vec<WindowId> {
let mut pruned = Vec::new();
self.windows.retain(|w| {
if *w.kill_switch.lock().unwrap() {
// window is dead, cleanup
pruned.push(make_wid(&w.surface));
w.surface.destroy();
false
} else {
true
}
});
pruned
}
pub fn new_seat(&self, seat: &Proxy<wl_seat::WlSeat>) {
for window in &self.windows {
if let Some(w) = window.frame.upgrade() {
w.lock().unwrap().new_seat(seat);
}
}
}
fn dpi_change(&mut self, surface: &Proxy<wl_surface::WlSurface>, new: i32) {
for window in &mut self.windows {
if surface.equals(&window.surface) {
window.new_dpi = Some(new);
}
}
}
pub fn for_each<F>(&mut self, mut f: F)
where
F: FnMut(Option<(u32, u32)>, &mut (u32, u32), Option<i32>, bool, bool, bool, WindowId, Option<&mut SWindow<BasicFrame>>),
impl wayland_window::Handler for DecoratedHandler {
fn configure(&mut self,
_: &mut EventQueueHandle,
_: wl_shell_surface::Resize,
width: i32, height: i32)
{
for window in &mut self.windows {
let opt_arc = window.frame.upgrade();
let mut opt_mutex_lock = opt_arc.as_ref().map(|m| m.lock().unwrap());
f(
window.newsize.take(),
&mut *(window.size.lock().unwrap()),
window.new_dpi,
window.need_refresh,
::std::mem::replace(&mut *window.need_frame_refresh.lock().unwrap(), false),
window.closed,
make_wid(&window.surface),
opt_mutex_lock.as_mut().map(|m| &mut **m),
);
if let Some(dpi) = window.new_dpi.take() {
window.current_dpi = dpi;
}
window.need_refresh = false;
// avoid re-spamming the event
window.closed = false;
}
}
}
/*
* Monitor list with some covenience method to compute DPI
*/
struct MonitorList {
monitors: Vec<MonitorId>
}
impl MonitorList {
fn new() -> MonitorList {
MonitorList {
monitors: Vec::new()
}
}
fn compute_hidpi_factor(&self) -> i32 {
let mut factor = 1;
for monitor_id in &self.monitors {
let monitor_dpi = monitor_id.get_hidpi_factor();
if monitor_dpi > factor { factor = monitor_dpi; }
}
factor
}
fn add_output(&mut self, monitor: MonitorId) -> Option<i32> {
let old_dpi = self.compute_hidpi_factor();
let monitor_dpi = monitor.get_hidpi_factor();
self.monitors.push(monitor);
if monitor_dpi > old_dpi {
Some(monitor_dpi)
} else {
None
}
}
fn del_output(&mut self, output: &Proxy<wl_output::WlOutput>) -> Option<i32> {
let old_dpi = self.compute_hidpi_factor();
self.monitors.retain(|m| !m.proxy.equals(output));
let new_dpi = self.compute_hidpi_factor();
if new_dpi != old_dpi {
Some(new_dpi)
} else {
None
}
use std::cmp::max;
self.newsize = Some((max(width,1) as u32, max(height,1) as u32));
}
}

219
src/platform/linux/x11/dnd.rs
View File

@@ -1,219 +0,0 @@
use std::io;
use std::sync::Arc;
use std::path::{Path, PathBuf};
use std::str::Utf8Error;
use std::os::raw::*;
use percent_encoding::percent_decode;
use super::{ffi, util, XConnection, XError};
#[derive(Debug)]
pub struct DndAtoms {
pub aware: ffi::Atom,
pub enter: ffi::Atom,
pub leave: ffi::Atom,
pub drop: ffi::Atom,
pub position: ffi::Atom,
pub status: ffi::Atom,
pub action_private: ffi::Atom,
pub selection: ffi::Atom,
pub finished: ffi::Atom,
pub type_list: ffi::Atom,
pub uri_list: ffi::Atom,
pub none: ffi::Atom,
}
impl DndAtoms {
pub fn new(xconn: &Arc<XConnection>) -> Result<Self, XError> {
let names = [
b"XdndAware\0".as_ptr() as *mut c_char,
b"XdndEnter\0".as_ptr() as *mut c_char,
b"XdndLeave\0".as_ptr() as *mut c_char,
b"XdndDrop\0".as_ptr() as *mut c_char,
b"XdndPosition\0".as_ptr() as *mut c_char,
b"XdndStatus\0".as_ptr() as *mut c_char,
b"XdndActionPrivate\0".as_ptr() as *mut c_char,
b"XdndSelection\0".as_ptr() as *mut c_char,
b"XdndFinished\0".as_ptr() as *mut c_char,
b"XdndTypeList\0".as_ptr() as *mut c_char,
b"text/uri-list\0".as_ptr() as *mut c_char,
b"None\0".as_ptr() as *mut c_char,
];
let atoms = unsafe { xconn.get_atoms(&names) }?;
Ok(DndAtoms {
aware: atoms[0],
enter: atoms[1],
leave: atoms[2],
drop: atoms[3],
position: atoms[4],
status: atoms[5],
action_private: atoms[6],
selection: atoms[7],
finished: atoms[8],
type_list: atoms[9],
uri_list: atoms[10],
none: atoms[11],
})
}
}
#[derive(Debug, Clone, Copy)]
pub enum DndState {
Accepted,
Rejected,
}
#[derive(Debug)]
pub enum DndDataParseError {
EmptyData,
InvalidUtf8(Utf8Error),
HostnameSpecified(String),
UnexpectedProtocol(String),
UnresolvablePath(io::Error),
}
impl From<Utf8Error> for DndDataParseError {
fn from(e: Utf8Error) -> Self {
DndDataParseError::InvalidUtf8(e)
}
}
impl From<io::Error> for DndDataParseError {
fn from(e: io::Error) -> Self {
DndDataParseError::UnresolvablePath(e)
}
}
pub struct Dnd {
xconn: Arc<XConnection>,
pub atoms: DndAtoms,
// Populated by XdndEnter event handler
pub version: Option<c_long>,
pub type_list: Option<Vec<c_ulong>>,
// Populated by XdndPosition event handler
pub source_window: Option<c_ulong>,
// Populated by SelectionNotify event handler (triggered by XdndPosition event handler)
pub result: Option<Result<Vec<PathBuf>, DndDataParseError>>,
}
impl Dnd {
pub fn new(xconn: Arc<XConnection>) -> Result<Self, XError> {
let atoms = DndAtoms::new(&xconn)?;
Ok(Dnd {
xconn,
atoms,
version: None,
type_list: None,
source_window: None,
result: None,
})
}
pub fn reset(&mut self) {
self.version = None;
self.type_list = None;
self.source_window = None;
self.result = None;
}
pub unsafe fn send_status(
&self,
this_window: c_ulong,
target_window: c_ulong,
state: DndState,
) -> Result<(), XError> {
let (accepted, action) = match state {
DndState::Accepted => (1, self.atoms.action_private as c_long),
DndState::Rejected => (0, self.atoms.none as c_long),
};
self.xconn.send_client_msg(
target_window,
target_window,
self.atoms.status,
None,
[this_window as c_long, accepted, 0, 0, action],
).flush()
}
pub unsafe fn send_finished(
&self,
this_window: c_ulong,
target_window: c_ulong,
state: DndState,
) -> Result<(), XError> {
let (accepted, action) = match state {
DndState::Accepted => (1, self.atoms.action_private as c_long),
DndState::Rejected => (0, self.atoms.none as c_long),
};
self.xconn.send_client_msg(
target_window,
target_window,
self.atoms.finished,
None,
[this_window as c_long, accepted, action, 0, 0],
).flush()
}
pub unsafe fn get_type_list(
&self,
source_window: c_ulong,
) -> Result<Vec<ffi::Atom>, util::GetPropertyError> {
self.xconn.get_property(
source_window,
self.atoms.type_list,
ffi::XA_ATOM,
)
}
pub unsafe fn convert_selection(&self, window: c_ulong, time: c_ulong) {
(self.xconn.xlib.XConvertSelection)(
self.xconn.display,
self.atoms.selection,
self.atoms.uri_list,
self.atoms.selection,
window,
time,
);
}
pub unsafe fn read_data(
&self,
window: c_ulong,
) -> Result<Vec<c_uchar>, util::GetPropertyError> {
self.xconn.get_property(
window,
self.atoms.selection,
self.atoms.uri_list,
)
}
pub fn parse_data(&self, data: &mut Vec<c_uchar>) -> Result<Vec<PathBuf>, DndDataParseError> {
if !data.is_empty() {
let mut path_list = Vec::new();
let decoded = percent_decode(data).decode_utf8()?.into_owned();
for uri in decoded.split("\r\n").filter(|u| !u.is_empty()) {
// The format is specified as protocol://host/path
// However, it's typically simply protocol:///path
let path_str = if uri.starts_with("file://") {
let path_str = uri.replace("file://", "");
if !path_str.starts_with('/') {
// A hostname is specified
// Supporting this case is beyond the scope of my mental health
return Err(DndDataParseError::HostnameSpecified(path_str));
}
path_str
} else {
// Only the file protocol is supported
return Err(DndDataParseError::UnexpectedProtocol(uri.to_owned()));
};
let path = Path::new(&path_str).canonicalize()?;
path_list.push(path);
}
Ok(path_list)
} else {
Err(DndDataParseError::EmptyData)
}
}
}

28
src/platform/linux/x11/events.rs
View File

@@ -2,8 +2,8 @@ use {events, libc};
use super::ffi;
use VirtualKeyCode;
pub fn keysym_to_element(keysym: libc::c_uint) -> Option<VirtualKeyCode> {
Some(match keysym {
pub fn keycode_to_element(scancode: libc::c_uint) -> Option<VirtualKeyCode> {
Some(match scancode {
ffi::XK_BackSpace => events::VirtualKeyCode::Back,
ffi::XK_Tab => events::VirtualKeyCode::Tab,
//ffi::XK_Linefeed => events::VirtualKeyCode::Linefeed,
@@ -67,19 +67,19 @@ pub fn keysym_to_element(keysym: libc::c_uint) -> Option<VirtualKeyCode> {
//ffi::XK_KP_F2 => events::VirtualKeyCode::Kp_f2,
//ffi::XK_KP_F3 => events::VirtualKeyCode::Kp_f3,
//ffi::XK_KP_F4 => events::VirtualKeyCode::Kp_f4,
ffi::XK_KP_Home => events::VirtualKeyCode::Home,
ffi::XK_KP_Left => events::VirtualKeyCode::Left,
ffi::XK_KP_Up => events::VirtualKeyCode::Up,
ffi::XK_KP_Right => events::VirtualKeyCode::Right,
ffi::XK_KP_Down => events::VirtualKeyCode::Down,
//ffi::XK_KP_Home => events::VirtualKeyCode::Kp_home,
//ffi::XK_KP_Left => events::VirtualKeyCode::NumpadLeft,
//ffi::XK_KP_Up => events::VirtualKeyCode::NumpadUp,
//ffi::XK_KP_Right => events::VirtualKeyCode::NumpadRight,
//ffi::XK_KP_Down => events::VirtualKeyCode::NumpadDown,
//ffi::XK_KP_Prior => events::VirtualKeyCode::Kp_prior,
ffi::XK_KP_Page_Up => events::VirtualKeyCode::PageUp,
//ffi::XK_KP_Page_Up => events::VirtualKeyCode::NumpadPageUp,
//ffi::XK_KP_Next => events::VirtualKeyCode::Kp_next,
ffi::XK_KP_Page_Down => events::VirtualKeyCode::PageDown,
ffi::XK_KP_End => events::VirtualKeyCode::End,
//ffi::XK_KP_Page_Down => events::VirtualKeyCode::NumpadPageDown,
//ffi::XK_KP_End => events::VirtualKeyCode::NumpadEnd,
//ffi::XK_KP_Begin => events::VirtualKeyCode::Kp_begin,
ffi::XK_KP_Insert => events::VirtualKeyCode::Insert,
ffi::XK_KP_Delete => events::VirtualKeyCode::Delete,
//ffi::XK_KP_Insert => events::VirtualKeyCode::NumpadInsert,
//ffi::XK_KP_Delete => events::VirtualKeyCode::NumpadDelete,
ffi::XK_KP_Equal => events::VirtualKeyCode::NumpadEquals,
//ffi::XK_KP_Multiply => events::VirtualKeyCode::NumpadMultiply,
//ffi::XK_KP_Add => events::VirtualKeyCode::NumpadAdd,
@@ -171,7 +171,6 @@ pub fn keysym_to_element(keysym: libc::c_uint) -> Option<VirtualKeyCode> {
//ffi::XK_Super_R => events::VirtualKeyCode::Super_r,
//ffi::XK_Hyper_L => events::VirtualKeyCode::Hyper_l,
//ffi::XK_Hyper_R => events::VirtualKeyCode::Hyper_r,
ffi::XK_ISO_Left_Tab => events::VirtualKeyCode::Tab,
ffi::XK_space => events::VirtualKeyCode::Space,
//ffi::XK_exclam => events::VirtualKeyCode::Exclam,
//ffi::XK_quotedbl => events::VirtualKeyCode::Quotedbl,
@@ -1000,9 +999,6 @@ pub fn keysym_to_element(keysym: libc::c_uint) -> Option<VirtualKeyCode> {
//ffi::XK_Hebrew_switch => events::VirtualKeyCode::Hebrew_switch,
ffi::XF86XK_Back => VirtualKeyCode::NavigateBackward,
ffi::XF86XK_Forward => VirtualKeyCode::NavigateForward,
ffi::XF86XK_Copy => VirtualKeyCode::Copy,
ffi::XF86XK_Paste => VirtualKeyCode::Paste,
ffi::XF86XK_Cut => VirtualKeyCode::Cut,
_ => return None
})
}

2
src/platform/linux/x11/ffi.rs
View File

@@ -1,8 +1,8 @@
pub use x11_dl::keysym::*;
pub use x11_dl::xcursor::*;
pub use x11_dl::xf86vmode::*;
pub use x11_dl::xlib::*;
pub use x11_dl::xinput::*;
pub use x11_dl::xinput2::*;
pub use x11_dl::xlib_xcb::*;
pub use x11_dl::error::OpenError;
pub use x11_dl::xrandr::*;

185
src/platform/linux/x11/ime/callbacks.rs
View File

@@ -1,185 +0,0 @@
use std::ptr;
use std::sync::Arc;
use std::collections::HashMap;
use std::os::raw::c_char;
use super::{ffi, XConnection, XError};
use super::inner::{close_im, ImeInner};
use super::input_method::PotentialInputMethods;
use super::context::{ImeContextCreationError, ImeContext};
pub unsafe fn xim_set_callback(
xconn: &Arc<XConnection>,
xim: ffi::XIM,
field: *const c_char,
callback: *mut ffi::XIMCallback,
) -> Result<(), XError> {
// It's advisable to wrap variadic FFI functions in our own functions, as we want to minimize
// access that isn't type-checked.
(xconn.xlib.XSetIMValues)(
xim,
field,
callback,
ptr::null_mut::<()>(),
);
xconn.check_errors()
}
// Set a callback for when an input method matching the current locale modifiers becomes
// available. Note that this has nothing to do with what input methods are open or able to be
// opened, and simply uses the modifiers that are set when the callback is set.
// * This is called per locale modifier, not per input method opened with that locale modifier.
// * Trying to set this for multiple locale modifiers causes problems, i.e. one of the rebuilt
// input contexts would always silently fail to use the input method.
pub unsafe fn set_instantiate_callback(
xconn: &Arc<XConnection>,
client_data: ffi::XPointer,
) -> Result<(), XError> {
(xconn.xlib.XRegisterIMInstantiateCallback)(
xconn.display,
ptr::null_mut(),
ptr::null_mut(),
ptr::null_mut(),
Some(xim_instantiate_callback),
client_data,
);
xconn.check_errors()
}
pub unsafe fn unset_instantiate_callback(
xconn: &Arc<XConnection>,
client_data: ffi::XPointer,
) -> Result<(), XError> {
(xconn.xlib.XUnregisterIMInstantiateCallback)(
xconn.display,
ptr::null_mut(),
ptr::null_mut(),
ptr::null_mut(),
Some(xim_instantiate_callback),
client_data,
);
xconn.check_errors()
}
pub unsafe fn set_destroy_callback(
xconn: &Arc<XConnection>,
im: ffi::XIM,
inner: &ImeInner,
) -> Result<(), XError> {
xim_set_callback(
&xconn,
im,
ffi::XNDestroyCallback_0.as_ptr() as *const _,
&inner.destroy_callback as *const _ as *mut _,
)
}
#[derive(Debug)]
enum ReplaceImError {
MethodOpenFailed(PotentialInputMethods),
ContextCreationFailed(ImeContextCreationError),
SetDestroyCallbackFailed(XError),
}
// Attempt to replace current IM (which may or may not be presently valid) with a new one. This
// includes replacing all existing input contexts and free'ing resources as necessary. This only
// modifies existing state if all operations succeed.
unsafe fn replace_im(inner: *mut ImeInner) -> Result<(), ReplaceImError> {
let xconn = &(*inner).xconn;
let (new_im, is_fallback) = {
let new_im = (*inner).potential_input_methods.open_im(xconn, None);
let is_fallback = new_im.is_fallback();
(
new_im.ok().ok_or_else(|| {
ReplaceImError::MethodOpenFailed((*inner).potential_input_methods.clone())
})?,
is_fallback,
)
};
// It's important to always set a destroy callback, since there's otherwise potential for us
// to try to use or free a resource that's already been destroyed on the server.
{
let result = set_destroy_callback(xconn, new_im.im, &*inner);
if result.is_err() {
let _ = close_im(xconn, new_im.im);
}
result
}.map_err(ReplaceImError::SetDestroyCallbackFailed)?;
let mut new_contexts = HashMap::new();
for (window, old_context) in (*inner).contexts.iter() {
let spot = old_context.as_ref().map(|old_context| old_context.ic_spot);
let new_context = {
let result = ImeContext::new(
xconn,
new_im.im,
*window,
spot,
);
if result.is_err() {
let _ = close_im(xconn, new_im.im);
}
result.map_err(ReplaceImError::ContextCreationFailed)?
};
new_contexts.insert(*window, Some(new_context));
}
// If we've made it this far, everything succeeded.
let _ = (*inner).destroy_all_contexts_if_necessary();
let _ = (*inner).close_im_if_necessary();
(*inner).im = new_im.im;
(*inner).contexts = new_contexts;
(*inner).is_destroyed = false;
(*inner).is_fallback = is_fallback;
Ok(())
}
pub unsafe extern fn xim_instantiate_callback(
_display: *mut ffi::Display,
client_data: ffi::XPointer,
// This field is unsupplied.
_call_data: ffi::XPointer,
) {
let inner: *mut ImeInner = client_data as _;
if !inner.is_null() {
let xconn = &(*inner).xconn;
let result = replace_im(inner);
if result.is_ok() {
let _ = unset_instantiate_callback(xconn, client_data);
(*inner).is_fallback = false;
} else if result.is_err() && (*inner).is_destroyed {
// We have no usable input methods!
result.expect("Failed to reopen input method");
}
}
}
// This callback is triggered when the input method is closed on the server end. When this
// happens, XCloseIM/XDestroyIC doesn't need to be called, as the resources have already been
// free'd (attempting to do so causes our connection to freeze).
pub unsafe extern fn xim_destroy_callback(
_xim: ffi::XIM,
client_data: ffi::XPointer,
// This field is unsupplied.
_call_data: ffi::XPointer,
) {
let inner: *mut ImeInner = client_data as _;
if !inner.is_null() {
(*inner).is_destroyed = true;
let xconn = &(*inner).xconn;
if !(*inner).is_fallback {
let _ = set_instantiate_callback(xconn, client_data);
// Attempt to open fallback input method.
let result = replace_im(inner);
if result.is_ok() {
(*inner).is_fallback = true;
} else {
// We have no usable input methods!
result.expect("Failed to open fallback input method");
}
}
}
}

134
src/platform/linux/x11/ime/context.rs
View File

@@ -1,134 +0,0 @@
use std::ptr;
use std::sync::Arc;
use std::os::raw::{c_short, c_void};
use super::{ffi, util, XConnection, XError};
#[derive(Debug)]
pub enum ImeContextCreationError {
XError(XError),
Null,
}
unsafe fn create_pre_edit_attr<'a>(
xconn: &'a Arc<XConnection>,
ic_spot: &'a ffi::XPoint,
) -> util::XSmartPointer<'a, c_void> {
util::XSmartPointer::new(
xconn,
(xconn.xlib.XVaCreateNestedList)(
0,
ffi::XNSpotLocation_0.as_ptr() as *const _,
ic_spot,
ptr::null_mut::<()>(),
),
).expect("XVaCreateNestedList returned NULL")
}
// WARNING: this struct doesn't destroy its XIC resource when dropped.
// This is intentional, as it doesn't have enough information to know whether or not the context
// still exists on the server. Since `ImeInner` has that awareness, destruction must be handled
// through `ImeInner`.
#[derive(Debug)]
pub struct ImeContext {
pub ic: ffi::XIC,
pub ic_spot: ffi::XPoint,
}
impl ImeContext {
pub unsafe fn new(
xconn: &Arc<XConnection>,
im: ffi::XIM,
window: ffi::Window,
ic_spot: Option<ffi::XPoint>,
) -> Result<Self, ImeContextCreationError> {
let ic = if let Some(ic_spot) = ic_spot {
ImeContext::create_ic_with_spot(xconn, im, window, ic_spot)
} else {
ImeContext::create_ic(xconn, im, window)
};
let ic = ic.ok_or(ImeContextCreationError::Null)?;
xconn.check_errors().map_err(ImeContextCreationError::XError)?;
Ok(ImeContext {
ic,
ic_spot: ic_spot.unwrap_or_else(|| ffi::XPoint { x: 0, y: 0 }),
})
}
unsafe fn create_ic(
xconn: &Arc<XConnection>,
im: ffi::XIM,
window: ffi::Window,
) -> Option<ffi::XIC> {
let ic = (xconn.xlib.XCreateIC)(
im,
ffi::XNInputStyle_0.as_ptr() as *const _,
ffi::XIMPreeditNothing | ffi::XIMStatusNothing,
ffi::XNClientWindow_0.as_ptr() as *const _,
window,
ptr::null_mut::<()>(),
);
if ic.is_null() {
None
} else {
Some(ic)
}
}
unsafe fn create_ic_with_spot(
xconn: &Arc<XConnection>,
im: ffi::XIM,
window: ffi::Window,
ic_spot: ffi::XPoint,
) -> Option<ffi::XIC> {
let pre_edit_attr = create_pre_edit_attr(xconn, &ic_spot);
let ic = (xconn.xlib.XCreateIC)(
im,
ffi::XNInputStyle_0.as_ptr() as *const _,
ffi::XIMPreeditNothing | ffi::XIMStatusNothing,
ffi::XNClientWindow_0.as_ptr() as *const _,
window,
ffi::XNPreeditAttributes_0.as_ptr() as *const _,
pre_edit_attr.ptr,
ptr::null_mut::<()>(),
);
if ic.is_null() {
None
} else {
Some(ic)
}
}
pub fn focus(&self, xconn: &Arc<XConnection>) -> Result<(), XError> {
unsafe {
(xconn.xlib.XSetICFocus)(self.ic);
}
xconn.check_errors()
}
pub fn unfocus(&self, xconn: &Arc<XConnection>) -> Result<(), XError> {
unsafe {
(xconn.xlib.XUnsetICFocus)(self.ic);
}
xconn.check_errors()
}
pub fn set_spot(&mut self, xconn: &Arc<XConnection>, x: c_short, y: c_short) {
if self.ic_spot.x == x && self.ic_spot.y == y {
return;
}
self.ic_spot = ffi::XPoint { x, y };
unsafe {
let pre_edit_attr = create_pre_edit_attr(xconn, &self.ic_spot);
(xconn.xlib.XSetICValues)(
self.ic,
ffi::XNPreeditAttributes_0.as_ptr() as *const _,
pre_edit_attr.ptr,
ptr::null_mut::<()>(),
);
}
}
}

75
src/platform/linux/x11/ime/inner.rs
View File

@@ -1,75 +0,0 @@
use std::mem;
use std::ptr;
use std::sync::Arc;
use std::collections::HashMap;
use super::{ffi, XConnection, XError};
use super::input_method::PotentialInputMethods;
use super::context::ImeContext;
pub unsafe fn close_im(xconn: &Arc<XConnection>, im: ffi::XIM) -> Result<(), XError> {
(xconn.xlib.XCloseIM)(im);
xconn.check_errors()
}
pub unsafe fn destroy_ic(xconn: &Arc<XConnection>, ic: ffi::XIC) -> Result<(), XError> {
(xconn.xlib.XDestroyIC)(ic);
xconn.check_errors()
}
pub struct ImeInner {
pub xconn: Arc<XConnection>,
// WARNING: this is initially null!
pub im: ffi::XIM,
pub potential_input_methods: PotentialInputMethods,
pub contexts: HashMap<ffi::Window, Option<ImeContext>>,
// WARNING: this is initially zeroed!
pub destroy_callback: ffi::XIMCallback,
// Indicates whether or not the the input method was destroyed on the server end
// (i.e. if ibus/fcitx/etc. was terminated/restarted)
pub is_destroyed: bool,
pub is_fallback: bool,
}
impl ImeInner {
pub fn new(
xconn: Arc<XConnection>,
potential_input_methods: PotentialInputMethods,
) -> Self {
ImeInner {
xconn,
im: ptr::null_mut(),
potential_input_methods,
contexts: HashMap::new(),
destroy_callback: unsafe { mem::zeroed() },
is_destroyed: false,
is_fallback: false,
}
}
pub unsafe fn close_im_if_necessary(&self) -> Result<bool, XError> {
if !self.is_destroyed {
close_im(&self.xconn, self.im).map(|_| true)
} else {
Ok(false)
}
}
pub unsafe fn destroy_ic_if_necessary(&self, ic: ffi::XIC) -> Result<bool, XError> {
if !self.is_destroyed {
destroy_ic(&self.xconn, ic).map(|_| true)
} else {
Ok(false)
}
}
pub unsafe fn destroy_all_contexts_if_necessary(&self) -> Result<bool, XError> {
for context in self.contexts.values() {
if let &Some(ref context) = context {
self.destroy_ic_if_necessary(context.ic)?;
}
}
Ok(!self.is_destroyed)
}
}

283
src/platform/linux/x11/ime/input_method.rs
View File

@@ -1,283 +0,0 @@
use std::env;
use std::fmt;
use std::ptr;
use std::sync::Arc;
use std::os::raw::c_char;
use std::ffi::{CStr, CString, IntoStringError};
use parking_lot::Mutex;
use super::{ffi, util, XConnection, XError};
lazy_static! {
static ref GLOBAL_LOCK: Mutex<()> = Default::default();
}
unsafe fn open_im(
xconn: &Arc<XConnection>,
locale_modifiers: &CStr,
) -> Option<ffi::XIM> {
let _lock = GLOBAL_LOCK.lock();
// XSetLocaleModifiers returns...
// * The current locale modifiers if it's given a NULL pointer.
// * The new locale modifiers if we succeeded in setting them.
// * NULL if the locale modifiers string is malformed.
(xconn.xlib.XSetLocaleModifiers)(locale_modifiers.as_ptr());
let im = (xconn.xlib.XOpenIM)(
xconn.display,
ptr::null_mut(),
ptr::null_mut(),
ptr::null_mut(),
);
if im.is_null() {
None
} else {
Some(im)
}
}
#[derive(Debug)]
pub struct InputMethod {
pub im: ffi::XIM,
name: String,
}
impl InputMethod {
fn new(im: ffi::XIM, name: String) -> Self {
InputMethod { im, name }
}
}
#[derive(Debug)]
pub enum InputMethodResult {
/// Input method used locale modifier from `XMODIFIERS` environment variable.
XModifiers(InputMethod),
/// Input method used internal fallback locale modifier.
Fallback(InputMethod),
/// Input method could not be opened using any locale modifier tried.
Failure,
}
impl InputMethodResult {
pub fn is_fallback(&self) -> bool {
if let &InputMethodResult::Fallback(_) = self {
true
} else {
false
}
}
pub fn ok(self) -> Option<InputMethod> {
use self::InputMethodResult::*;
match self {
XModifiers(im) | Fallback(im) => Some(im),
Failure => None,
}
}
}
#[derive(Debug, Clone)]
enum GetXimServersError {
XError(XError),
GetPropertyError(util::GetPropertyError),
InvalidUtf8(IntoStringError),
}
// The root window has a property named XIM_SERVERS, which contains a list of atoms represeting
// the availabile XIM servers. For instance, if you're using ibus, it would contain an atom named
// "@server=ibus". It's possible for this property to contain multiple atoms, though presumably
// rare. Note that we replace "@server=" with "@im=" in order to match the format of locale
// modifiers, since we don't want a user who's looking at logs to ask "am I supposed to set
// XMODIFIERS to `@server=ibus`?!?"
unsafe fn get_xim_servers(xconn: &Arc<XConnection>) -> Result<Vec<String>, GetXimServersError> {
let servers_atom = xconn.get_atom_unchecked(b"XIM_SERVERS\0");
let root = (xconn.xlib.XDefaultRootWindow)(xconn.display);
let mut atoms: Vec<ffi::Atom> = xconn.get_property(
root,
servers_atom,
ffi::XA_ATOM,
).map_err(GetXimServersError::GetPropertyError)?;
let mut names: Vec<*const c_char> = Vec::with_capacity(atoms.len());
(xconn.xlib.XGetAtomNames)(
xconn.display,
atoms.as_mut_ptr(),
atoms.len() as _,
names.as_mut_ptr() as _,
);
names.set_len(atoms.len());
let mut formatted_names = Vec::with_capacity(names.len());
for name in names {
let string = CStr::from_ptr(name)
.to_owned()
.into_string()
.map_err(GetXimServersError::InvalidUtf8)?;
(xconn.xlib.XFree)(name as _);
formatted_names.push(string.replace("@server=", "@im="));
}
xconn.check_errors().map_err(GetXimServersError::XError)?;
Ok(formatted_names)
}
#[derive(Clone)]
struct InputMethodName {
c_string: CString,
string: String,
}
impl InputMethodName {
pub fn from_string(string: String) -> Self {
let c_string = CString::new(string.clone())
.expect("String used to construct CString contained null byte");
InputMethodName {
c_string,
string,
}
}
pub fn from_str(string: &str) -> Self {
let c_string = CString::new(string)
.expect("String used to construct CString contained null byte");
InputMethodName {
c_string,
string: string.to_owned(),
}
}
}
impl fmt::Debug for InputMethodName {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
self.string.fmt(f)
}
}
#[derive(Debug, Clone)]
struct PotentialInputMethod {
name: InputMethodName,
successful: Option<bool>,
}
impl PotentialInputMethod {
pub fn from_string(string: String) -> Self {
PotentialInputMethod {
name: InputMethodName::from_string(string),
successful: None,
}
}
pub fn from_str(string: &str) -> Self {
PotentialInputMethod {
name: InputMethodName::from_str(string),
successful: None,
}
}
pub fn reset(&mut self) {
self.successful = None;
}
pub fn open_im(&mut self, xconn: &Arc<XConnection>) -> Option<InputMethod> {
let im = unsafe { open_im(xconn, &self.name.c_string) };
self.successful = Some(im.is_some());
im.map(|im| InputMethod::new(im, self.name.string.clone()))
}
}
// By logging this struct, you get a sequential listing of every locale modifier tried, where it
// came from, and if it succceeded.
#[derive(Debug, Clone)]
pub struct PotentialInputMethods {
// On correctly configured systems, the XMODIFIERS environemnt variable tells us everything we
// need to know.
xmodifiers: Option<PotentialInputMethod>,
// We have some standard options at our disposal that should ostensibly always work. For users
// who only need compose sequences, this ensures that the program launches without a hitch
// For users who need more sophisticated IME features, this is more or less a silent failure.
// Logging features should be added in the future to allow both audiences to be effectively
// served.
fallbacks: [PotentialInputMethod; 2],
// For diagnostic purposes, we include the list of XIM servers that the server reports as
// being available.
_xim_servers: Result<Vec<String>, GetXimServersError>,
}
impl PotentialInputMethods {
pub fn new(xconn: &Arc<XConnection>) -> Self {
let xmodifiers = env::var("XMODIFIERS")
.ok()
.map(PotentialInputMethod::from_string);
PotentialInputMethods {
// Since passing "" to XSetLocaleModifiers results in it defaulting to the value of
// XMODIFIERS, it's worth noting what happens if XMODIFIERS is also "". If simply
// running the program with `XMODIFIERS="" cargo run`, then assuming XMODIFIERS is
// defined in the profile (or parent environment) then that parent XMODIFIERS is used.
// If that XMODIFIERS value is also "" (i.e. if you ran `export XMODIFIERS=""`), then
// XSetLocaleModifiers uses the default local input method. Note that defining
// XMODIFIERS as "" is different from XMODIFIERS not being defined at all, since in
// that case, we get `None` and end up skipping ahead to the next method.
xmodifiers,
fallbacks: [
// This is a standard input method that supports compose equences, which should
// always be available. `@im=none` appears to mean the same thing.
PotentialInputMethod::from_str("@im=local"),
// This explicitly specifies to use the implementation-dependent default, though
// that seems to be equivalent to just using the local input method.
PotentialInputMethod::from_str("@im="),
],
// The XIM_SERVERS property can have surprising values. For instance, when I exited
// ibus to run fcitx, it retained the value denoting ibus. Even more surprising is
// that the fcitx input method could only be successfully opened using "@im=ibus".
// Presumably due to this quirk, it's actually possible to alternate between ibus and
// fcitx in a running application.
_xim_servers: unsafe { get_xim_servers(xconn) },
}
}
// This resets the `successful` field of every potential input method, ensuring we have
// accurate information when this struct is re-used by the destruction/instantiation callbacks.
fn reset(&mut self) {
if let Some(ref mut input_method) = self.xmodifiers {
input_method.reset();
}
for input_method in &mut self.fallbacks {
input_method.reset();
}
}
pub fn open_im(
&mut self,
xconn: &Arc<XConnection>,
callback: Option<&Fn() -> ()>,
) -> InputMethodResult {
use self::InputMethodResult::*;
self.reset();
if let Some(ref mut input_method) = self.xmodifiers {
let im = input_method.open_im(xconn);
if let Some(im) = im {
return XModifiers(im);
} else {
if let Some(ref callback) = callback {
callback();
}
}
}
for input_method in &mut self.fallbacks {
let im = input_method.open_im(xconn);
if let Some(im) = im {
return Fallback(im);
}
}
Failure
}
}

165
src/platform/linux/x11/ime/mod.rs
View File

@@ -1,165 +0,0 @@
// Important: all XIM calls need to happen from the same thread!
mod inner;
mod input_method;
mod context;
mod callbacks;
use std::sync::Arc;
use std::sync::mpsc::{Receiver, Sender};
use super::{ffi, util, XConnection, XError};
use self::inner::{close_im, ImeInner};
use self::input_method::PotentialInputMethods;
use self::context::{ImeContextCreationError, ImeContext};
use self::callbacks::*;
pub type ImeReceiver = Receiver<(ffi::Window, i16, i16)>;
pub type ImeSender = Sender<(ffi::Window, i16, i16)>;
#[derive(Debug)]
pub enum ImeCreationError {
OpenFailure(PotentialInputMethods),
SetDestroyCallbackFailed(XError),
}
pub struct Ime {
xconn: Arc<XConnection>,
// The actual meat of this struct is boxed away, since it needs to have a fixed location in
// memory so we can pass a pointer to it around.
inner: Box<ImeInner>,
}
impl Ime {
pub fn new(xconn: Arc<XConnection>) -> Result<Self, ImeCreationError> {
let potential_input_methods = PotentialInputMethods::new(&xconn);
let (mut inner, client_data) = {
let mut inner = Box::new(ImeInner::new(
xconn,
potential_input_methods,
));
let inner_ptr = Box::into_raw(inner);
let client_data = inner_ptr as _;
let destroy_callback = ffi::XIMCallback {
client_data,
callback: Some(xim_destroy_callback),
};
inner = unsafe { Box::from_raw(inner_ptr) };
inner.destroy_callback = destroy_callback;
(inner, client_data)
};
let xconn = Arc::clone(&inner.xconn);
let input_method = inner.potential_input_methods.open_im(&xconn, Some(&|| {
let _ = unsafe { set_instantiate_callback(&xconn, client_data) };
}));
let is_fallback = input_method.is_fallback();
if let Some(input_method) = input_method.ok() {
inner.im = input_method.im;
inner.is_fallback = is_fallback;
unsafe {
let result = set_destroy_callback(&xconn, input_method.im, &*inner)
.map_err(ImeCreationError::SetDestroyCallbackFailed);
if result.is_err() {
let _ = close_im(&xconn, input_method.im);
}
result?;
}
Ok(Ime { xconn, inner })
} else {
Err(ImeCreationError::OpenFailure(inner.potential_input_methods))
}
}
pub fn is_destroyed(&self) -> bool {
self.inner.is_destroyed
}
// This pattern is used for various methods here:
// Ok(_) indicates that nothing went wrong internally
// Ok(true) indicates that the action was actually performed
// Ok(false) indicates that the action is not presently applicable
pub fn create_context(&mut self, window: ffi::Window)
-> Result<bool, ImeContextCreationError>
{
let context = if self.is_destroyed() {
// Create empty entry in map, so that when IME is rebuilt, this window has a context.
None
} else {
Some(unsafe { ImeContext::new(
&self.inner.xconn,
self.inner.im,
window,
None,
) }?)
};
self.inner.contexts.insert(window, context);
Ok(!self.is_destroyed())
}
pub fn get_context(&self, window: ffi::Window) -> Option<ffi::XIC> {
if self.is_destroyed() {
return None;
}
if let Some(&Some(ref context)) = self.inner.contexts.get(&window) {
Some(context.ic)
} else {
None
}
}
pub fn remove_context(&mut self, window: ffi::Window) -> Result<bool, XError> {
if let Some(Some(context)) = self.inner.contexts.remove(&window) {
unsafe {
self.inner.destroy_ic_if_necessary(context.ic)?;
}
Ok(true)
} else {
Ok(false)
}
}
pub fn focus(&mut self, window: ffi::Window) -> Result<bool, XError> {
if self.is_destroyed() {
return Ok(false);
}
if let Some(&mut Some(ref mut context)) = self.inner.contexts.get_mut(&window) {
context.focus(&self.xconn).map(|_| true)
} else {
Ok(false)
}
}
pub fn unfocus(&mut self, window: ffi::Window) -> Result<bool, XError> {
if self.is_destroyed() {
return Ok(false);
}
if let Some(&mut Some(ref mut context)) = self.inner.contexts.get_mut(&window) {
context.unfocus(&self.xconn).map(|_| true)
} else {
Ok(false)
}
}
pub fn send_xim_spot(&mut self, window: ffi::Window, x: i16, y: i16) {
if self.is_destroyed() {
return;
}
if let Some(&mut Some(ref mut context)) = self.inner.contexts.get_mut(&window) {
context.set_spot(&self.xconn, x as _, y as _);
}
}
}
impl Drop for Ime {
fn drop(&mut self) {
unsafe {
let _ = self.inner.destroy_all_contexts_if_necessary();
let _ = self.inner.close_im_if_necessary();
}
}
}

391
src/platform/linux/x11/input.rs Normal file
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@@ -0,0 +1,391 @@
use std::sync::Arc;
use libc;
use std::{mem, ptr};
use std::ffi::CString;
use std::slice::from_raw_parts;
use WindowAttributes;
use events::WindowEvent as Event;
use events::ModifiersState;
use super::{events, ffi};
use super::XConnection;
#[derive(Debug)]
enum AxisType {
HorizontalScroll,
VerticalScroll
}
#[derive(Debug)]
struct Axis {
id: i32,
device_id: i32,
axis_number: i32,
axis_type: AxisType,
scroll_increment: f64,
}
#[derive(Debug)]
struct AxisValue {
device_id: i32,
axis_number: i32,
value: f64
}
struct InputState {
/// Last-seen cursor position within a window in (x, y)
/// coordinates
cursor_pos: (f64, f64),
/// Last-seen positions of axes, used to report delta
/// movements when a new absolute axis value is received
axis_values: Vec<AxisValue>
}
pub struct XInputEventHandler {
display: Arc<XConnection>,
window: ffi::Window,
ic: ffi::XIC,
axis_list: Vec<Axis>,
current_state: InputState,
multitouch: bool,
}
impl XInputEventHandler {
pub fn new(display: &Arc<XConnection>, window: ffi::Window, ic: ffi::XIC,
window_attrs: &WindowAttributes) -> XInputEventHandler {
// query XInput support
let mut opcode: libc::c_int = 0;
let mut event: libc::c_int = 0;
let mut error: libc::c_int = 0;
let xinput_str = CString::new("XInputExtension").unwrap();
unsafe {
if (display.xlib.XQueryExtension)(display.display, xinput_str.as_ptr(), &mut opcode, &mut event, &mut error) == ffi::False {
panic!("XInput not available")
}
}
let mut xinput_major_ver = ffi::XI_2_Major;
let mut xinput_minor_ver = ffi::XI_2_Minor;
unsafe {
if (display.xinput2.XIQueryVersion)(display.display, &mut xinput_major_ver, &mut xinput_minor_ver) != ffi::Success as libc::c_int {
panic!("Unable to determine XInput version");
}
}
// specify the XInput events we want to receive.
// Button clicks and mouse events are handled via XInput
// events. Key presses are still handled via plain core
// X11 events.
let mut mask: [libc::c_uchar; 3] = [0; 3];
let mut input_event_mask = ffi::XIEventMask {
deviceid: ffi::XIAllMasterDevices,
mask_len: mask.len() as i32,
mask: mask.as_mut_ptr()
};
let events = &[
ffi::XI_ButtonPress,
ffi::XI_ButtonRelease,
ffi::XI_Motion,
ffi::XI_Enter,
ffi::XI_Leave,
ffi::XI_FocusIn,
ffi::XI_FocusOut,
ffi::XI_TouchBegin,
ffi::XI_TouchUpdate,
ffi::XI_TouchEnd,
];
for event in events {
ffi::XISetMask(&mut mask, *event);
}
unsafe {
match (display.xinput2.XISelectEvents)(display.display, window, &mut input_event_mask, 1) {
status if status as u8 == ffi::Success => (),
err => panic!("Failed to select events {:?}", err)
}
}
XInputEventHandler {
display: display.clone(),
window: window,
ic: ic,
axis_list: read_input_axis_info(display),
current_state: InputState {
cursor_pos: (0.0, 0.0),
axis_values: Vec::new()
},
multitouch: window_attrs.multitouch,
}
}
pub fn translate_key_event(&self, event: &mut ffi::XKeyEvent) -> Vec<Event> {
use events::WindowEvent::{KeyboardInput, ReceivedCharacter};
use events::ElementState::{Pressed, Released};
let mut translated_events = Vec::new();
let state;
if event.type_ == ffi::KeyPress {
let raw_ev: *mut ffi::XKeyEvent = event;
unsafe { (self.display.xlib.XFilterEvent)(mem::transmute(raw_ev), self.window) };
state = Pressed;
} else {
state = Released;
}
let mut kp_keysym = 0;
let mut ev_mods = ModifiersState::default();
let written = unsafe {
use std::str;
let mut buffer: [u8; 16] = [mem::uninitialized(); 16];
let raw_ev: *mut ffi::XKeyEvent = event;
let count = (self.display.xlib.Xutf8LookupString)(self.ic, mem::transmute(raw_ev),
mem::transmute(buffer.as_mut_ptr()),
buffer.len() as libc::c_int, &mut kp_keysym, ptr::null_mut());
{
// Translate x event state to mods
let state = event.state;
if (state & ffi::Mod1Mask) != 0 {
ev_mods.alt = true;
}
if (state & ffi::ShiftMask) != 0 {
ev_mods.shift = true;
}
if (state & ffi::ControlMask) != 0 {
ev_mods.ctrl = true;
}
if (state & ffi::Mod4Mask) != 0 {
ev_mods.logo = true;
}
}
str::from_utf8(&buffer[..count as usize]).unwrap_or("").to_string()
};
for chr in written.chars() {
translated_events.push(ReceivedCharacter(chr));
}
let mut keysym = unsafe {
(self.display.xlib.XKeycodeToKeysym)(self.display.display, event.keycode as ffi::KeyCode, 0)
};
if (ffi::XK_KP_Space as libc::c_ulong <= keysym) && (keysym <= ffi::XK_KP_9 as libc::c_ulong) {
keysym = kp_keysym
};
let vkey = events::keycode_to_element(keysym as libc::c_uint);
translated_events.push(KeyboardInput(state, event.keycode as u8, vkey, ev_mods));
translated_events
}
pub fn translate_event(&mut self, cookie: &ffi::XGenericEventCookie) -> Option<Event> {
use events::WindowEvent::{Focused, MouseEntered, MouseInput, MouseLeft, MouseMoved, MouseWheel};
use events::ElementState::{Pressed, Released};
use events::MouseButton::{Left, Right, Middle};
use events::MouseScrollDelta::LineDelta;
use events::{Touch, TouchPhase};
match cookie.evtype {
ffi::XI_ButtonPress | ffi::XI_ButtonRelease => {
let event_data: &ffi::XIDeviceEvent = unsafe{mem::transmute(cookie.data)};
if self.multitouch && (event_data.flags & ffi::XIPointerEmulated) != 0 {
// Deliver multi-touch events instead of emulated mouse events.
return None
}
let state = if cookie.evtype == ffi::XI_ButtonPress {
Pressed
} else {
Released
};
match event_data.detail as u32 {
ffi::Button1 => Some(MouseInput(state, Left)),
ffi::Button2 => Some(MouseInput(state, Middle)),
ffi::Button3 => Some(MouseInput(state, Right)),
ffi::Button4 | ffi::Button5 => {
if event_data.flags & ffi::XIPointerEmulated == 0 {
// scroll event from a traditional wheel with
// distinct 'clicks'
let delta = if event_data.detail as u32 == ffi::Button4 {
1.0
} else {
-1.0
};
Some(MouseWheel(LineDelta(0.0, delta), TouchPhase::Moved))
} else {
// emulated button event from a touch/smooth-scroll
// event. Ignore these events and handle scrolling
// via XI_Motion event handler instead
None
}
}
_ => None
}
},
ffi::XI_Motion => {
let event_data: &ffi::XIDeviceEvent = unsafe{mem::transmute(cookie.data)};
if self.multitouch && (event_data.flags & ffi::XIPointerEmulated) != 0 {
// Deliver multi-touch events instead of emulated mouse events.
return None
}
let axis_state = event_data.valuators;
let mask = unsafe{ from_raw_parts(axis_state.mask, axis_state.mask_len as usize) };
let mut axis_count = 0;
let mut scroll_delta = (0.0, 0.0);
for axis_id in 0..axis_state.mask_len {
if ffi::XIMaskIsSet(&mask, axis_id) {
let axis_value = unsafe{*axis_state.values.offset(axis_count)};
let delta = calc_scroll_deltas(event_data, axis_id, axis_value, &self.axis_list,
&mut self.current_state.axis_values);
scroll_delta.0 += delta.0;
scroll_delta.1 += delta.1;
axis_count += 1;
}
}
if scroll_delta.0.abs() > 0.0 || scroll_delta.1.abs() > 0.0 {
Some(MouseWheel(LineDelta(scroll_delta.0 as f32, scroll_delta.1 as f32),
TouchPhase::Moved))
} else {
let new_cursor_pos = (event_data.event_x, event_data.event_y);
if new_cursor_pos != self.current_state.cursor_pos {
self.current_state.cursor_pos = new_cursor_pos;
Some(MouseMoved(new_cursor_pos.0 as i32, new_cursor_pos.1 as i32))
} else {
None
}
}
},
ffi::XI_Enter => {
// axis movements whilst the cursor is outside the window
// will alter the absolute value of the axes. We only want to
// report changes in the axis value whilst the cursor is above
// our window however, so clear the previous axis state whenever
// the cursor re-enters the window
self.current_state.axis_values.clear();
Some(MouseEntered)
},
ffi::XI_Leave => Some(MouseLeft),
ffi::XI_FocusIn => Some(Focused(true)),
ffi::XI_FocusOut => Some(Focused(false)),
ffi::XI_TouchBegin | ffi::XI_TouchUpdate | ffi::XI_TouchEnd => {
if !self.multitouch {
return None
}
let event_data: &ffi::XIDeviceEvent = unsafe{mem::transmute(cookie.data)};
let phase = match cookie.evtype {
ffi::XI_TouchBegin => TouchPhase::Started,
ffi::XI_TouchUpdate => TouchPhase::Moved,
ffi::XI_TouchEnd => TouchPhase::Ended,
_ => unreachable!()
};
Some(Event::Touch(Touch {
phase: phase,
location: (event_data.event_x, event_data.event_y),
id: event_data.detail as u64,
}))
}
_ => None
}
}
}
fn read_input_axis_info(display: &Arc<XConnection>) -> Vec<Axis> {
let mut axis_list = Vec::new();
let mut device_count = 0;
// Check all input devices for scroll axes.
let devices = unsafe{
(display.xinput2.XIQueryDevice)(display.display, ffi::XIAllDevices, &mut device_count)
};
for i in 0..device_count {
let device = unsafe { *(devices.offset(i as isize)) };
for k in 0..device.num_classes {
let class = unsafe { *(device.classes.offset(k as isize)) };
match unsafe { (*class)._type } {
// Note that scroll axis
// are reported both as 'XIScrollClass' and 'XIValuatorClass'
// axes. For the moment we only care about scrolling axes.
ffi::XIScrollClass => {
let scroll_class: &ffi::XIScrollClassInfo = unsafe{mem::transmute(class)};
axis_list.push(Axis{
id: scroll_class.sourceid,
device_id: device.deviceid,
axis_number: scroll_class.number,
axis_type: match scroll_class.scroll_type {
ffi::XIScrollTypeHorizontal => AxisType::HorizontalScroll,
ffi::XIScrollTypeVertical => AxisType::VerticalScroll,
_ => { unreachable!() }
},
scroll_increment: scroll_class.increment,
})
},
_ => {}
}
}
}
unsafe {
(display.xinput2.XIFreeDeviceInfo)(devices);
}
axis_list
}
/// Given an input motion event for an axis and the previous
/// state of the axes, return the horizontal/vertical
/// scroll deltas
fn calc_scroll_deltas(event: &ffi::XIDeviceEvent,
axis_id: i32,
axis_value: f64,
axis_list: &[Axis],
prev_axis_values: &mut Vec<AxisValue>) -> (f64, f64) {
let prev_value_pos = prev_axis_values.iter().position(|prev_axis| {
prev_axis.device_id == event.sourceid &&
prev_axis.axis_number == axis_id
});
let delta = match prev_value_pos {
Some(idx) => prev_axis_values[idx].value - axis_value,
None => 0.0
};
let new_axis_value = AxisValue{
device_id: event.sourceid,
axis_number: axis_id,
value: axis_value
};
match prev_value_pos {
Some(idx) => prev_axis_values[idx] = new_axis_value,
None => prev_axis_values.push(new_axis_value)
}
let mut scroll_delta = (0.0, 0.0);
for axis in axis_list.iter() {
if axis.id == event.sourceid &&
axis.axis_number == axis_id {
match axis.axis_type {
AxisType::HorizontalScroll => scroll_delta.0 = delta / axis.scroll_increment,
AxisType::VerticalScroll => scroll_delta.1 = delta / axis.scroll_increment
}
}
}
scroll_delta
}

1456
src/platform/linux/x11/mod.rs
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File diff suppressed because it is too large Load Diff

279
src/platform/linux/x11/monitor.rs
View File

@@ -1,269 +1,44 @@
use std::os::raw::*;
use std::collections::VecDeque;
use std::sync::Arc;
use parking_lot::Mutex;
use super::XConnection;
use native_monitor::NativeMonitorId;
use {PhysicalPosition, PhysicalSize};
use super::{util, XConnection, XError};
use super::ffi::{
RRCrtcChangeNotifyMask,
RROutputPropertyNotifyMask,
RRScreenChangeNotifyMask,
True,
Window,
XRRScreenResources,
};
#[derive(Clone)]
pub struct MonitorId(pub Arc<XConnection>, pub u32);
// Used to test XRandR < 1.5 code path. This should always be committed as false.
const FORCE_RANDR_COMPAT: bool = false;
// Also used for testing. This should always be committed as false.
const DISABLE_MONITOR_LIST_CACHING: bool = false;
pub fn get_available_monitors(x: &Arc<XConnection>) -> VecDeque<MonitorId> {
let nb_monitors = unsafe { (x.xlib.XScreenCount)(x.display) };
x.check_errors().expect("Failed to call XScreenCount");
lazy_static! {
static ref XRANDR_VERSION: Mutex<Option<(c_int, c_int)>> = Mutex::default();
static ref MONITORS: Mutex<Option<Vec<MonitorId>>> = Mutex::default();
let mut monitors = VecDeque::new();
monitors.extend((0 .. nb_monitors).map(|i| MonitorId(x.clone(), i as u32)));
monitors
}
fn version_is_at_least(major: c_int, minor: c_int) -> bool {
if let Some((avail_major, avail_minor)) = *XRANDR_VERSION.lock() {
if avail_major == major {
avail_minor >= minor
} else {
avail_major > major
}
} else {
unreachable!();
}
}
pub fn invalidate_cached_monitor_list() -> Option<Vec<MonitorId>> {
// We update this lazily.
(*MONITORS.lock()).take()
}
#[derive(Debug, Clone)]
pub struct MonitorId {
/// The actual id
id: u32,
/// The name of the monitor
pub(crate) name: String,
/// The size of the monitor
dimensions: (u32, u32),
/// The position of the monitor in the X screen
position: (i32, i32),
/// If the monitor is the primary one
primary: bool,
/// The DPI scale factor
pub(crate) hidpi_factor: f64,
/// Used to determine which windows are on this monitor
pub(crate) rect: util::AaRect,
#[inline]
pub fn get_primary_monitor(x: &Arc<XConnection>) -> MonitorId {
let primary_monitor = unsafe { (x.xlib.XDefaultScreen)(x.display) };
x.check_errors().expect("Failed to call XDefaultScreen");
MonitorId(x.clone(), primary_monitor as u32)
}
impl MonitorId {
fn from_repr(
xconn: &XConnection,
resources: *mut XRRScreenResources,
id: u32,
repr: util::MonitorRepr,
primary: bool,
) -> Self {
let (name, hidpi_factor) = unsafe { xconn.get_output_info(resources, &repr) };
let (dimensions, position) = unsafe { (repr.get_dimensions(), repr.get_position()) };
let rect = util::AaRect::new(position, dimensions);
MonitorId {
id,
name,
hidpi_factor,
dimensions,
position,
primary,
rect,
}
}
pub fn get_name(&self) -> Option<String> {
Some(self.name.clone())
let MonitorId(_, screen_num) = *self;
Some(format!("Monitor #{}", screen_num))
}
#[inline]
pub fn get_native_identifier(&self) -> u32 {
self.id as u32
pub fn get_native_identifier(&self) -> NativeMonitorId {
NativeMonitorId::Numeric(self.1)
}
pub fn get_dimensions(&self) -> PhysicalSize {
self.dimensions.into()
}
pub fn get_position(&self) -> PhysicalPosition {
self.position.into()
}
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
self.hidpi_factor
}
}
impl XConnection {
pub fn get_monitor_for_window(&self, window_rect: Option<util::AaRect>) -> MonitorId {
let monitors = self.get_available_monitors();
let default = monitors
.get(0)
.expect("[winit] Failed to find any monitors using XRandR.");
let window_rect = match window_rect {
Some(rect) => rect,
None => return default.to_owned(),
};
let mut largest_overlap = 0;
let mut matched_monitor = default;
for monitor in &monitors {
let overlapping_area = window_rect.get_overlapping_area(&monitor.rect);
if overlapping_area > largest_overlap {
largest_overlap = overlapping_area;
matched_monitor = &monitor;
}
}
matched_monitor.to_owned()
}
fn query_monitor_list(&self) -> Vec<MonitorId> {
unsafe {
let root = (self.xlib.XDefaultRootWindow)(self.display);
// WARNING: this function is supposedly very slow, on the order of hundreds of ms.
// Upon failure, `resources` will be null.
let resources = (self.xrandr.XRRGetScreenResources)(self.display, root);
if resources.is_null() {
panic!("[winit] `XRRGetScreenResources` returned NULL. That should only happen if the root window doesn't exist.");
}
let mut available;
let mut has_primary = false;
if self.xrandr_1_5.is_some() && version_is_at_least(1, 5) && !FORCE_RANDR_COMPAT {
// We're in XRandR >= 1.5, enumerate monitors. This supports things like MST and
// videowalls.
let xrandr_1_5 = self.xrandr_1_5.as_ref().unwrap();
let mut monitor_count = 0;
let monitors = (xrandr_1_5.XRRGetMonitors)(self.display, root, 1, &mut monitor_count);
assert!(monitor_count >= 0);
available = Vec::with_capacity(monitor_count as usize);
for monitor_index in 0..monitor_count {
let monitor = monitors.offset(monitor_index as isize);
let is_primary = (*monitor).primary != 0;
has_primary |= is_primary;
available.push(MonitorId::from_repr(
self,
resources,
monitor_index as u32,
monitor.into(),
is_primary,
));
}
(xrandr_1_5.XRRFreeMonitors)(monitors);
} else {
// We're in XRandR < 1.5, enumerate CRTCs. Everything will work except MST and
// videowall setups will also show monitors that aren't in the logical groups the user
// cares about.
let primary = (self.xrandr.XRRGetOutputPrimary)(self.display, root);
available = Vec::with_capacity((*resources).ncrtc as usize);
for crtc_index in 0..(*resources).ncrtc {
let crtc_id = *((*resources).crtcs.offset(crtc_index as isize));
let crtc = (self.xrandr.XRRGetCrtcInfo)(self.display, resources, crtc_id);
let is_active = (*crtc).width > 0 && (*crtc).height > 0 && (*crtc).noutput > 0;
if is_active {
let crtc = util::MonitorRepr::from(crtc);
let is_primary = crtc.get_output() == primary;
has_primary |= is_primary;
available.push(MonitorId::from_repr(
self,
resources,
crtc_id as u32,
crtc,
is_primary,
));
}
(self.xrandr.XRRFreeCrtcInfo)(crtc);
}
}
// If no monitors were detected as being primary, we just pick one ourselves!
if !has_primary {
if let Some(ref mut fallback) = available.first_mut() {
// Setting this here will come in handy if we ever add an `is_primary` method.
fallback.primary = true;
}
}
(self.xrandr.XRRFreeScreenResources)(resources);
available
}
}
pub fn get_available_monitors(&self) -> Vec<MonitorId> {
let mut monitors_lock = MONITORS.lock();
(*monitors_lock)
.as_ref()
.cloned()
.or_else(|| {
let monitors = Some(self.query_monitor_list());
if !DISABLE_MONITOR_LIST_CACHING {
(*monitors_lock) = monitors.clone();
}
monitors
})
.unwrap()
}
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
self.get_available_monitors()
.into_iter()
.find(|monitor| monitor.primary)
.expect("[winit] Failed to find any monitors using XRandR.")
}
pub fn select_xrandr_input(&self, root: Window) -> Result<c_int, XError> {
{
let mut version_lock = XRANDR_VERSION.lock();
if version_lock.is_none() {
let mut major = 0;
let mut minor = 0;
let has_extension = unsafe {
(self.xrandr.XRRQueryVersion)(
self.display,
&mut major,
&mut minor,
)
};
if has_extension != True {
panic!("[winit] XRandR extension not available.");
}
*version_lock = Some((major, minor));
}
}
let mut event_offset = 0;
let mut error_offset = 0;
let status = unsafe {
(self.xrandr.XRRQueryExtension)(
self.display,
&mut event_offset,
&mut error_offset,
)
};
if status != True {
self.check_errors()?;
unreachable!("[winit] `XRRQueryExtension` failed but no error was received.");
}
let mask = RRCrtcChangeNotifyMask
| RROutputPropertyNotifyMask
| RRScreenChangeNotifyMask;
unsafe { (self.xrandr.XRRSelectInput)(self.display, root, mask) };
Ok(event_offset)
pub fn get_dimensions(&self) -> (u32, u32) {
let screen = unsafe { (self.0.xlib.XScreenOfDisplay)(self.0.display, self.1 as i32) };
let width = unsafe { (self.0.xlib.XWidthOfScreen)(screen) };
let height = unsafe { (self.0.xlib.XHeightOfScreen)(screen) };
self.0.check_errors().expect("Failed to get monitor dimensions");
(width as u32, height as u32)
}
}

72
src/platform/linux/x11/util/atom.rs
View File

@@ -1,72 +0,0 @@
use std::collections::HashMap;
use std::ffi::{CStr, CString};
use std::fmt::Debug;
use std::os::raw::*;
use parking_lot::Mutex;
use super::*;
type AtomCache = HashMap<CString, ffi::Atom>;
lazy_static! {
static ref ATOM_CACHE: Mutex<AtomCache> = Mutex::new(HashMap::with_capacity(2048));
}
impl XConnection {
pub fn get_atom<T: AsRef<CStr> + Debug>(&self, name: T) -> ffi::Atom {
let name = name.as_ref();
let mut atom_cache_lock = ATOM_CACHE.lock();
let cached_atom = (*atom_cache_lock).get(name).cloned();
if let Some(atom) = cached_atom {
atom
} else {
let atom = unsafe { (self.xlib.XInternAtom)(
self.display,
name.as_ptr() as *const c_char,
ffi::False,
) };
if atom == 0 {
let msg = format!(
"`XInternAtom` failed, which really shouldn't happen. Atom: {:?}, Error: {:#?}",
name,
self.check_errors(),
);
panic!(msg);
}
/*println!(
"XInternAtom name:{:?} atom:{:?}",
name,
atom,
);*/
(*atom_cache_lock).insert(name.to_owned(), atom);
atom
}
}
pub unsafe fn get_atom_unchecked(&self, name: &[u8]) -> ffi::Atom {
debug_assert!(CStr::from_bytes_with_nul(name).is_ok());
let name = CStr::from_bytes_with_nul_unchecked(name);
self.get_atom(name)
}
// Note: this doesn't use caching, for the sake of simplicity.
// If you're dealing with this many atoms, you'll usually want to cache them locally anyway.
pub unsafe fn get_atoms(&self, names: &[*mut c_char]) -> Result<Vec<ffi::Atom>, XError> {
let mut atoms = Vec::with_capacity(names.len());
(self.xlib.XInternAtoms)(
self.display,
names.as_ptr() as *mut _,
names.len() as c_int,
ffi::False,
atoms.as_mut_ptr(),
);
self.check_errors()?;
atoms.set_len(names.len());
/*println!(
"XInternAtoms atoms:{:?}",
atoms,
);*/
Ok(atoms)
}
}

95
src/platform/linux/x11/util/client_msg.rs
View File

@@ -1,95 +0,0 @@
use super::*;
pub type ClientMsgPayload = [c_long; 5];
impl XConnection {
pub fn send_event<T: Into<ffi::XEvent>>(
&self,
target_window: c_ulong,
event_mask: Option<c_long>,
event: T,
) -> Flusher {
let event_mask = event_mask.unwrap_or(ffi::NoEventMask);
unsafe {
(self.xlib.XSendEvent)(
self.display,
target_window,
ffi::False,
event_mask,
&mut event.into(),
);
}
Flusher::new(self)
}
pub fn send_client_msg(
&self,
window: c_ulong, // The window this is "about"; not necessarily this window
target_window: c_ulong, // The window we're sending to
message_type: ffi::Atom,
event_mask: Option<c_long>,
data: ClientMsgPayload,
) -> Flusher {
let mut event: ffi::XClientMessageEvent = unsafe { mem::uninitialized() };
event.type_ = ffi::ClientMessage;
event.display = self.display;
event.window = window;
event.message_type = message_type;
event.format = c_long::FORMAT as c_int;
event.data = unsafe { mem::transmute(data) };
self.send_event(target_window, event_mask, event)
}
// Prepare yourself for the ultimate in unsafety!
// You should favor `send_client_msg` whenever possible, but some protocols (i.e. startup notification) require you
// to send more than one message worth of data.
pub fn send_client_msg_multi<T: Formattable>(
&self,
window: c_ulong, // The window this is "about"; not necessarily this window
target_window: c_ulong, // The window we're sending to
message_type: ffi::Atom,
event_mask: Option<c_long>,
data: &[T],
) -> Flusher {
let format = T::FORMAT;
let size_of_t = mem::size_of::<T>();
debug_assert_eq!(size_of_t, format.get_actual_size());
let mut event: ffi::XClientMessageEvent = unsafe { mem::uninitialized() };
event.type_ = ffi::ClientMessage;
event.display = self.display;
event.window = window;
event.message_type = message_type;
event.format = format as c_int;
let t_per_payload = format.get_payload_size() / size_of_t;
assert!(t_per_payload > 0);
let payload_count = data.len() / t_per_payload;
let payload_remainder = data.len() % t_per_payload;
let payload_ptr = data.as_ptr() as *const ClientMsgPayload;
let mut payload_index = 0;
while payload_index < payload_count {
let payload = unsafe { payload_ptr.offset(payload_index as isize) };
payload_index += 1;
event.data = unsafe { mem::transmute(*payload) };
self.send_event(target_window, event_mask, &event).queue();
}
if payload_remainder > 0 {
let mut payload: ClientMsgPayload = [0; 5];
let t_payload = payload.as_mut_ptr() as *mut T;
let invalid_payload = unsafe { payload_ptr.offset(payload_index as isize) };
let invalid_t_payload = invalid_payload as *const T;
let mut t_index = 0;
while t_index < payload_remainder {
let valid_t = unsafe { invalid_t_payload.offset(t_index as isize) };
unsafe { (*t_payload.offset(t_index as isize)) = (*valid_t).clone() };
t_index += 1;
}
event.data = unsafe { mem::transmute(payload) };
self.send_event(target_window, event_mask, &event).queue();
}
Flusher::new(self)
}
}

58
src/platform/linux/x11/util/format.rs
View File

@@ -1,58 +0,0 @@
use std::fmt::Debug;
use std::mem;
use std::os::raw::*;
// This isn't actually the number of the bits in the format.
// X11 does a match on this value to determine which type to call sizeof on.
// Thus, we use 32 for c_long, since 32 maps to c_long which maps to 64.
// ...if that sounds confusing, then you know why this enum is here.
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord)]
pub enum Format {
Char = 8,
Short = 16,
Long = 32,
}
impl Format {
pub fn from_format(format: usize) -> Option<Self> {
match format {
8 => Some(Format::Char),
16 => Some(Format::Short),
32 => Some(Format::Long),
_ => None,
}
}
pub fn is_same_size_as<T>(&self) -> bool {
mem::size_of::<T>() == self.get_actual_size()
}
pub fn get_actual_size(&self) -> usize {
match self {
&Format::Char => mem::size_of::<c_char>(),
&Format::Short => mem::size_of::<c_short>(),
&Format::Long => mem::size_of::<c_long>(),
}
}
pub fn get_payload_size(&self) -> usize {
match self {
// Due to the wonders of X11, half the space goes unused if you're not using longs (on 64-bit).
&Format::Char => mem::size_of::<c_char>() * 20,
&Format::Short => mem::size_of::<c_short>() * 10,
&Format::Long => mem::size_of::<c_long>() * 5,
}
}
}
pub trait Formattable: Debug + Clone + Copy + PartialEq + PartialOrd {
const FORMAT: Format;
}
// You might be surprised by the absence of c_int, but not as surprised as X11 would be by the presence of it.
impl Formattable for c_schar { const FORMAT: Format = Format::Char; }
impl Formattable for c_uchar { const FORMAT: Format = Format::Char; }
impl Formattable for c_short { const FORMAT: Format = Format::Short; }
impl Formattable for c_ushort { const FORMAT: Format = Format::Short; }
impl Formattable for c_long { const FORMAT: Format = Format::Long; }
impl Formattable for c_ulong { const FORMAT: Format = Format::Long; }

387
src/platform/linux/x11/util/geometry.rs
View File

@@ -1,387 +0,0 @@
use std::cmp;
use super::*;
use {LogicalPosition, LogicalSize};
// Friendly neighborhood axis-aligned rectangle
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct AaRect {
x: i64,
y: i64,
width: i64,
height: i64,
}
impl AaRect {
pub fn new((x, y): (i32, i32), (width, height): (u32, u32)) -> Self {
let (x, y) = (x as i64, y as i64);
let (width, height) = (width as i64, height as i64);
AaRect { x, y, width, height }
}
pub fn contains_point(&self, x: i64, y: i64) -> bool {
x >= self.x && x <= self.x + self.width && y >= self.y && y <= self.y + self.height
}
pub fn get_overlapping_area(&self, other: &Self) -> i64 {
let x_overlap = cmp::max(
0,
cmp::min(self.x + self.width, other.x + other.width) - cmp::max(self.x, other.x),
);
let y_overlap = cmp::max(
0,
cmp::min(self.y + self.height, other.y + other.height) - cmp::max(self.y, other.y),
);
x_overlap * y_overlap
}
}
#[derive(Debug)]
pub struct TranslatedCoords {
pub x_rel_root: c_int,
pub y_rel_root: c_int,
pub child: ffi::Window,
}
#[derive(Debug)]
pub struct Geometry {
pub root: ffi::Window,
// If you want positions relative to the root window, use translate_coords.
// Note that the overwhelming majority of window managers are reparenting WMs, thus the window
// ID we get from window creation is for a nested window used as the window's client area. If
// you call get_geometry with that window ID, then you'll get the position of that client area
// window relative to the parent it's nested in (the frame), which isn't helpful if you want
// to know the frame position.
pub x_rel_parent: c_int,
pub y_rel_parent: c_int,
// In that same case, this will give you client area size.
pub width: c_uint,
pub height: c_uint,
// xmonad and dwm were the only WMs tested that use the border return at all.
// The majority of WMs seem to simply fill it with 0 unconditionally.
pub border: c_uint,
pub depth: c_uint,
}
#[derive(Debug, Clone)]
pub struct FrameExtents {
pub left: c_ulong,
pub right: c_ulong,
pub top: c_ulong,
pub bottom: c_ulong,
}
impl FrameExtents {
pub fn new(left: c_ulong, right: c_ulong, top: c_ulong, bottom: c_ulong) -> Self {
FrameExtents { left, right, top, bottom }
}
pub fn from_border(border: c_ulong) -> Self {
Self::new(border, border, border, border)
}
pub fn as_logical(&self, factor: f64) -> LogicalFrameExtents {
let logicalize = |value: c_ulong| value as f64 / factor;
LogicalFrameExtents {
left: logicalize(self.left),
right: logicalize(self.right),
top: logicalize(self.top),
bottom: logicalize(self.bottom),
}
}
}
#[derive(Debug, Clone)]
pub struct LogicalFrameExtents {
pub left: f64,
pub right: f64,
pub top: f64,
pub bottom: f64,
}
#[derive(Debug, Clone, PartialEq)]
pub enum FrameExtentsHeuristicPath {
Supported,
UnsupportedNested,
UnsupportedBordered,
}
#[derive(Debug, Clone)]
pub struct FrameExtentsHeuristic {
pub frame_extents: FrameExtents,
pub heuristic_path: FrameExtentsHeuristicPath,
}
impl FrameExtentsHeuristic {
pub fn inner_pos_to_outer(&self, x: i32, y: i32) -> (i32, i32) {
use self::FrameExtentsHeuristicPath::*;
if self.heuristic_path != UnsupportedBordered {
(x - self.frame_extents.left as i32, y - self.frame_extents.top as i32)
} else {
(x, y)
}
}
pub fn inner_pos_to_outer_logical(&self, mut logical: LogicalPosition, factor: f64) -> LogicalPosition {
use self::FrameExtentsHeuristicPath::*;
if self.heuristic_path != UnsupportedBordered {
let frame_extents = self.frame_extents.as_logical(factor);
logical.x -= frame_extents.left;
logical.y -= frame_extents.top;
}
logical
}
pub fn inner_size_to_outer(&self, width: u32, height: u32) -> (u32, u32) {
(
width.saturating_add(
self.frame_extents.left.saturating_add(self.frame_extents.right) as u32
),
height.saturating_add(
self.frame_extents.top.saturating_add(self.frame_extents.bottom) as u32
),
)
}
pub fn inner_size_to_outer_logical(&self, mut logical: LogicalSize, factor: f64) -> LogicalSize {
let frame_extents = self.frame_extents.as_logical(factor);
logical.width += frame_extents.left + frame_extents.right;
logical.height += frame_extents.top + frame_extents.bottom;
logical
}
}
impl XConnection {
// This is adequate for get_inner_position
pub fn translate_coords(&self, window: ffi::Window, root: ffi::Window) -> Result<TranslatedCoords, XError> {
let mut translated_coords: TranslatedCoords = unsafe { mem::uninitialized() };
unsafe {
(self.xlib.XTranslateCoordinates)(
self.display,
window,
root,
0,
0,
&mut translated_coords.x_rel_root,
&mut translated_coords.y_rel_root,
&mut translated_coords.child,
);
}
//println!("XTranslateCoordinates coords:{:?}", translated_coords);
self.check_errors().map(|_| translated_coords)
}
// This is adequate for get_inner_size
pub fn get_geometry(&self, window: ffi::Window) -> Result<Geometry, XError> {
let mut geometry: Geometry = unsafe { mem::uninitialized() };
let _status = unsafe {
(self.xlib.XGetGeometry)(
self.display,
window,
&mut geometry.root,
&mut geometry.x_rel_parent,
&mut geometry.y_rel_parent,
&mut geometry.width,
&mut geometry.height,
&mut geometry.border,
&mut geometry.depth,
)
};
//println!("XGetGeometry geo:{:?}", geometry);
self.check_errors().map(|_| geometry)
}
fn get_frame_extents(&self, window: ffi::Window) -> Option<FrameExtents> {
let extents_atom = unsafe { self.get_atom_unchecked(b"_NET_FRAME_EXTENTS\0") };
if !hint_is_supported(extents_atom) {
return None;
}
// Of the WMs tested, xmonad, i3, dwm, IceWM (1.3.x and earlier), and blackbox don't
// support this. As this is part of EWMH (Extended Window Manager Hints), it's likely to
// be unsupported by many smaller WMs.
let extents: Option<Vec<c_ulong>> = self.get_property(
window,
extents_atom,
ffi::XA_CARDINAL,
).ok();
extents.and_then(|extents| {
if extents.len() >= 4 {
Some(FrameExtents {
left: extents[0],
right: extents[1],
top: extents[2],
bottom: extents[3],
})
} else {
None
}
})
}
pub fn is_top_level(&self, window: ffi::Window, root: ffi::Window) -> Option<bool> {
let client_list_atom = unsafe { self.get_atom_unchecked(b"_NET_CLIENT_LIST\0") };
if !hint_is_supported(client_list_atom) {
return None;
}
let client_list: Option<Vec<ffi::Window>> = self.get_property(
root,
client_list_atom,
ffi::XA_WINDOW,
).ok();
client_list.map(|client_list| client_list.contains(&window))
}
fn get_parent_window(&self, window: ffi::Window) -> Result<ffi::Window, XError> {
let parent = unsafe {
let mut root: ffi::Window = mem::uninitialized();
let mut parent: ffi::Window = mem::uninitialized();
let mut children: *mut ffi::Window = ptr::null_mut();
let mut nchildren: c_uint = mem::uninitialized();
// What's filled into `parent` if `window` is the root window?
let _status = (self.xlib.XQueryTree)(
self.display,
window,
&mut root,
&mut parent,
&mut children,
&mut nchildren,
);
// The list of children isn't used
if children != ptr::null_mut() {
(self.xlib.XFree)(children as *mut _);
}
parent
};
self.check_errors().map(|_| parent)
}
fn climb_hierarchy(&self, window: ffi::Window, root: ffi::Window) -> Result<ffi::Window, XError> {
let mut outer_window = window;
loop {
let candidate = self.get_parent_window(outer_window)?;
if candidate == root {
break;
}
outer_window = candidate;
}
Ok(outer_window)
}
pub fn get_frame_extents_heuristic(&self, window: ffi::Window, root: ffi::Window) -> FrameExtentsHeuristic {
use self::FrameExtentsHeuristicPath::*;
// Position relative to root window.
// With rare exceptions, this is the position of a nested window. Cases where the window
// isn't nested are outlined in the comments throghout this function, but in addition to
// that, fullscreen windows often aren't nested.
let (inner_y_rel_root, child) = {
let coords = self.translate_coords(window, root).expect("Failed to translate window coordinates");
(
coords.y_rel_root,
coords.child,
)
};
let (width, height, border) = {
let inner_geometry = self.get_geometry(window).expect("Failed to get inner window geometry");
(
inner_geometry.width,
inner_geometry.height,
inner_geometry.border,
)
};
// The first condition is only false for un-nested windows, but isn't always false for
// un-nested windows. Mutter/Muffin/Budgie and Marco present a mysterious discrepancy:
// when y is on the range [0, 2] and if the window has been unfocused since being
// undecorated (or was undecorated upon construction), the first condition is true,
// requiring us to rely on the second condition.
let nested = !(window == child || self.is_top_level(child, root) == Some(true));
// Hopefully the WM supports EWMH, allowing us to get exact info on the window frames.
if let Some(mut frame_extents) = self.get_frame_extents(window) {
// Mutter/Muffin/Budgie and Marco preserve their decorated frame extents when
// decorations are disabled, but since the window becomes un-nested, it's easy to
// catch.
if !nested {
frame_extents = FrameExtents::new(0, 0, 0, 0);
}
// The difference between the nested window's position and the outermost window's
// position is equivalent to the frame size. In most scenarios, this is equivalent to
// manually climbing the hierarchy as is done in the case below. Here's a list of
// known discrepancies:
// * Mutter/Muffin/Budgie gives decorated windows a margin of 9px (only 7px on top) in
// addition to a 1px semi-transparent border. The margin can be easily observed by
// using a screenshot tool to get a screenshot of a selected window, and is
// presumably used for drawing drop shadows. Getting window geometry information
// via hierarchy-climbing results in this margin being included in both the
// position and outer size, so a window positioned at (0, 0) would be reported as
// having a position (-10, -8).
// * Compiz has a drop shadow margin just like Mutter/Muffin/Budgie, though it's 10px
// on all sides, and there's no additional border.
// * Enlightenment otherwise gets a y position equivalent to inner_y_rel_root.
// Without decorations, there's no difference. This is presumably related to
// Enlightenment's fairly unique concept of window position; it interprets
// positions given to XMoveWindow as a client area position rather than a position
// of the overall window.
FrameExtentsHeuristic {
frame_extents,
heuristic_path: Supported,
}
} else if nested {
// If the position value we have is for a nested window used as the client area, we'll
// just climb up the hierarchy and get the geometry of the outermost window we're
// nested in.
let outer_window = self.climb_hierarchy(window, root).expect("Failed to climb window hierarchy");
let (outer_y, outer_width, outer_height) = {
let outer_geometry = self.get_geometry(outer_window).expect("Failed to get outer window geometry");
(
outer_geometry.y_rel_parent,
outer_geometry.width,
outer_geometry.height,
)
};
// Since we have the geometry of the outermost window and the geometry of the client
// area, we can figure out what's in between.
let diff_x = outer_width.saturating_sub(width);
let diff_y = outer_height.saturating_sub(height);
let offset_y = inner_y_rel_root.saturating_sub(outer_y) as c_uint;
let left = diff_x / 2;
let right = left;
let top = offset_y;
let bottom = diff_y.saturating_sub(offset_y);
let frame_extents = FrameExtents::new(
left.into(),
right.into(),
top.into(),
bottom.into(),
);
FrameExtentsHeuristic {
frame_extents,
heuristic_path: UnsupportedNested,
}
} else {
// This is the case for xmonad and dwm, AKA the only WMs tested that supplied a
// border value. This is convenient, since we can use it to get an accurate frame.
let frame_extents = FrameExtents::from_border(border.into());
FrameExtentsHeuristic {
frame_extents,
heuristic_path: UnsupportedBordered,
}
}
}
}

211
src/platform/linux/x11/util/hint.rs
View File

@@ -1,211 +0,0 @@
use std::sync::Arc;
use super::*;
pub const MWM_HINTS_DECORATIONS: c_ulong = 2;
#[derive(Debug)]
pub enum StateOperation {
Remove = 0, // _NET_WM_STATE_REMOVE
Add = 1, // _NET_WM_STATE_ADD
Toggle = 2, // _NET_WM_STATE_TOGGLE
}
impl From<bool> for StateOperation {
fn from(op: bool) -> Self {
if op {
StateOperation::Add
} else {
StateOperation::Remove
}
}
}
/// X window type. Maps directly to
/// [`_NET_WM_WINDOW_TYPE`](https://specifications.freedesktop.org/wm-spec/1.3/ar01s05.html).
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub enum WindowType {
/// A desktop feature. This can include a single window containing desktop icons with the same dimensions as the
/// screen, allowing the desktop environment to have full control of the desktop, without the need for proxying
/// root window clicks.
Desktop,
/// A dock or panel feature. Typically a Window Manager would keep such windows on top of all other windows.
Dock,
/// Toolbar windows. "Torn off" from the main application.
Toolbar,
/// Pinnable menu windows. "Torn off" from the main application.
Menu,
/// A small persistent utility window, such as a palette or toolbox.
Utility,
/// The window is a splash screen displayed as an application is starting up.
Splash,
/// This is a dialog window.
Dialog,
/// This is a normal, top-level window.
Normal,
}
impl Default for WindowType {
fn default() -> Self {
WindowType::Normal
}
}
impl WindowType {
pub(crate) fn as_atom(&self, xconn: &Arc<XConnection>) -> ffi::Atom {
use self::WindowType::*;
let atom_name: &[u8] = match self {
&Desktop => b"_NET_WM_WINDOW_TYPE_DESKTOP\0",
&Dock => b"_NET_WM_WINDOW_TYPE_DOCK\0",
&Toolbar => b"_NET_WM_WINDOW_TYPE_TOOLBAR\0",
&Menu => b"_NET_WM_WINDOW_TYPE_MENU\0",
&Utility => b"_NET_WM_WINDOW_TYPE_UTILITY\0",
&Splash => b"_NET_WM_WINDOW_TYPE_SPLASH\0",
&Dialog => b"_NET_WM_WINDOW_TYPE_DIALOG\0",
&Normal => b"_NET_WM_WINDOW_TYPE_NORMAL\0",
};
unsafe { xconn.get_atom_unchecked(atom_name) }
}
}
pub struct NormalHints<'a> {
size_hints: XSmartPointer<'a, ffi::XSizeHints>,
}
impl<'a> NormalHints<'a> {
pub fn new(xconn: &'a XConnection) -> Self {
NormalHints { size_hints: xconn.alloc_size_hints() }
}
pub fn has_flag(&self, flag: c_long) -> bool {
has_flag(self.size_hints.flags, flag)
}
fn getter(&self, flag: c_long, field1: &c_int, field2: &c_int) -> Option<(u32, u32)> {
if self.has_flag(flag) {
Some((*field1 as _, *field2 as _))
} else {
None
}
}
pub fn get_size(&self) -> Option<(u32, u32)> {
self.getter(ffi::PSize, &self.size_hints.width, &self.size_hints.height)
}
// WARNING: This hint is obsolete
pub fn set_size(&mut self, size: Option<(u32, u32)>) {
if let Some((width, height)) = size {
self.size_hints.flags |= ffi::PSize;
self.size_hints.width = width as c_int;
self.size_hints.height = height as c_int;
} else {
self.size_hints.flags &= !ffi::PSize;
}
}
pub fn get_max_size(&self) -> Option<(u32, u32)> {
self.getter(ffi::PMaxSize, &self.size_hints.max_width, &self.size_hints.max_height)
}
pub fn set_max_size(&mut self, max_size: Option<(u32, u32)>) {
if let Some((max_width, max_height)) = max_size {
self.size_hints.flags |= ffi::PMaxSize;
self.size_hints.max_width = max_width as c_int;
self.size_hints.max_height = max_height as c_int;
} else {
self.size_hints.flags &= !ffi::PMaxSize;
}
}
pub fn get_min_size(&self) -> Option<(u32, u32)> {
self.getter(ffi::PMinSize, &self.size_hints.min_width, &self.size_hints.min_height)
}
pub fn set_min_size(&mut self, min_size: Option<(u32, u32)>) {
if let Some((min_width, min_height)) = min_size {
self.size_hints.flags |= ffi::PMinSize;
self.size_hints.min_width = min_width as c_int;
self.size_hints.min_height = min_height as c_int;
} else {
self.size_hints.flags &= !ffi::PMinSize;
}
}
pub fn get_resize_increments(&self) -> Option<(u32, u32)> {
self.getter(ffi::PResizeInc, &self.size_hints.width_inc, &self.size_hints.height_inc)
}
pub fn set_resize_increments(&mut self, resize_increments: Option<(u32, u32)>) {
if let Some((width_inc, height_inc)) = resize_increments {
self.size_hints.flags |= ffi::PResizeInc;
self.size_hints.width_inc = width_inc as c_int;
self.size_hints.height_inc = height_inc as c_int;
} else {
self.size_hints.flags &= !ffi::PResizeInc;
}
}
pub fn get_base_size(&self) -> Option<(u32, u32)> {
self.getter(ffi::PBaseSize, &self.size_hints.base_width, &self.size_hints.base_height)
}
pub fn set_base_size(&mut self, base_size: Option<(u32, u32)>) {
if let Some((base_width, base_height)) = base_size {
self.size_hints.flags |= ffi::PBaseSize;
self.size_hints.base_width = base_width as c_int;
self.size_hints.base_height = base_height as c_int;
} else {
self.size_hints.flags &= !ffi::PBaseSize;
}
}
}
impl XConnection {
pub fn get_wm_hints(&self, window: ffi::Window) -> Result<XSmartPointer<ffi::XWMHints>, XError> {
let wm_hints = unsafe { (self.xlib.XGetWMHints)(self.display, window) };
self.check_errors()?;
let wm_hints = if wm_hints.is_null() {
self.alloc_wm_hints()
} else {
XSmartPointer::new(self, wm_hints).unwrap()
};
Ok(wm_hints)
}
pub fn set_wm_hints(&self, window: ffi::Window, wm_hints: XSmartPointer<ffi::XWMHints>) -> Flusher {
unsafe {
(self.xlib.XSetWMHints)(
self.display,
window,
wm_hints.ptr,
);
}
Flusher::new(self)
}
pub fn get_normal_hints(&self, window: ffi::Window) -> Result<NormalHints, XError> {
let size_hints = self.alloc_size_hints();
let mut supplied_by_user: c_long = unsafe { mem::uninitialized() };
unsafe {
(self.xlib.XGetWMNormalHints)(
self.display,
window,
size_hints.ptr,
&mut supplied_by_user,
);
}
self.check_errors().map(|_| NormalHints { size_hints })
}
pub fn set_normal_hints(&self, window: ffi::Window, normal_hints: NormalHints) -> Flusher {
unsafe {
(self.xlib.XSetWMNormalHints)(
self.display,
window,
normal_hints.size_hints.ptr,
);
}
Flusher::new(self)
}
}

34
src/platform/linux/x11/util/icon.rs
View File

@@ -1,34 +0,0 @@
use {Icon, Pixel, PIXEL_SIZE};
use super::*;
impl Pixel {
pub fn to_packed_argb(&self) -> Cardinal {
let mut cardinal = 0;
assert!(CARDINAL_SIZE >= PIXEL_SIZE);
let as_bytes = &mut cardinal as *mut _ as *mut u8;
unsafe {
*as_bytes.offset(0) = self.b;
*as_bytes.offset(1) = self.g;
*as_bytes.offset(2) = self.r;
*as_bytes.offset(3) = self.a;
}
cardinal
}
}
impl Icon {
pub(crate) fn to_cardinals(&self) -> Vec<Cardinal> {
assert_eq!(self.rgba.len() % PIXEL_SIZE, 0);
let pixel_count = self.rgba.len() / PIXEL_SIZE;
assert_eq!(pixel_count, (self.width * self.height) as usize);
let mut data = Vec::with_capacity(pixel_count);
data.push(self.width as Cardinal);
data.push(self.height as Cardinal);
let pixels = self.rgba.as_ptr() as *const Pixel;
for pixel_index in 0..pixel_count {
let pixel = unsafe { &*pixels.offset(pixel_index as isize) };
data.push(pixel.to_packed_argb());
}
data
}
}

159
src/platform/linux/x11/util/input.rs
View File

@@ -1,159 +0,0 @@
use std::str;
use super::*;
use events::ModifiersState;
pub const VIRTUAL_CORE_POINTER: c_int = 2;
pub const VIRTUAL_CORE_KEYBOARD: c_int = 3;
// A base buffer size of 1kB uses a negligible amount of RAM while preventing us from having to
// re-allocate (and make another round-trip) in the *vast* majority of cases.
// To test if `lookup_utf8` works correctly, set this to 1.
const TEXT_BUFFER_SIZE: usize = 1024;
impl From<ffi::XIModifierState> for ModifiersState {
fn from(mods: ffi::XIModifierState) -> Self {
let state = mods.effective as c_uint;
ModifiersState {
alt: state & ffi::Mod1Mask != 0,
shift: state & ffi::ShiftMask != 0,
ctrl: state & ffi::ControlMask != 0,
logo: state & ffi::Mod4Mask != 0,
}
}
}
pub struct PointerState<'a> {
xconn: &'a XConnection,
root: ffi::Window,
child: ffi::Window,
pub root_x: c_double,
pub root_y: c_double,
win_x: c_double,
win_y: c_double,
buttons: ffi::XIButtonState,
modifiers: ffi::XIModifierState,
group: ffi::XIGroupState,
relative_to_window: bool,
}
impl<'a> PointerState<'a> {
pub fn get_modifier_state(&self) -> ModifiersState {
self.modifiers.into()
}
}
impl<'a> Drop for PointerState<'a> {
fn drop(&mut self) {
if !self.buttons.mask.is_null() {
unsafe {
// This is why you need to read the docs carefully...
(self.xconn.xlib.XFree)(self.buttons.mask as _);
}
}
}
}
impl XConnection {
pub fn select_xinput_events(&self, window: c_ulong, device_id: c_int, mask: i32) -> Flusher {
let mut event_mask = ffi::XIEventMask {
deviceid: device_id,
mask: &mask as *const _ as *mut c_uchar,
mask_len: mem::size_of_val(&mask) as c_int,
};
unsafe {
(self.xinput2.XISelectEvents)(
self.display,
window,
&mut event_mask as *mut ffi::XIEventMask,
1, // number of masks to read from pointer above
);
}
Flusher::new(self)
}
#[allow(dead_code)]
pub fn select_xkb_events(&self, device_id: c_uint, mask: c_ulong) -> Option<Flusher> {
let status = unsafe {
(self.xlib.XkbSelectEvents)(
self.display,
device_id,
mask,
mask,
)
};
if status == ffi::True {
Some(Flusher::new(self))
} else {
None
}
}
pub fn query_pointer(&self, window: ffi::Window, device_id: c_int) -> Result<PointerState, XError> {
unsafe {
let mut pointer_state: PointerState = mem::uninitialized();
pointer_state.xconn = self;
pointer_state.relative_to_window = (self.xinput2.XIQueryPointer)(
self.display,
device_id,
window,
&mut pointer_state.root,
&mut pointer_state.child,
&mut pointer_state.root_x,
&mut pointer_state.root_y,
&mut pointer_state.win_x,
&mut pointer_state.win_y,
&mut pointer_state.buttons,
&mut pointer_state.modifiers,
&mut pointer_state.group,
) == ffi::True;
if let Err(err) = self.check_errors() {
// Running the destrutor would be bad news for us...
mem::forget(pointer_state);
Err(err)
} else {
Ok(pointer_state)
}
}
}
fn lookup_utf8_inner(
&self,
ic: ffi::XIC,
key_event: &mut ffi::XKeyEvent,
buffer: &mut [u8],
) -> (ffi::KeySym, ffi::Status, c_int) {
let mut keysym: ffi::KeySym = 0;
let mut status: ffi::Status = 0;
let count = unsafe {
(self.xlib.Xutf8LookupString)(
ic,
key_event,
buffer.as_mut_ptr() as *mut c_char,
buffer.len() as c_int,
&mut keysym,
&mut status,
)
};
(keysym, status, count)
}
pub fn lookup_utf8(&self, ic: ffi::XIC, key_event: &mut ffi::XKeyEvent) -> String {
let mut buffer: [u8; TEXT_BUFFER_SIZE] = unsafe { mem::uninitialized() };
let (_, status, count) = self.lookup_utf8_inner(ic, key_event, &mut buffer);
// The buffer overflowed, so we'll make a new one on the heap.
if status == ffi::XBufferOverflow {
let mut buffer = Vec::with_capacity(count as usize);
unsafe { buffer.set_len(count as usize) };
let (_, _, new_count) = self.lookup_utf8_inner(ic, key_event, &mut buffer);
debug_assert_eq!(count, new_count);
str::from_utf8(&buffer[..count as usize])
.unwrap_or("")
.to_string()
} else {
str::from_utf8(&buffer[..count as usize])
.unwrap_or("")
.to_string()
}
}
}

62
src/platform/linux/x11/util/memory.rs
View File

@@ -1,62 +0,0 @@
use std::ops::{Deref, DerefMut};
use super::*;
pub struct XSmartPointer<'a, T> {
xconn: &'a XConnection,
pub ptr: *mut T,
}
impl<'a, T> XSmartPointer<'a, T> {
// You're responsible for only passing things to this that should be XFree'd.
// Returns None if ptr is null.
pub fn new(xconn: &'a XConnection, ptr: *mut T) -> Option<Self> {
if !ptr.is_null() {
Some(XSmartPointer {
xconn,
ptr,
})
} else {
None
}
}
}
impl<'a, T> Deref for XSmartPointer<'a, T> {
type Target = T;
fn deref(&self) -> &T {
unsafe { &*self.ptr }
}
}
impl<'a, T> DerefMut for XSmartPointer<'a, T> {
fn deref_mut(&mut self) -> &mut T {
unsafe { &mut *self.ptr }
}
}
impl<'a, T> Drop for XSmartPointer<'a, T> {
fn drop(&mut self) {
unsafe {
(self.xconn.xlib.XFree)(self.ptr as *mut _);
}
}
}
impl XConnection {
pub fn alloc_class_hint(&self) -> XSmartPointer<ffi::XClassHint> {
XSmartPointer::new(self, unsafe { (self.xlib.XAllocClassHint)() })
.expect("`XAllocClassHint` returned null; out of memory")
}
pub fn alloc_size_hints(&self) -> XSmartPointer<ffi::XSizeHints> {
XSmartPointer::new(self, unsafe { (self.xlib.XAllocSizeHints)() })
.expect("`XAllocSizeHints` returned null; out of memory")
}
pub fn alloc_wm_hints(&self) -> XSmartPointer<ffi::XWMHints> {
XSmartPointer::new(self, unsafe { (self.xlib.XAllocWMHints)() })
.expect("`XAllocWMHints` returned null; out of memory")
}
}

104
src/platform/linux/x11/util/mod.rs
View File

@@ -1,104 +0,0 @@
// Welcome to the util module, where we try to keep you from shooting yourself in the foot.
// *results may vary
mod atom;
mod client_msg;
mod format;
mod geometry;
mod hint;
mod icon;
mod input;
mod memory;
mod randr;
mod window_property;
mod wm;
pub use self::atom::*;
pub use self::client_msg::*;
pub use self::format::*;
pub use self::geometry::*;
pub use self::hint::*;
pub use self::icon::*;
pub use self::input::*;
pub use self::memory::*;
pub use self::randr::*;
pub use self::window_property::*;
pub use self::wm::*;
use std::mem;
use std::ptr;
use std::ops::BitAnd;
use std::os::raw::*;
use super::{ffi, XConnection, XError};
pub fn reinterpret<'a, A, B>(a: &'a A) -> &'a B {
let b_ptr = a as *const _ as *const B;
unsafe { &*b_ptr }
}
pub fn maybe_change<T: PartialEq>(field: &mut Option<T>, value: T) -> bool {
let wrapped = Some(value);
if *field != wrapped {
*field = wrapped;
true
} else {
false
}
}
pub fn has_flag<T>(bitset: T, flag: T) -> bool
where T:
Copy + PartialEq + BitAnd<T, Output = T>
{
bitset & flag == flag
}
#[must_use = "This request was made asynchronously, and is still in the output buffer. You must explicitly choose to either `.flush()` (empty the output buffer, sending the request now) or `.queue()` (wait to send the request, allowing you to continue to add more requests without additional round-trips). For more information, see the documentation for `util::flush_requests`."]
pub struct Flusher<'a> {
xconn: &'a XConnection,
}
impl<'a> Flusher<'a> {
pub fn new(xconn: &'a XConnection) -> Self {
Flusher { xconn }
}
// "I want this request sent now!"
pub fn flush(self) -> Result<(), XError> {
self.xconn.flush_requests()
}
// "I want the response now too!"
pub fn sync(self) -> Result<(), XError> {
self.xconn.sync_with_server()
}
// "I'm aware that this request hasn't been sent, and I'm okay with waiting."
pub fn queue(self) {}
}
impl XConnection {
// This is impoartant, so pay attention!
// Xlib has an output buffer, and tries to hide the async nature of X from you.
// This buffer contains the requests you make, and is flushed under various circumstances:
// 1. `XPending`, `XNextEvent`, and `XWindowEvent` flush "as needed"
// 2. `XFlush` explicitly flushes
// 3. `XSync` flushes and blocks until all requests are responded to
// 4. Calls that have a return dependent on a response (i.e. `XGetWindowProperty`) sync internally.
// When in doubt, check the X11 source; if a function calls `_XReply`, it flushes and waits.
// All util functions that abstract an async function will return a `Flusher`.
pub fn flush_requests(&self) -> Result<(), XError> {
unsafe { (self.xlib.XFlush)(self.display) };
//println!("XFlush");
// This isn't necessarily a useful time to check for errors (since our request hasn't
// necessarily been processed yet)
self.check_errors()
}
pub fn sync_with_server(&self) -> Result<(), XError> {
unsafe { (self.xlib.XSync)(self.display, ffi::False) };
//println!("XSync");
self.check_errors()
}
}

100
src/platform/linux/x11/util/randr.rs
View File

@@ -1,100 +0,0 @@
use std::{env, slice};
use std::str::FromStr;
use validate_hidpi_factor;
use super::*;
pub fn calc_dpi_factor(
(width_px, height_px): (u32, u32),
(width_mm, height_mm): (u64, u64),
) -> f64 {
// Override DPI if `WINIT_HIDPI_FACTOR` variable is set
let dpi_override = env::var("WINIT_HIDPI_FACTOR")
.ok()
.and_then(|var| f64::from_str(&var).ok());
if let Some(dpi_override) = dpi_override {
if !validate_hidpi_factor(dpi_override) {
panic!(
"`WINIT_HIDPI_FACTOR` invalid; DPI factors must be normal floats greater than 0. Got `{}`",
dpi_override,
);
}
return dpi_override;
}
// See http://xpra.org/trac/ticket/728 for more information.
if width_mm == 0 || width_mm == 0 {
warn!("XRandR reported that the display's 0mm in size, which is certifiably insane");
return 1.0;
}
let ppmm = (
(width_px as f64 * height_px as f64) / (width_mm as f64 * height_mm as f64)
).sqrt();
// Quantize 1/12 step size
let dpi_factor = ((ppmm * (12.0 * 25.4 / 96.0)).round() / 12.0).max(1.0);
assert!(validate_hidpi_factor(dpi_factor));
dpi_factor
}
pub enum MonitorRepr {
Monitor(*mut ffi::XRRMonitorInfo),
Crtc(*mut ffi::XRRCrtcInfo),
}
impl MonitorRepr {
pub unsafe fn get_output(&self) -> ffi::RROutput {
match *self {
// Same member names, but different locations within the struct...
MonitorRepr::Monitor(monitor) => *((*monitor).outputs.offset(0)),
MonitorRepr::Crtc(crtc) => *((*crtc).outputs.offset(0)),
}
}
pub unsafe fn get_dimensions(&self) -> (u32, u32) {
match *self {
MonitorRepr::Monitor(monitor) => ((*monitor).width as u32, (*monitor).height as u32),
MonitorRepr::Crtc(crtc) => ((*crtc).width as u32, (*crtc).height as u32),
}
}
pub unsafe fn get_position(&self) -> (i32, i32) {
match *self {
MonitorRepr::Monitor(monitor) => ((*monitor).x as i32, (*monitor).y as i32),
MonitorRepr::Crtc(crtc) => ((*crtc).x as i32, (*crtc).y as i32),
}
}
}
impl From<*mut ffi::XRRMonitorInfo> for MonitorRepr {
fn from(monitor: *mut ffi::XRRMonitorInfo) -> Self {
MonitorRepr::Monitor(monitor)
}
}
impl From<*mut ffi::XRRCrtcInfo> for MonitorRepr {
fn from(crtc: *mut ffi::XRRCrtcInfo) -> Self {
MonitorRepr::Crtc(crtc)
}
}
impl XConnection {
pub unsafe fn get_output_info(&self, resources: *mut ffi::XRRScreenResources, repr: &MonitorRepr) -> (String, f64) {
let output_info = (self.xrandr.XRRGetOutputInfo)(
self.display,
resources,
repr.get_output(),
);
let name_slice = slice::from_raw_parts(
(*output_info).name as *mut u8,
(*output_info).nameLen as usize,
);
let name = String::from_utf8_lossy(name_slice).into();
let hidpi_factor = calc_dpi_factor(
repr.get_dimensions(),
((*output_info).mm_width as u64, (*output_info).mm_height as u64),
);
(self.xrandr.XRRFreeOutputInfo)(output_info);
(name, hidpi_factor)
}
}

144
src/platform/linux/x11/util/window_property.rs
View File

@@ -1,144 +0,0 @@
use std;
use super::*;
pub type Cardinal = c_long;
pub const CARDINAL_SIZE: usize = mem::size_of::<c_long>();
#[derive(Debug, Clone)]
pub enum GetPropertyError {
XError(XError),
TypeMismatch(ffi::Atom),
FormatMismatch(c_int),
NothingAllocated,
}
impl GetPropertyError {
pub fn is_actual_property_type(&self, t: ffi::Atom) -> bool {
if let GetPropertyError::TypeMismatch(actual_type) = *self {
actual_type == t
} else {
false
}
}
}
// Number of 32-bit chunks to retrieve per iteration of get_property's inner loop.
// To test if `get_property` works correctly, set this to 1.
const PROPERTY_BUFFER_SIZE: c_long = 1024; // 4k of RAM ought to be enough for anyone!
#[derive(Debug)]
pub enum PropMode {
Replace = ffi::PropModeReplace as isize,
Prepend = ffi::PropModePrepend as isize,
Append = ffi::PropModeAppend as isize,
}
impl XConnection {
pub fn get_property<T: Formattable>(
&self,
window: c_ulong,
property: ffi::Atom,
property_type: ffi::Atom,
) -> Result<Vec<T>, GetPropertyError> {
let mut data = Vec::new();
let mut offset = 0;
let mut done = false;
while !done {
unsafe {
let mut actual_type: ffi::Atom = mem::uninitialized();
let mut actual_format: c_int = mem::uninitialized();
let mut quantity_returned: c_ulong = mem::uninitialized();
let mut bytes_after: c_ulong = mem::uninitialized();
let mut buf: *mut c_uchar = ptr::null_mut();
(self.xlib.XGetWindowProperty)(
self.display,
window,
property,
// This offset is in terms of 32-bit chunks.
offset,
// This is the quanity of 32-bit chunks to receive at once.
PROPERTY_BUFFER_SIZE,
ffi::False,
property_type,
&mut actual_type,
&mut actual_format,
// This is the quantity of items we retrieved in our format, NOT of 32-bit chunks!
&mut quantity_returned,
// ...and this is a quantity of bytes. So, this function deals in 3 different units.
&mut bytes_after,
&mut buf,
);
if let Err(e) = self.check_errors() {
return Err(GetPropertyError::XError(e));
}
if actual_type != property_type {
return Err(GetPropertyError::TypeMismatch(actual_type));
}
let format_mismatch = Format::from_format(actual_format as _) != Some(T::FORMAT);
if format_mismatch {
return Err(GetPropertyError::FormatMismatch(actual_format));
}
if !buf.is_null() {
offset += PROPERTY_BUFFER_SIZE;
let new_data = std::slice::from_raw_parts(
buf as *mut T,
quantity_returned as usize,
);
/*println!(
"XGetWindowProperty prop:{:?} fmt:{:02} len:{:02} off:{:02} out:{:02}, buf:{:?}",
property,
mem::size_of::<T>() * 8,
data.len(),
offset,
quantity_returned,
new_data,
);*/
data.extend_from_slice(&new_data);
// Fun fact: XGetWindowProperty allocates one extra byte at the end.
(self.xlib.XFree)(buf as _); // Don't try to access new_data after this.
} else {
return Err(GetPropertyError::NothingAllocated);
}
done = bytes_after == 0;
}
}
Ok(data)
}
pub fn change_property<'a, T: Formattable>(
&'a self,
window: c_ulong,
property: ffi::Atom,
property_type: ffi::Atom,
mode: PropMode,
new_value: &[T],
) -> Flusher<'a> {
debug_assert_eq!(mem::size_of::<T>(), T::FORMAT.get_actual_size());
unsafe {
(self.xlib.XChangeProperty)(
self.display,
window,
property,
property_type,
T::FORMAT as c_int,
mode as c_int,
new_value.as_ptr() as *const c_uchar,
new_value.len() as c_int,
);
}
/*println!(
"XChangeProperty prop:{:?} val:{:?}",
property,
new_value,
);*/
Flusher::new(self)
}
}

141
src/platform/linux/x11/util/wm.rs
View File

@@ -1,141 +0,0 @@
use parking_lot::Mutex;
use super::*;
// This info is global to the window manager.
lazy_static! {
static ref SUPPORTED_HINTS: Mutex<Vec<ffi::Atom>> = Mutex::new(Vec::with_capacity(0));
static ref WM_NAME: Mutex<Option<String>> = Mutex::new(None);
}
pub fn hint_is_supported(hint: ffi::Atom) -> bool {
(*SUPPORTED_HINTS.lock()).contains(&hint)
}
pub fn wm_name_is_one_of(names: &[&str]) -> bool {
if let Some(ref name) = *WM_NAME.lock() {
names.contains(&name.as_str())
} else {
false
}
}
impl XConnection {
pub fn update_cached_wm_info(&self, root: ffi::Window) {
*SUPPORTED_HINTS.lock() = self.get_supported_hints(root);
*WM_NAME.lock() = self.get_wm_name(root);
}
fn get_supported_hints(&self, root: ffi::Window) -> Vec<ffi::Atom> {
let supported_atom = unsafe { self.get_atom_unchecked(b"_NET_SUPPORTED\0") };
self.get_property(
root,
supported_atom,
ffi::XA_ATOM,
).unwrap_or_else(|_| Vec::with_capacity(0))
}
fn get_wm_name(&self, root: ffi::Window) -> Option<String> {
let check_atom = unsafe { self.get_atom_unchecked(b"_NET_SUPPORTING_WM_CHECK\0") };
let wm_name_atom = unsafe { self.get_atom_unchecked(b"_NET_WM_NAME\0") };
// Mutter/Muffin/Budgie doesn't have _NET_SUPPORTING_WM_CHECK in its _NET_SUPPORTED, despite
// it working and being supported. This has been reported upstream, but due to the
// inavailability of time machines, we'll just try to get _NET_SUPPORTING_WM_CHECK
// regardless of whether or not the WM claims to support it.
//
// Blackbox 0.70 also incorrectly reports not supporting this, though that appears to be fixed
// in 0.72.
/*if !supported_hints.contains(&check_atom) {
return None;
}*/
// IceWM (1.3.x and earlier) doesn't report supporting _NET_WM_NAME, but will nonetheless
// provide us with a value for it. Note that the unofficial 1.4 fork of IceWM works fine.
/*if !supported_hints.contains(&wm_name_atom) {
return None;
}*/
// Of the WMs tested, only xmonad and dwm fail to provide a WM name.
// Querying this property on the root window will give us the ID of a child window created by
// the WM.
let root_window_wm_check = {
let result = self.get_property(
root,
check_atom,
ffi::XA_WINDOW,
);
let wm_check = result
.ok()
.and_then(|wm_check| wm_check.get(0).cloned());
if let Some(wm_check) = wm_check {
wm_check
} else {
return None;
}
};
// Querying the same property on the child window we were given, we should get this child
// window's ID again.
let child_window_wm_check = {
let result = self.get_property(
root_window_wm_check,
check_atom,
ffi::XA_WINDOW,
);
let wm_check = result
.ok()
.and_then(|wm_check| wm_check.get(0).cloned());
if let Some(wm_check) = wm_check {
wm_check
} else {
return None;
}
};
// These values should be the same.
if root_window_wm_check != child_window_wm_check {
return None;
}
// All of that work gives us a window ID that we can get the WM name from.
let wm_name = {
let utf8_string_atom = unsafe { self.get_atom_unchecked(b"UTF8_STRING\0") };
let result = self.get_property(
root_window_wm_check,
wm_name_atom,
utf8_string_atom,
);
// IceWM requires this. IceWM was also the only WM tested that returns a null-terminated
// string. For more fun trivia, IceWM is also unique in including version and uname
// information in this string (this means you'll have to be careful if you want to match
// against it, though).
// The unofficial 1.4 fork of IceWM still includes the extra details, but properly
// returns a UTF8 string that isn't null-terminated.
let no_utf8 = if let Err(ref err) = result {
err.is_actual_property_type(ffi::XA_STRING)
} else {
false
};
if no_utf8 {
self.get_property(
root_window_wm_check,
wm_name_atom,
ffi::XA_STRING,
)
} else {
result
}
}.ok();
wm_name.and_then(|wm_name| String::from_utf8(wm_name).ok())
}
}

1938
src/platform/linux/x11/window.rs
View File

File diff suppressed because it is too large Load Diff

42
src/platform/linux/x11/xdisplay.rs
View File

@@ -1,19 +1,16 @@
use std::ptr;
use std::fmt;
use std::error::Error;
use std::sync::Mutex;
use libc;
use parking_lot::Mutex;
use super::ffi;
/// A connection to an X server.
pub struct XConnection {
pub xlib: ffi::Xlib,
/// Exposes XRandR functions from version < 1.5
pub xrandr: ffi::Xrandr_2_2_0,
/// Exposes XRandR functions from version = 1.5
pub xrandr_1_5: Option<ffi::Xrandr>,
pub xf86vmode: ffi::Xf86vmode,
pub xcursor: ffi::Xcursor,
pub xinput2: ffi::XInput2,
pub xlib_xcb: ffi::Xlib_xcb,
@@ -29,12 +26,11 @@ pub type XErrorHandler = Option<unsafe extern fn(*mut ffi::Display, *mut ffi::XE
impl XConnection {
pub fn new(error_handler: XErrorHandler) -> Result<XConnection, XNotSupported> {
// opening the libraries
let xlib = ffi::Xlib::open()?;
let xcursor = ffi::Xcursor::open()?;
let xrandr = ffi::Xrandr_2_2_0::open()?;
let xrandr_1_5 = ffi::Xrandr::open().ok();
let xinput2 = ffi::XInput2::open()?;
let xlib_xcb = ffi::Xlib_xcb::open()?;
let xlib = try!(ffi::Xlib::open());
let xcursor = try!(ffi::Xcursor::open());
let xf86vmode = try!(ffi::Xf86vmode::open());
let xinput2 = try!(ffi::XInput2::open());
let xlib_xcb = try!(ffi::Xlib_xcb::open());
unsafe { (xlib.XInitThreads)() };
unsafe { (xlib.XSetErrorHandler)(error_handler) };
@@ -49,13 +45,12 @@ impl XConnection {
};
Ok(XConnection {
xlib,
xrandr,
xrandr_1_5,
xcursor,
xinput2,
xlib_xcb,
display,
xlib: xlib,
xf86vmode: xf86vmode,
xcursor: xcursor,
xinput2: xinput2,
xlib_xcb: xlib_xcb,
display: display,
latest_error: Mutex::new(None),
})
}
@@ -63,7 +58,8 @@ impl XConnection {
/// Checks whether an error has been triggered by the previous function calls.
#[inline]
pub fn check_errors(&self) -> Result<(), XError> {
let error = self.latest_error.lock().take();
let error = self.latest_error.lock().unwrap().take();
if let Some(error) = error {
Err(error)
} else {
@@ -74,13 +70,7 @@ impl XConnection {
/// Ignores any previous error.
#[inline]
pub fn ignore_error(&self) {
*self.latest_error.lock() = None;
}
}
impl fmt::Debug for XConnection {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
self.display.fmt(f)
*self.latest_error.lock().unwrap() = None;
}
}

571
src/platform/macos/events_loop.rs
View File

@@ -1,23 +1,16 @@
use {ControlFlow, EventsLoopClosed};
use cocoa::{self, appkit, foundation};
use cocoa::appkit::{NSApplication, NSEvent, NSEventMask, NSEventModifierFlags, NSEventPhase, NSView, NSWindow};
use events::{self, ElementState, Event, TouchPhase, WindowEvent, DeviceEvent, ModifiersState, KeyboardInput};
use std::collections::VecDeque;
use std::sync::{Arc, Mutex, Weak};
use super::window::Window2;
use cocoa::appkit::{NSApplication, NSEvent, NSView, NSWindow};
use events::{self, ElementState, Event, MouseButton, TouchPhase, WindowEvent, ModifiersState};
use super::window::Window;
use std;
use std::os::raw::*;
use super::DeviceId;
pub struct EventsLoop {
modifiers: Modifiers,
pub shared: Arc<Shared>,
}
pub windows: std::sync::Mutex<Vec<std::sync::Weak<Window>>>,
pub pending_events: std::sync::Mutex<std::collections::VecDeque<Event>>,
modifiers: std::sync::Mutex<Modifiers>,
interrupted: std::sync::atomic::AtomicBool,
// State shared between the `EventsLoop` and its registered windows.
pub struct Shared {
pub windows: Mutex<Vec<Weak<Window2>>>,
pub pending_events: Mutex<VecDeque<Event>>,
// The user event callback given via either of the `poll_events` or `run_forever` methods.
//
// We store the user's callback here so that it may be accessed by each of the window delegate
@@ -29,9 +22,6 @@ pub struct Shared {
user_callback: UserCallback,
}
#[derive(Clone)]
pub struct Proxy {}
struct Modifiers {
shift_pressed: bool,
ctrl_pressed: bool,
@@ -43,76 +33,14 @@ struct Modifiers {
//
// - ensure the callback pointer is never accidentally cloned
// - ensure that only the `EventsLoop` can `store` and `drop` the callback pointer
// - Share access to the user callback with the NSWindow callbacks.
// - `unsafe impl Send` and `Sync` so that `Send` and `Sync` can be implemented for `EventsLoop`.
pub struct UserCallback {
mutex: Mutex<Option<*mut FnMut(Event)>>,
mutex: std::sync::Mutex<Option<*mut FnMut(Event)>>,
}
impl Shared {
pub fn new() -> Self {
Shared {
windows: Mutex::new(Vec::new()),
pending_events: Mutex::new(VecDeque::new()),
user_callback: UserCallback { mutex: Mutex::new(None) },
}
}
fn call_user_callback_with_pending_events(&self) {
loop {
let event = match self.pending_events.lock().unwrap().pop_front() {
Some(event) => event,
None => return,
};
unsafe {
self.user_callback.call_with_event(event);
}
}
}
// Calls the user callback if one exists.
//
// Otherwise, stores the event in the `pending_events` queue.
//
// This is necessary for the case when `WindowDelegate` callbacks are triggered during a call
// to the user's callback.
pub fn call_user_callback_with_event_or_store_in_pending(&self, event: Event) {
if self.user_callback.mutex.lock().unwrap().is_some() {
unsafe {
self.user_callback.call_with_event(event);
}
} else {
self.pending_events.lock().unwrap().push_back(event);
}
}
// Removes the window with the given `Id` from the `windows` list.
//
// This is called in response to `windowWillClose`.
pub fn find_and_remove_window(&self, id: super::window::Id) {
if let Ok(mut windows) = self.windows.lock() {
windows.retain(|w| match w.upgrade() {
Some(w) => w.id() != id,
None => false,
});
}
}
}
impl Modifiers {
pub fn new() -> Self {
Modifiers {
shift_pressed: false,
ctrl_pressed: false,
win_pressed: false,
alt_pressed: false,
}
}
}
unsafe impl Send for UserCallback {}
unsafe impl Sync for UserCallback {}
impl UserCallback {
@@ -163,41 +91,43 @@ impl UserCallback {
impl EventsLoop {
pub fn new() -> Self {
// Mark this thread as the main thread of the Cocoa event system.
//
// This must be done before any worker threads get a chance to call it
// (e.g., via `EventsLoopProxy::wakeup()`), causing a wrong thread to be
// marked as the main thread.
unsafe { appkit::NSApp(); }
let modifiers = Modifiers {
shift_pressed: false,
ctrl_pressed: false,
win_pressed: false,
alt_pressed: false,
};
EventsLoop {
shared: Arc::new(Shared::new()),
modifiers: Modifiers::new(),
windows: std::sync::Mutex::new(Vec::new()),
pending_events: std::sync::Mutex::new(std::collections::VecDeque::new()),
modifiers: std::sync::Mutex::new(modifiers),
interrupted: std::sync::atomic::AtomicBool::new(false),
user_callback: UserCallback { mutex: std::sync::Mutex::new(None) },
}
}
pub fn poll_events<F>(&mut self, mut callback: F)
pub fn poll_events<F>(&self, mut callback: F)
where F: FnMut(Event),
{
unsafe {
if !msg_send![class!(NSThread), isMainThread] {
if !msg_send![cocoa::base::class("NSThread"), isMainThread] {
panic!("Events can only be polled from the main thread on macOS");
}
}
self.shared.user_callback.store(&mut callback);
self.user_callback.store(&mut callback);
// Loop as long as we have pending events to return.
loop {
unsafe {
// First, yield all pending events.
self.shared.call_user_callback_with_pending_events();
self.call_user_callback_with_pending_events();
let pool = foundation::NSAutoreleasePool::new(cocoa::base::nil);
// Poll for the next event, returning `nil` if there are none.
let ns_event = appkit::NSApp().nextEventMatchingMask_untilDate_inMode_dequeue_(
NSEventMask::NSAnyEventMask.bits() | NSEventMask::NSEventMaskPressure.bits(),
appkit::NSAnyEventMask.bits() | appkit::NSEventMaskPressure.bits(),
foundation::NSDate::distantPast(cocoa::base::nil),
foundation::NSDefaultRunLoopMode,
cocoa::base::YES);
@@ -208,48 +138,38 @@ impl EventsLoop {
match event {
// Call the user's callback.
Some(event) => self.shared.user_callback.call_with_event(event),
Some(event) => self.user_callback.call_with_event(event),
None => break,
}
}
}
self.shared.user_callback.drop();
self.user_callback.drop();
}
pub fn run_forever<F>(&mut self, mut callback: F)
where F: FnMut(Event) -> ControlFlow
pub fn run_forever<F>(&self, mut callback: F)
where F: FnMut(Event)
{
self.interrupted.store(false, std::sync::atomic::Ordering::Relaxed);
unsafe {
if !msg_send![class!(NSThread), isMainThread] {
if !msg_send![cocoa::base::class("NSThread"), isMainThread] {
panic!("Events can only be polled from the main thread on macOS");
}
}
// Track whether or not control flow has changed.
let control_flow = std::cell::Cell::new(ControlFlow::Continue);
let mut callback = |event| {
if let ControlFlow::Break = callback(event) {
control_flow.set(ControlFlow::Break);
}
};
self.shared.user_callback.store(&mut callback);
self.user_callback.store(&mut callback);
loop {
unsafe {
// First, yield all pending events.
self.shared.call_user_callback_with_pending_events();
if let ControlFlow::Break = control_flow.get() {
break;
}
self.call_user_callback_with_pending_events();
let pool = foundation::NSAutoreleasePool::new(cocoa::base::nil);
// Wait for the next event. Note that this function blocks during resize.
let ns_event = appkit::NSApp().nextEventMatchingMask_untilDate_inMode_dequeue_(
NSEventMask::NSAnyEventMask.bits() | NSEventMask::NSEventMaskPressure.bits(),
appkit::NSAnyEventMask.bits() | appkit::NSEventMaskPressure.bits(),
foundation::NSDate::distantFuture(cocoa::base::nil),
foundation::NSDefaultRunLoopMode,
cocoa::base::YES);
@@ -261,19 +181,84 @@ impl EventsLoop {
let _: () = msg_send![pool, release];
if let Some(event) = maybe_event {
self.shared.user_callback.call_with_event(event);
if let ControlFlow::Break = control_flow.get() {
break;
}
self.user_callback.call_with_event(event);
}
}
if self.interrupted.load(std::sync::atomic::Ordering::Relaxed) {
self.interrupted.store(false, std::sync::atomic::Ordering::Relaxed);
break;
}
}
self.shared.user_callback.drop();
self.user_callback.drop();
}
pub fn interrupt(&self) {
self.interrupted.store(true, std::sync::atomic::Ordering::Relaxed);
// Awaken the event loop by triggering `NSApplicationActivatedEventType`.
unsafe {
let pool = foundation::NSAutoreleasePool::new(cocoa::base::nil);
let event =
NSEvent::otherEventWithType_location_modifierFlags_timestamp_windowNumber_context_subtype_data1_data2_(
cocoa::base::nil,
appkit::NSApplicationDefined,
foundation::NSPoint::new(0.0, 0.0),
appkit::NSEventModifierFlags::empty(),
0.0,
0,
cocoa::base::nil,
appkit::NSEventSubtype::NSApplicationActivatedEventType,
0,
0);
appkit::NSApp().postEvent_atStart_(event, cocoa::base::NO);
foundation::NSAutoreleasePool::drain(pool);
}
}
// Removes the window with the given `Id` from the `windows` list.
//
// This is called when a window is either `Closed` or `Drop`ped.
pub fn find_and_remove_window(&self, id: super::window::Id) {
if let Ok(mut windows) = self.windows.lock() {
windows.retain(|w| match w.upgrade() {
Some(w) => w.id() != id,
None => true,
});
}
}
fn call_user_callback_with_pending_events(&self) {
loop {
let event = match self.pending_events.lock().unwrap().pop_front() {
Some(event) => event,
None => return,
};
unsafe {
self.user_callback.call_with_event(event);
}
}
}
// Calls the user callback if one exists.
//
// Otherwise, stores the event in the `pending_events` queue.
//
// This is necessary for the case when `WindowDelegate` callbacks are triggered during a call
// to the user's callback.
pub fn call_user_callback_with_event_or_store_in_pending(&self, event: Event) {
if self.user_callback.mutex.lock().unwrap().is_some() {
unsafe {
self.user_callback.call_with_event(event);
}
} else {
self.pending_events.lock().unwrap().push_back(event);
}
}
// Convert some given `NSEvent` into a winit `Event`.
unsafe fn ns_event_to_event(&mut self, ns_event: cocoa::base::id) -> Option<Event> {
unsafe fn ns_event_to_event(&self, ns_event: cocoa::base::id) -> Option<Event> {
if ns_event == cocoa::base::nil {
return None;
}
@@ -294,11 +279,14 @@ impl EventsLoop {
// FIXME: Document this. Why do we do this? Seems like it passes on events to window/app.
// If we don't do this, window does not become main for some reason.
appkit::NSApp().sendEvent_(ns_event);
match event_type {
appkit::NSKeyDown => (),
_ => appkit::NSApp().sendEvent_(ns_event),
}
let windows = self.shared.windows.lock().unwrap();
let windows = self.windows.lock().unwrap();
let maybe_window = windows.iter()
.filter_map(Weak::upgrade)
.filter_map(std::sync::Weak::upgrade)
.find(|window| window_id == window.id());
let into_event = |window_event| Event::WindowEvent {
@@ -308,82 +296,126 @@ impl EventsLoop {
// Returns `Some` window if one of our windows is the key window.
let maybe_key_window = || windows.iter()
.filter_map(Weak::upgrade)
.filter_map(std::sync::Weak::upgrade)
.find(|window| {
let is_key_window: cocoa::base::BOOL = msg_send![*window.window, isKeyWindow];
is_key_window == cocoa::base::YES
});
match event_type {
// https://github.com/glfw/glfw/blob/50eccd298a2bbc272b4977bd162d3e4b55f15394/src/cocoa_window.m#L881
appkit::NSKeyUp => {
if let Some(key_window) = maybe_key_window() {
if event_mods(ns_event).logo {
let _: () = msg_send![*key_window.window, sendEvent:ns_event];
appkit::NSKeyDown => {
let mut events = std::collections::VecDeque::new();
let received_c_str = foundation::NSString::UTF8String(ns_event.characters());
let received_str = std::ffi::CStr::from_ptr(received_c_str);
for received_char in std::str::from_utf8(received_str.to_bytes()).unwrap().chars() {
let window_event = WindowEvent::ReceivedCharacter(received_char);
events.push_back(into_event(window_event));
}
let vkey = to_virtual_key_code(NSEvent::keyCode(ns_event));
let state = ElementState::Pressed;
let code = NSEvent::keyCode(ns_event) as u8;
let window_event = WindowEvent::KeyboardInput(state, code, vkey, event_mods(ns_event));
events.push_back(into_event(window_event));
let event = events.pop_front();
self.pending_events.lock().unwrap().extend(events.into_iter());
event
},
appkit::NSKeyUp => {
let vkey = to_virtual_key_code(NSEvent::keyCode(ns_event));
let state = ElementState::Released;
let code = NSEvent::keyCode(ns_event) as u8;
let window_event = WindowEvent::KeyboardInput(state, code, vkey, event_mods(ns_event));
Some(into_event(window_event))
},
appkit::NSFlagsChanged => {
let mut modifiers = self.modifiers.lock().unwrap();
unsafe fn modifier_event(event: cocoa::base::id,
keymask: appkit::NSEventModifierFlags,
key: events::VirtualKeyCode,
key_pressed: bool) -> Option<WindowEvent>
{
if !key_pressed && NSEvent::modifierFlags(event).contains(keymask) {
let state = ElementState::Pressed;
let code = NSEvent::keyCode(event) as u8;
let window_event = WindowEvent::KeyboardInput(state, code, Some(key), event_mods(event));
Some(window_event)
} else if key_pressed && !NSEvent::modifierFlags(event).contains(keymask) {
let state = ElementState::Released;
let code = NSEvent::keyCode(event) as u8;
let window_event = WindowEvent::KeyboardInput(state, code, Some(key), event_mods(event));
Some(window_event)
} else {
None
}
}
None
},
// similar to above, but for `<Cmd-.>`, the keyDown is suppressed instead of the
// KeyUp, and the above trick does not appear to work.
appkit::NSKeyDown => {
let modifiers = event_mods(ns_event);
let keycode = NSEvent::keyCode(ns_event);
if modifiers.logo && keycode == 47 {
modifier_event(ns_event, NSEventModifierFlags::NSCommandKeyMask, false)
.map(into_event)
} else {
None
}
},
appkit::NSFlagsChanged => {
let mut events = std::collections::VecDeque::new();
if let Some(window_event) = modifier_event(
ns_event,
NSEventModifierFlags::NSShiftKeyMask,
self.modifiers.shift_pressed,
) {
self.modifiers.shift_pressed = !self.modifiers.shift_pressed;
if let Some(window_event) = modifier_event(ns_event,
appkit::NSShiftKeyMask,
events::VirtualKeyCode::LShift,
modifiers.shift_pressed)
{
modifiers.shift_pressed = !modifiers.shift_pressed;
events.push_back(into_event(window_event));
}
if let Some(window_event) = modifier_event(
ns_event,
NSEventModifierFlags::NSControlKeyMask,
self.modifiers.ctrl_pressed,
) {
self.modifiers.ctrl_pressed = !self.modifiers.ctrl_pressed;
if let Some(window_event) = modifier_event(ns_event,
appkit::NSControlKeyMask,
events::VirtualKeyCode::LControl,
modifiers.ctrl_pressed)
{
modifiers.ctrl_pressed = !modifiers.ctrl_pressed;
events.push_back(into_event(window_event));
}
if let Some(window_event) = modifier_event(
ns_event,
NSEventModifierFlags::NSCommandKeyMask,
self.modifiers.win_pressed,
) {
self.modifiers.win_pressed = !self.modifiers.win_pressed;
if let Some(window_event) = modifier_event(ns_event,
appkit::NSCommandKeyMask,
events::VirtualKeyCode::LWin,
modifiers.win_pressed)
{
modifiers.win_pressed = !modifiers.win_pressed;
events.push_back(into_event(window_event));
}
if let Some(window_event) = modifier_event(
ns_event,
NSEventModifierFlags::NSAlternateKeyMask,
self.modifiers.alt_pressed,
) {
self.modifiers.alt_pressed = !self.modifiers.alt_pressed;
if let Some(window_event) = modifier_event(ns_event,
appkit::NSAlternateKeyMask,
events::VirtualKeyCode::LAlt,
modifiers.alt_pressed)
{
modifiers.alt_pressed = !modifiers.alt_pressed;
events.push_back(into_event(window_event));
}
let event = events.pop_front();
self.shared.pending_events
.lock()
.unwrap()
.extend(events.into_iter());
self.pending_events.lock().unwrap().extend(events.into_iter());
event
},
appkit::NSMouseEntered => {
appkit::NSLeftMouseDown => { Some(into_event(WindowEvent::MouseInput(ElementState::Pressed, MouseButton::Left))) },
appkit::NSLeftMouseUp => { Some(into_event(WindowEvent::MouseInput(ElementState::Released, MouseButton::Left))) },
appkit::NSRightMouseDown => { Some(into_event(WindowEvent::MouseInput(ElementState::Pressed, MouseButton::Right))) },
appkit::NSRightMouseUp => { Some(into_event(WindowEvent::MouseInput(ElementState::Released, MouseButton::Right))) },
appkit::NSOtherMouseDown => { Some(into_event(WindowEvent::MouseInput(ElementState::Pressed, MouseButton::Middle))) },
appkit::NSOtherMouseUp => { Some(into_event(WindowEvent::MouseInput(ElementState::Released, MouseButton::Middle))) },
appkit::NSMouseEntered => { Some(into_event(WindowEvent::MouseEntered)) },
appkit::NSMouseExited => { Some(into_event(WindowEvent::MouseLeft)) },
appkit::NSMouseMoved |
appkit::NSLeftMouseDragged |
appkit::NSOtherMouseDragged |
appkit::NSRightMouseDragged => {
// If the mouse movement was on one of our windows, use it.
// Otherwise, if one of our windows is the key window (receiving input), use it.
// Otherwise, return `None`.
let window = match maybe_window.or_else(maybe_key_window) {
Some(window) => window,
None => return None,
@@ -398,114 +430,51 @@ impl EventsLoop {
} else {
window.view.convertPoint_fromView_(window_point, cocoa::base::nil)
};
let view_rect = NSView::frame(*window.view);
let x = view_point.x as f64;
let y = (view_rect.size.height - view_point.y) as f64;
let window_event = WindowEvent::CursorMoved {
device_id: DEVICE_ID,
position: (x, y).into(),
modifiers: event_mods(ns_event),
};
let scale_factor = window.hidpi_factor();
let x = (scale_factor * view_point.x as f32) as i32;
let y = (scale_factor * (view_rect.size.height - view_point.y) as f32) as i32;
let window_event = WindowEvent::MouseMoved(x, y);
let event = Event::WindowEvent { window_id: ::WindowId(window.id()), event: window_event };
self.shared.pending_events.lock().unwrap().push_back(event);
Some(into_event(WindowEvent::CursorEntered { device_id: DEVICE_ID }))
},
appkit::NSMouseExited => { Some(into_event(WindowEvent::CursorLeft { device_id: DEVICE_ID })) },
appkit::NSMouseMoved |
appkit::NSLeftMouseDragged |
appkit::NSOtherMouseDragged |
appkit::NSRightMouseDragged => {
// If the mouse movement was on one of our windows, use it.
// Otherwise, if one of our windows is the key window (receiving input), use it.
// Otherwise, return `None`.
match maybe_window.or_else(maybe_key_window) {
Some(_window) => (),
None => return None,
}
let mut events = std::collections::VecDeque::with_capacity(3);
let delta_x = ns_event.deltaX() as f64;
if delta_x != 0.0 {
let motion_event = DeviceEvent::Motion { axis: 0, value: delta_x };
let event = Event::DeviceEvent { device_id: DEVICE_ID, event: motion_event };
events.push_back(event);
}
let delta_y = ns_event.deltaY() as f64;
if delta_y != 0.0 {
let motion_event = DeviceEvent::Motion { axis: 1, value: delta_y };
let event = Event::DeviceEvent { device_id: DEVICE_ID, event: motion_event };
events.push_back(event);
}
if delta_x != 0.0 || delta_y != 0.0 {
let motion_event = DeviceEvent::MouseMotion { delta: (delta_x, delta_y) };
let event = Event::DeviceEvent { device_id: DEVICE_ID, event: motion_event };
events.push_back(event);
}
let event = events.pop_front();
self.shared.pending_events.lock().unwrap().extend(events.into_iter());
event
Some(event)
},
appkit::NSScrollWheel => {
// If none of the windows received the scroll, return `None`.
if maybe_window.is_none() {
return None;
}
let window = match maybe_window {
Some(window) => window,
None => return None,
};
use events::MouseScrollDelta::{LineDelta, PixelDelta};
let scale_factor = window.hidpi_factor();
let delta = if ns_event.hasPreciseScrollingDeltas() == cocoa::base::YES {
PixelDelta((
ns_event.scrollingDeltaX() as f64,
ns_event.scrollingDeltaY() as f64,
).into())
PixelDelta(scale_factor * ns_event.scrollingDeltaX() as f32,
scale_factor * ns_event.scrollingDeltaY() as f32)
} else {
// TODO: This is probably wrong
LineDelta(
ns_event.scrollingDeltaX() as f32,
ns_event.scrollingDeltaY() as f32,
)
LineDelta(scale_factor * ns_event.scrollingDeltaX() as f32,
scale_factor * ns_event.scrollingDeltaY() as f32)
};
let phase = match ns_event.phase() {
NSEventPhase::NSEventPhaseMayBegin | NSEventPhase::NSEventPhaseBegan => TouchPhase::Started,
NSEventPhase::NSEventPhaseEnded => TouchPhase::Ended,
appkit::NSEventPhaseMayBegin | appkit::NSEventPhaseBegan => TouchPhase::Started,
appkit::NSEventPhaseEnded => TouchPhase::Ended,
_ => TouchPhase::Moved,
};
self.shared.pending_events.lock().unwrap().push_back(Event::DeviceEvent {
device_id: DEVICE_ID,
event: DeviceEvent::MouseWheel {
delta: if ns_event.hasPreciseScrollingDeltas() == cocoa::base::YES {
PixelDelta((
ns_event.scrollingDeltaX() as f64,
ns_event.scrollingDeltaY() as f64,
).into())
} else {
LineDelta(
ns_event.scrollingDeltaX() as f32,
ns_event.scrollingDeltaY() as f32,
)
},
}
});
let window_event = WindowEvent::MouseWheel { device_id: DEVICE_ID, delta: delta, phase: phase, modifiers: event_mods(ns_event) };
let window_event = WindowEvent::MouseWheel(delta, phase);
Some(into_event(window_event))
},
appkit::NSEventTypePressure => {
let pressure = ns_event.pressure();
let stage = ns_event.stage();
let window_event = WindowEvent::TouchpadPressure { device_id: DEVICE_ID, pressure: pressure, stage: stage };
let window_event = WindowEvent::TouchpadPressure(pressure, stage);
Some(into_event(window_event))
},
appkit::NSApplicationDefined => match ns_event.subtype() {
appkit::NSEventSubtype::NSApplicationActivatedEventType => {
Some(Event::Awakened)
Some(into_event(WindowEvent::Awakened))
},
_ => None,
},
@@ -514,37 +483,10 @@ impl EventsLoop {
}
}
pub fn create_proxy(&self) -> Proxy {
Proxy {}
}
}
impl Proxy {
pub fn wakeup(&self) -> Result<(), EventsLoopClosed> {
// Awaken the event loop by triggering `NSApplicationActivatedEventType`.
unsafe {
let pool = foundation::NSAutoreleasePool::new(cocoa::base::nil);
let event =
NSEvent::otherEventWithType_location_modifierFlags_timestamp_windowNumber_context_subtype_data1_data2_(
cocoa::base::nil,
appkit::NSApplicationDefined,
foundation::NSPoint::new(0.0, 0.0),
appkit::NSEventModifierFlags::empty(),
0.0,
0,
cocoa::base::nil,
appkit::NSEventSubtype::NSApplicationActivatedEventType,
0,
0);
appkit::NSApp().postEvent_atStart_(event, cocoa::base::NO);
foundation::NSAutoreleasePool::drain(pool);
}
Ok(())
}
}
pub fn to_virtual_key_code(code: c_ushort) -> Option<events::VirtualKeyCode> {
fn to_virtual_key_code(code: u16) -> Option<events::VirtualKeyCode> {
Some(match code {
0x00 => events::VirtualKeyCode::A,
0x01 => events::VirtualKeyCode::S,
@@ -600,14 +542,14 @@ pub fn to_virtual_key_code(code: c_ushort) -> Option<events::VirtualKeyCode> {
0x33 => events::VirtualKeyCode::Back,
//0x34 => unkown,
0x35 => events::VirtualKeyCode::Escape,
0x36 => events::VirtualKeyCode::LWin,
0x37 => events::VirtualKeyCode::RWin,
0x36 => events::VirtualKeyCode::RWin,
0x37 => events::VirtualKeyCode::LWin,
0x38 => events::VirtualKeyCode::LShift,
//0x39 => Caps lock,
0x3a => events::VirtualKeyCode::LAlt,
//0x3a => Left alt,
0x3b => events::VirtualKeyCode::LControl,
0x3c => events::VirtualKeyCode::RShift,
0x3d => events::VirtualKeyCode::RAlt,
//0x3d => Right alt,
0x3e => events::VirtualKeyCode::RControl,
//0x3f => Fn key,
//0x40 => F17 Key,
@@ -675,51 +617,18 @@ pub fn to_virtual_key_code(code: c_ushort) -> Option<events::VirtualKeyCode> {
0x7e => events::VirtualKeyCode::Up,
//0x7f => unkown,
0xa => events::VirtualKeyCode::Caret,
_ => return None,
})
}
pub fn event_mods(event: cocoa::base::id) -> ModifiersState {
fn event_mods(event: cocoa::base::id) -> ModifiersState {
let flags = unsafe {
NSEvent::modifierFlags(event)
};
ModifiersState {
shift: flags.contains(NSEventModifierFlags::NSShiftKeyMask),
ctrl: flags.contains(NSEventModifierFlags::NSControlKeyMask),
alt: flags.contains(NSEventModifierFlags::NSAlternateKeyMask),
logo: flags.contains(NSEventModifierFlags::NSCommandKeyMask),
shift: flags.contains(appkit::NSShiftKeyMask),
ctrl: flags.contains(appkit::NSControlKeyMask),
alt: flags.contains(appkit::NSAlternateKeyMask),
logo: flags.contains(appkit::NSCommandKeyMask),
}
}
unsafe fn modifier_event(
ns_event: cocoa::base::id,
keymask: NSEventModifierFlags,
was_key_pressed: bool,
) -> Option<WindowEvent> {
if !was_key_pressed && NSEvent::modifierFlags(ns_event).contains(keymask)
|| was_key_pressed && !NSEvent::modifierFlags(ns_event).contains(keymask) {
let state = if was_key_pressed {
ElementState::Released
} else {
ElementState::Pressed
};
let keycode = NSEvent::keyCode(ns_event);
let scancode = keycode as u32;
let virtual_keycode = to_virtual_key_code(keycode);
Some(WindowEvent::KeyboardInput {
device_id: DEVICE_ID,
input: KeyboardInput {
state,
scancode,
virtual_keycode,
modifiers: event_mods(ns_event),
},
})
} else {
None
}
}
// Constant device ID, to be removed when this backend is updated to report real device IDs.
pub const DEVICE_ID: ::DeviceId = ::DeviceId(DeviceId);

107
src/platform/macos/ffi.rs
View File

@@ -1,107 +0,0 @@
// TODO: Upstream these
#![allow(dead_code, non_snake_case, non_upper_case_globals)]
use cocoa::base::id;
use cocoa::foundation::{NSInteger, NSUInteger};
use objc;
pub const NSNotFound: NSInteger = NSInteger::max_value();
#[repr(C)]
pub struct NSRange {
pub location: NSUInteger,
pub length: NSUInteger,
}
impl NSRange {
#[inline]
pub fn new(location: NSUInteger, length: NSUInteger) -> NSRange {
NSRange { location, length }
}
}
unsafe impl objc::Encode for NSRange {
fn encode() -> objc::Encoding {
let encoding = format!(
// TODO: Verify that this is correct
"{{NSRange={}{}}}",
NSUInteger::encode().as_str(),
NSUInteger::encode().as_str(),
);
unsafe { objc::Encoding::from_str(&encoding) }
}
}
pub trait NSMutableAttributedString: Sized {
unsafe fn alloc(_: Self) -> id {
msg_send![class!(NSMutableAttributedString), alloc]
}
unsafe fn init(self) -> id; // *mut NSMutableAttributedString
unsafe fn initWithString(self, string: id) -> id;
unsafe fn initWithAttributedString(self, string: id) -> id;
unsafe fn string(self) -> id; // *mut NSString
unsafe fn mutableString(self) -> id; // *mut NSMutableString
unsafe fn length(self) -> NSUInteger;
}
impl NSMutableAttributedString for id {
unsafe fn init(self) -> id {
msg_send![self, init]
}
unsafe fn initWithString(self, string: id) -> id {
msg_send![self, initWithString:string]
}
unsafe fn initWithAttributedString(self, string: id) -> id {
msg_send![self, initWithAttributedString:string]
}
unsafe fn string(self) -> id {
msg_send![self, string]
}
unsafe fn mutableString(self) -> id {
msg_send![self, mutableString]
}
unsafe fn length(self) -> NSUInteger {
msg_send![self, length]
}
}
pub const kCGBaseWindowLevelKey: NSInteger = 0;
pub const kCGMinimumWindowLevelKey: NSInteger = 1;
pub const kCGDesktopWindowLevelKey: NSInteger = 2;
pub const kCGBackstopMenuLevelKey: NSInteger = 3;
pub const kCGNormalWindowLevelKey: NSInteger = 4;
pub const kCGFloatingWindowLevelKey: NSInteger = 5;
pub const kCGTornOffMenuWindowLevelKey: NSInteger = 6;
pub const kCGDockWindowLevelKey: NSInteger = 7;
pub const kCGMainMenuWindowLevelKey: NSInteger = 8;
pub const kCGStatusWindowLevelKey: NSInteger = 9;
pub const kCGModalPanelWindowLevelKey: NSInteger = 10;
pub const kCGPopUpMenuWindowLevelKey: NSInteger = 11;
pub const kCGDraggingWindowLevelKey: NSInteger = 12;
pub const kCGScreenSaverWindowLevelKey: NSInteger = 13;
pub const kCGMaximumWindowLevelKey: NSInteger = 14;
pub const kCGOverlayWindowLevelKey: NSInteger = 15;
pub const kCGHelpWindowLevelKey: NSInteger = 16;
pub const kCGUtilityWindowLevelKey: NSInteger = 17;
pub const kCGDesktopIconWindowLevelKey: NSInteger = 18;
pub const kCGCursorWindowLevelKey: NSInteger = 19;
pub const kCGNumberOfWindowLevelKeys: NSInteger = 20;
pub enum NSWindowLevel {
NSNormalWindowLevel = kCGBaseWindowLevelKey as _,
NSFloatingWindowLevel = kCGFloatingWindowLevelKey as _,
NSTornOffMenuWindowLevel = kCGTornOffMenuWindowLevelKey as _,
NSModalPanelWindowLevel = kCGModalPanelWindowLevelKey as _,
NSMainMenuWindowLevel = kCGMainMenuWindowLevelKey as _,
NSStatusWindowLevel = kCGStatusWindowLevelKey as _,
NSPopUpMenuWindowLevel = kCGPopUpMenuWindowLevelKey as _,
NSScreenSaverWindowLevel = kCGScreenSaverWindowLevelKey as _,
}

41
src/platform/macos/mod.rs
View File

@@ -1,45 +1,38 @@
#![cfg(target_os = "macos")]
pub use self::events_loop::{EventsLoop, Proxy as EventsLoopProxy};
pub use self::monitor::MonitorId;
pub use self::window::{Id as WindowId, PlatformSpecificWindowBuilderAttributes, Window2};
use std::sync::Arc;
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct DeviceId;
pub use self::events_loop::EventsLoop;
pub use self::monitor::{MonitorId, get_available_monitors, get_primary_monitor};
pub use self::window::{Id as WindowId, PlatformSpecificWindowBuilderAttributes, Window};
use {CreationError};
pub struct Window {
pub window: Arc<Window2>,
pub struct Window2 {
pub window: ::std::sync::Arc<Window>,
}
impl ::std::ops::Deref for Window {
type Target = Window2;
impl ::std::ops::Deref for Window2 {
type Target = Window;
#[inline]
fn deref(&self) -> &Window2 {
fn deref(&self) -> &Window {
&*self.window
}
}
impl Window {
impl Window2 {
pub fn new(events_loop: &EventsLoop,
attributes: ::WindowAttributes,
pl_attribs: PlatformSpecificWindowBuilderAttributes) -> Result<Self, CreationError>
pub fn new(events_loop: ::std::sync::Arc<EventsLoop>,
attributes: &::WindowAttributes,
pl_attribs: &PlatformSpecificWindowBuilderAttributes) -> Result<Self, CreationError>
{
let weak_shared = Arc::downgrade(&events_loop.shared);
let window = Arc::new(try!(Window2::new(weak_shared, attributes, pl_attribs)));
let weak_window = Arc::downgrade(&window);
events_loop.shared.windows.lock().unwrap().push(weak_window);
Ok(Window { window: window })
let weak_events_loop = ::std::sync::Arc::downgrade(&events_loop);
let window = ::std::sync::Arc::new(try!(Window::new(weak_events_loop, attributes, pl_attribs)));
let weak_window = ::std::sync::Arc::downgrade(&window);
events_loop.windows.lock().unwrap().push(weak_window);
Ok(Window2 { window: window })
}
}
mod events_loop;
mod ffi;
mod monitor;
mod util;
mod view;
mod window;

149
src/platform/macos/monitor.rs
View File

@@ -1,147 +1,50 @@
use core_graphics::display;
use std::collections::VecDeque;
use std::fmt;
use native_monitor::NativeMonitorId;
use cocoa::appkit::NSScreen;
use cocoa::base::{id, nil};
use cocoa::foundation::{NSString, NSUInteger};
use core_graphics::display::{CGDirectDisplayID, CGDisplay, CGDisplayBounds};
#[derive(Clone)]
pub struct MonitorId(u32);
use {PhysicalPosition, PhysicalSize};
use super::EventsLoop;
use super::window::{IdRef, Window2};
#[derive(Clone, PartialEq)]
pub struct MonitorId(CGDirectDisplayID);
fn get_available_monitors() -> VecDeque<MonitorId> {
if let Ok(displays) = CGDisplay::active_displays() {
let mut monitors = VecDeque::with_capacity(displays.len());
for d in displays {
monitors.push_back(MonitorId(d));
pub fn get_available_monitors() -> VecDeque<MonitorId> {
let mut monitors = VecDeque::new();
unsafe {
let max_displays = 10u32;
let mut active_displays = [0u32; 10];
let mut display_count = 0;
display::CGGetActiveDisplayList(max_displays, &mut active_displays[0], &mut display_count);
for i in 0..display_count as usize {
monitors.push_back(MonitorId(active_displays[i]));
}
monitors
} else {
VecDeque::with_capacity(0)
}
monitors
}
#[inline]
pub fn get_primary_monitor() -> MonitorId {
let id = MonitorId(CGDisplay::main().id);
let id = unsafe { MonitorId(display::CGMainDisplayID()) };
id
}
impl EventsLoop {
#[inline]
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
get_available_monitors()
}
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
get_primary_monitor()
}
pub fn make_monitor_from_display(id: CGDirectDisplayID) -> MonitorId {
let id = MonitorId(id);
id
}
}
impl Window2 {
#[inline]
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
get_available_monitors()
}
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
get_primary_monitor()
}
}
impl fmt::Debug for MonitorId {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
#[derive(Debug)]
struct MonitorId {
name: Option<String>,
native_identifier: u32,
dimensions: PhysicalSize,
position: PhysicalPosition,
hidpi_factor: f64,
}
let monitor_id_proxy = MonitorId {
name: self.get_name(),
native_identifier: self.get_native_identifier(),
dimensions: self.get_dimensions(),
position: self.get_position(),
hidpi_factor: self.get_hidpi_factor(),
};
monitor_id_proxy.fmt(f)
}
}
impl MonitorId {
pub fn get_name(&self) -> Option<String> {
let MonitorId(display_id) = *self;
let screen_num = CGDisplay::new(display_id).model_number();
let screen_num = unsafe { display::CGDisplayModelNumber(display_id) };
Some(format!("Monitor #{}", screen_num))
}
#[inline]
pub fn get_native_identifier(&self) -> u32 {
self.0
}
pub fn get_dimensions(&self) -> PhysicalSize {
pub fn get_native_identifier(&self) -> NativeMonitorId {
let MonitorId(display_id) = *self;
let display = CGDisplay::new(display_id);
let height = display.pixels_high();
let width = display.pixels_wide();
PhysicalSize::from_logical(
(width as f64, height as f64),
self.get_hidpi_factor(),
)
NativeMonitorId::Numeric(display_id)
}
#[inline]
pub fn get_position(&self) -> PhysicalPosition {
let bounds = unsafe { CGDisplayBounds(self.get_native_identifier()) };
PhysicalPosition::from_logical(
(bounds.origin.x as f64, bounds.origin.y as f64),
self.get_hidpi_factor(),
)
}
pub fn get_hidpi_factor(&self) -> f64 {
let screen = match self.get_nsscreen() {
Some(screen) => screen,
None => return 1.0, // default to 1.0 when we can't find the screen
pub fn get_dimensions(&self) -> (u32, u32) {
let MonitorId(display_id) = *self;
let dimension = unsafe {
let height = display::CGDisplayPixelsHigh(display_id);
let width = display::CGDisplayPixelsWide(display_id);
(width as u32, height as u32)
};
unsafe { NSScreen::backingScaleFactor(screen) as f64 }
}
pub(crate) fn get_nsscreen(&self) -> Option<id> {
unsafe {
let native_id = self.get_native_identifier();
let screens = NSScreen::screens(nil);
let count: NSUInteger = msg_send![screens, count];
let key = IdRef::new(NSString::alloc(nil).init_str("NSScreenNumber"));
let mut matching_screen: Option<id> = None;
for i in 0..count {
let screen = msg_send![screens, objectAtIndex: i as NSUInteger];
let device_description = NSScreen::deviceDescription(screen);
let value: id = msg_send![device_description, objectForKey:*key];
if value != nil {
let screen_number: NSUInteger = msg_send![value, unsignedIntegerValue];
if screen_number as u32 == native_id {
matching_screen = Some(screen);
break;
}
}
}
matching_screen
}
dimension
}
}

38
src/platform/macos/util.rs
View File

@@ -1,38 +0,0 @@
use cocoa::appkit::NSWindowStyleMask;
use cocoa::base::{id, nil};
use cocoa::foundation::{NSRect, NSUInteger};
use core_graphics::display::CGDisplay;
use platform::platform::ffi;
use platform::platform::window::IdRef;
pub const EMPTY_RANGE: ffi::NSRange = ffi::NSRange {
location: ffi::NSNotFound as NSUInteger,
length: 0,
};
// For consistency with other platforms, this will...
// 1. translate the bottom-left window corner into the top-left window corner
// 2. translate the coordinate from a bottom-left origin coordinate system to a top-left one
pub fn bottom_left_to_top_left(rect: NSRect) -> f64 {
CGDisplay::main().pixels_high() as f64 - (rect.origin.y + rect.size.height)
}
pub unsafe fn set_style_mask(window: id, view: id, mask: NSWindowStyleMask) {
use cocoa::appkit::NSWindow;
window.setStyleMask_(mask);
// If we don't do this, key handling will break. Therefore, never call `setStyleMask` directly!
window.makeFirstResponder_(view);
}
pub unsafe fn create_input_context(view: id) -> IdRef {
let input_context: id = msg_send![class!(NSTextInputContext), alloc];
let input_context: id = msg_send![input_context, initWithClient:view];
IdRef::new(input_context)
}
#[allow(dead_code)]
pub unsafe fn open_emoji_picker() {
let app: id = msg_send![class!(NSApplication), sharedApplication];
let _: () = msg_send![app, orderFrontCharacterPalette:nil];
}

574
src/platform/macos/view.rs
View File

@@ -1,574 +0,0 @@
// This is a pretty close port of the implementation in GLFW:
// https://github.com/glfw/glfw/blob/7ef34eb06de54dd9186d3d21a401b2ef819b59e7/src/cocoa_window.m
use std::{slice, str};
use std::boxed::Box;
use std::collections::VecDeque;
use std::os::raw::*;
use std::sync::Weak;
use cocoa::base::{id, nil};
use cocoa::appkit::{NSEvent, NSView, NSWindow};
use cocoa::foundation::{NSPoint, NSRect, NSSize, NSString, NSUInteger};
use objc::declare::ClassDecl;
use objc::runtime::{Class, Object, Protocol, Sel, BOOL, YES};
use {ElementState, Event, KeyboardInput, MouseButton, WindowEvent, WindowId};
use platform::platform::events_loop::{DEVICE_ID, event_mods, Shared, to_virtual_key_code};
use platform::platform::util;
use platform::platform::ffi::*;
use platform::platform::window::{get_window_id, IdRef};
struct ViewState {
window: id,
shared: Weak<Shared>,
ime_spot: Option<(f64, f64)>,
raw_characters: Option<String>,
last_insert: Option<String>,
}
pub fn new_view(window: id, shared: Weak<Shared>) -> IdRef {
let state = ViewState {
window,
shared,
ime_spot: None,
raw_characters: None,
last_insert: None,
};
unsafe {
// This is free'd in `dealloc`
let state_ptr = Box::into_raw(Box::new(state)) as *mut c_void;
let view: id = msg_send![VIEW_CLASS.0, alloc];
IdRef::new(msg_send![view, initWithWinit:state_ptr])
}
}
pub fn set_ime_spot(view: id, input_context: id, x: f64, y: f64) {
unsafe {
let state_ptr: *mut c_void = *(*view).get_mut_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
let content_rect = NSWindow::contentRectForFrameRect_(
state.window,
NSWindow::frame(state.window),
);
let base_x = content_rect.origin.x as f64;
let base_y = (content_rect.origin.y + content_rect.size.height) as f64;
state.ime_spot = Some((base_x + x, base_y - y));
let _: () = msg_send![input_context, invalidateCharacterCoordinates];
}
}
struct ViewClass(*const Class);
unsafe impl Send for ViewClass {}
unsafe impl Sync for ViewClass {}
lazy_static! {
static ref VIEW_CLASS: ViewClass = unsafe {
let superclass = class!(NSView);
let mut decl = ClassDecl::new("WinitView", superclass).unwrap();
decl.add_method(sel!(dealloc), dealloc as extern fn(&Object, Sel));
decl.add_method(
sel!(initWithWinit:),
init_with_winit as extern fn(&Object, Sel, *mut c_void) -> id,
);
decl.add_method(sel!(hasMarkedText), has_marked_text as extern fn(&Object, Sel) -> BOOL);
decl.add_method(
sel!(markedRange),
marked_range as extern fn(&Object, Sel) -> NSRange,
);
decl.add_method(sel!(selectedRange), selected_range as extern fn(&Object, Sel) -> NSRange);
decl.add_method(
sel!(setMarkedText:selectedRange:replacementRange:),
set_marked_text as extern fn(&mut Object, Sel, id, NSRange, NSRange),
);
decl.add_method(sel!(unmarkText), unmark_text as extern fn(&Object, Sel));
decl.add_method(
sel!(validAttributesForMarkedText),
valid_attributes_for_marked_text as extern fn(&Object, Sel) -> id,
);
decl.add_method(
sel!(attributedSubstringForProposedRange:actualRange:),
attributed_substring_for_proposed_range
as extern fn(&Object, Sel, NSRange, *mut c_void) -> id,
);
decl.add_method(
sel!(insertText:replacementRange:),
insert_text as extern fn(&Object, Sel, id, NSRange),
);
decl.add_method(
sel!(characterIndexForPoint:),
character_index_for_point as extern fn(&Object, Sel, NSPoint) -> NSUInteger,
);
decl.add_method(
sel!(firstRectForCharacterRange:actualRange:),
first_rect_for_character_range
as extern fn(&Object, Sel, NSRange, *mut c_void) -> NSRect,
);
decl.add_method(
sel!(doCommandBySelector:),
do_command_by_selector as extern fn(&Object, Sel, Sel),
);
decl.add_method(sel!(keyDown:), key_down as extern fn(&Object, Sel, id));
decl.add_method(sel!(keyUp:), key_up as extern fn(&Object, Sel, id));
decl.add_method(sel!(insertTab:), insert_tab as extern fn(&Object, Sel, id));
decl.add_method(sel!(insertBackTab:), insert_back_tab as extern fn(&Object, Sel, id));
decl.add_method(sel!(mouseDown:), mouse_down as extern fn(&Object, Sel, id));
decl.add_method(sel!(mouseUp:), mouse_up as extern fn(&Object, Sel, id));
decl.add_method(sel!(rightMouseDown:), right_mouse_down as extern fn(&Object, Sel, id));
decl.add_method(sel!(rightMouseUp:), right_mouse_up as extern fn(&Object, Sel, id));
decl.add_method(sel!(otherMouseDown:), other_mouse_down as extern fn(&Object, Sel, id));
decl.add_method(sel!(otherMouseUp:), other_mouse_up as extern fn(&Object, Sel, id));
decl.add_method(sel!(mouseMoved:), mouse_moved as extern fn(&Object, Sel, id));
decl.add_method(sel!(mouseDragged:), mouse_dragged as extern fn(&Object, Sel, id));
decl.add_method(sel!(rightMouseDragged:), right_mouse_dragged as extern fn(&Object, Sel, id));
decl.add_method(sel!(otherMouseDragged:), other_mouse_dragged as extern fn(&Object, Sel, id));
decl.add_method(sel!(_wantsKeyDownForEvent:), wants_key_down_for_event as extern fn(&Object, Sel, id) -> BOOL);
decl.add_ivar::<*mut c_void>("winitState");
decl.add_ivar::<id>("markedText");
let protocol = Protocol::get("NSTextInputClient").unwrap();
decl.add_protocol(&protocol);
ViewClass(decl.register())
};
}
extern fn dealloc(this: &Object, _sel: Sel) {
unsafe {
let state: *mut c_void = *this.get_ivar("winitState");
let marked_text: id = *this.get_ivar("markedText");
let _: () = msg_send![marked_text, release];
Box::from_raw(state as *mut ViewState);
}
}
extern fn init_with_winit(this: &Object, _sel: Sel, state: *mut c_void) -> id {
unsafe {
let this: id = msg_send![this, init];
if this != nil {
(*this).set_ivar("winitState", state);
let marked_text = <id as NSMutableAttributedString>::init(
NSMutableAttributedString::alloc(nil),
);
(*this).set_ivar("markedText", marked_text);
}
this
}
}
extern fn has_marked_text(this: &Object, _sel: Sel) -> BOOL {
//println!("hasMarkedText");
unsafe {
let marked_text: id = *this.get_ivar("markedText");
(marked_text.length() > 0) as i8
}
}
extern fn marked_range(this: &Object, _sel: Sel) -> NSRange {
//println!("markedRange");
unsafe {
let marked_text: id = *this.get_ivar("markedText");
let length = marked_text.length();
if length > 0 {
NSRange::new(0, length - 1)
} else {
util::EMPTY_RANGE
}
}
}
extern fn selected_range(_this: &Object, _sel: Sel) -> NSRange {
//println!("selectedRange");
util::EMPTY_RANGE
}
extern fn set_marked_text(
this: &mut Object,
_sel: Sel,
string: id,
_selected_range: NSRange,
_replacement_range: NSRange,
) {
//println!("setMarkedText");
unsafe {
let marked_text_ref: &mut id = this.get_mut_ivar("markedText");
let _: () = msg_send![(*marked_text_ref), release];
let marked_text = NSMutableAttributedString::alloc(nil);
let has_attr = msg_send![string, isKindOfClass:class!(NSAttributedString)];
if has_attr {
marked_text.initWithAttributedString(string);
} else {
marked_text.initWithString(string);
};
*marked_text_ref = marked_text;
}
}
extern fn unmark_text(this: &Object, _sel: Sel) {
//println!("unmarkText");
unsafe {
let marked_text: id = *this.get_ivar("markedText");
let mutable_string = marked_text.mutableString();
let _: () = msg_send![mutable_string, setString:""];
let input_context: id = msg_send![this, inputContext];
let _: () = msg_send![input_context, discardMarkedText];
}
}
extern fn valid_attributes_for_marked_text(_this: &Object, _sel: Sel) -> id {
//println!("validAttributesForMarkedText");
unsafe { msg_send![class!(NSArray), array] }
}
extern fn attributed_substring_for_proposed_range(
_this: &Object,
_sel: Sel,
_range: NSRange,
_actual_range: *mut c_void, // *mut NSRange
) -> id {
//println!("attributedSubstringForProposedRange");
nil
}
extern fn character_index_for_point(_this: &Object, _sel: Sel, _point: NSPoint) -> NSUInteger {
//println!("characterIndexForPoint");
0
}
extern fn first_rect_for_character_range(
this: &Object,
_sel: Sel,
_range: NSRange,
_actual_range: *mut c_void, // *mut NSRange
) -> NSRect {
//println!("firstRectForCharacterRange");
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
let (x, y) = state.ime_spot.unwrap_or_else(|| {
let content_rect = NSWindow::contentRectForFrameRect_(
state.window,
NSWindow::frame(state.window),
);
let x = content_rect.origin.x;
let y = util::bottom_left_to_top_left(content_rect);
(x, y)
});
NSRect::new(
NSPoint::new(x as _, y as _),
NSSize::new(0.0, 0.0),
)
}
}
extern fn insert_text(this: &Object, _sel: Sel, string: id, _replacement_range: NSRange) {
//println!("insertText");
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
let has_attr = msg_send![string, isKindOfClass:class!(NSAttributedString)];
let characters = if has_attr {
// This is a *mut NSAttributedString
msg_send![string, string]
} else {
// This is already a *mut NSString
string
};
let slice = slice::from_raw_parts(
characters.UTF8String() as *const c_uchar,
characters.len(),
);
let string = str::from_utf8_unchecked(slice);
state.last_insert = Some(string.to_owned());
// We don't need this now, but it's here if that changes.
//let event: id = msg_send![class!(NSApp), currentEvent];
let mut events = VecDeque::with_capacity(characters.len());
for character in string.chars() {
events.push_back(Event::WindowEvent {
window_id: WindowId(get_window_id(state.window)),
event: WindowEvent::ReceivedCharacter(character),
});
}
if let Some(shared) = state.shared.upgrade() {
shared.pending_events
.lock()
.unwrap()
.append(&mut events);
}
}
}
extern fn do_command_by_selector(this: &Object, _sel: Sel, command: Sel) {
//println!("doCommandBySelector");
// Basically, we're sent this message whenever a keyboard event that doesn't generate a "human readable" character
// happens, i.e. newlines, tabs, and Ctrl+C.
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
let shared = if let Some(shared) = state.shared.upgrade() {
shared
} else {
return;
};
let mut events = VecDeque::with_capacity(1);
if command == sel!(insertNewline:) {
// The `else` condition would emit the same character, but I'm keeping this here both...
// 1) as a reminder for how `doCommandBySelector` works
// 2) to make our use of carriage return explicit
events.push_back(Event::WindowEvent {
window_id: WindowId(get_window_id(state.window)),
event: WindowEvent::ReceivedCharacter('\r'),
});
} else {
let raw_characters = state.raw_characters.take();
if let Some(raw_characters) = raw_characters {
for character in raw_characters.chars() {
events.push_back(Event::WindowEvent {
window_id: WindowId(get_window_id(state.window)),
event: WindowEvent::ReceivedCharacter(character),
});
}
}
};
shared.pending_events
.lock()
.unwrap()
.append(&mut events);
}
}
extern fn key_down(this: &Object, _sel: Sel, event: id) {
//println!("keyDown");
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
let window_id = WindowId(get_window_id(state.window));
let keycode: c_ushort = msg_send![event, keyCode];
let virtual_keycode = to_virtual_key_code(keycode);
let scancode = keycode as u32;
let is_repeat = msg_send![event, isARepeat];
let window_event = Event::WindowEvent {
window_id,
event: WindowEvent::KeyboardInput {
device_id: DEVICE_ID,
input: KeyboardInput {
state: ElementState::Pressed,
scancode,
virtual_keycode,
modifiers: event_mods(event),
},
},
};
state.raw_characters = {
let characters: id = msg_send![event, characters];
let slice = slice::from_raw_parts(
characters.UTF8String() as *const c_uchar,
characters.len(),
);
let string = str::from_utf8_unchecked(slice);
Some(string.to_owned())
};
if let Some(shared) = state.shared.upgrade() {
shared.pending_events
.lock()
.unwrap()
.push_back(window_event);
// Emit `ReceivedCharacter` for key repeats
if is_repeat && state.last_insert.is_some() {
let last_insert = state.last_insert.as_ref().unwrap();
for character in last_insert.chars() {
let window_event = Event::WindowEvent {
window_id,
event: WindowEvent::ReceivedCharacter(character),
};
shared.pending_events
.lock()
.unwrap()
.push_back(window_event);
}
} else {
// Some keys (and only *some*, with no known reason) don't trigger `insertText`, while others do...
// So, we don't give repeats the opportunity to trigger that, since otherwise our hack will cause some
// keys to generate twice as many characters.
let array: id = msg_send![class!(NSArray), arrayWithObject:event];
let (): _ = msg_send![this, interpretKeyEvents:array];
}
}
}
}
extern fn key_up(this: &Object, _sel: Sel, event: id) {
//println!("keyUp");
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
state.last_insert = None;
let keycode: c_ushort = msg_send![event, keyCode];
let virtual_keycode = to_virtual_key_code(keycode);
let scancode = keycode as u32;
let window_event = Event::WindowEvent {
window_id: WindowId(get_window_id(state.window)),
event: WindowEvent::KeyboardInput {
device_id: DEVICE_ID,
input: KeyboardInput {
state: ElementState::Released,
scancode,
virtual_keycode,
modifiers: event_mods(event),
},
},
};
if let Some(shared) = state.shared.upgrade() {
shared.pending_events
.lock()
.unwrap()
.push_back(window_event);
}
}
}
extern fn insert_tab(this: &Object, _sel: Sel, _sender: id) {
unsafe {
let window: id = msg_send![this, window];
let first_responder: id = msg_send![window, firstResponder];
let this_ptr = this as *const _ as *mut _;
if first_responder == this_ptr {
let (): _ = msg_send![window, selectNextKeyView:this];
}
}
}
extern fn insert_back_tab(this: &Object, _sel: Sel, _sender: id) {
unsafe {
let window: id = msg_send![this, window];
let first_responder: id = msg_send![window, firstResponder];
let this_ptr = this as *const _ as *mut _;
if first_responder == this_ptr {
let (): _ = msg_send![window, selectPreviousKeyView:this];
}
}
}
fn mouse_click(this: &Object, event: id, button: MouseButton, button_state: ElementState) {
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
let window_event = Event::WindowEvent {
window_id: WindowId(get_window_id(state.window)),
event: WindowEvent::MouseInput {
device_id: DEVICE_ID,
state: button_state,
button,
modifiers: event_mods(event),
},
};
if let Some(shared) = state.shared.upgrade() {
shared.pending_events
.lock()
.unwrap()
.push_back(window_event);
}
}
}
extern fn mouse_down(this: &Object, _sel: Sel, event: id) {
mouse_click(this, event, MouseButton::Left, ElementState::Pressed);
}
extern fn mouse_up(this: &Object, _sel: Sel, event: id) {
mouse_click(this, event, MouseButton::Left, ElementState::Released);
}
extern fn right_mouse_down(this: &Object, _sel: Sel, event: id) {
mouse_click(this, event, MouseButton::Right, ElementState::Pressed);
}
extern fn right_mouse_up(this: &Object, _sel: Sel, event: id) {
mouse_click(this, event, MouseButton::Right, ElementState::Released);
}
extern fn other_mouse_down(this: &Object, _sel: Sel, event: id) {
mouse_click(this, event, MouseButton::Middle, ElementState::Pressed);
}
extern fn other_mouse_up(this: &Object, _sel: Sel, event: id) {
mouse_click(this, event, MouseButton::Middle, ElementState::Released);
}
fn mouse_motion(this: &Object, event: id) {
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
// We have to do this to have access to the `NSView` trait...
let view: id = this as *const _ as *mut _;
let window_point = event.locationInWindow();
let view_point = view.convertPoint_fromView_(window_point, nil);
let view_rect = NSView::frame(view);
if view_point.x.is_sign_negative()
|| view_point.y.is_sign_negative()
|| view_point.x > view_rect.size.width
|| view_point.y > view_rect.size.height {
// Point is outside of the client area (view)
return;
}
let x = view_point.x as f64;
let y = view_rect.size.height as f64 - view_point.y as f64;
let window_event = Event::WindowEvent {
window_id: WindowId(get_window_id(state.window)),
event: WindowEvent::CursorMoved {
device_id: DEVICE_ID,
position: (x, y).into(),
modifiers: event_mods(event),
},
};
if let Some(shared) = state.shared.upgrade() {
shared.pending_events
.lock()
.unwrap()
.push_back(window_event);
}
}
}
extern fn mouse_moved(this: &Object, _sel: Sel, event: id) {
mouse_motion(this, event);
}
extern fn mouse_dragged(this: &Object, _sel: Sel, event: id) {
mouse_motion(this, event);
}
extern fn right_mouse_dragged(this: &Object, _sel: Sel, event: id) {
mouse_motion(this, event);
}
extern fn other_mouse_dragged(this: &Object, _sel: Sel, event: id) {
mouse_motion(this, event);
}
// https://github.com/chromium/chromium/blob/a86a8a6bcfa438fa3ac2eba6f02b3ad1f8e0756f/ui/views/cocoa/bridged_content_view.mm#L816
extern fn wants_key_down_for_event(_this: &Object, _se: Sel, _event: id) -> BOOL {
YES
}

1146
src/platform/macos/window.rs
View File

File diff suppressed because it is too large Load Diff

10
src/platform/mod.rs
View File

@@ -3,7 +3,7 @@ pub use self::platform::*;
#[cfg(target_os = "windows")]
#[path="windows/mod.rs"]
mod platform;
#[cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "netbsd", target_os = "openbsd"))]
#[cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd"))]
#[path="linux/mod.rs"]
mod platform;
#[cfg(target_os = "macos")]
@@ -15,12 +15,8 @@ mod platform;
#[cfg(target_os = "ios")]
#[path="ios/mod.rs"]
mod platform;
#[cfg(target_os = "emscripten")]
#[path="emscripten/mod.rs"]
mod platform;
#[cfg(all(not(target_os = "ios"), not(target_os = "windows"), not(target_os = "linux"),
not(target_os = "macos"), not(target_os = "android"), not(target_os = "dragonfly"),
not(target_os = "freebsd"), not(target_os = "netbsd"), not(target_os = "openbsd"),
not(target_os = "emscripten")))]
compile_error!("The platform you're compiling for is not supported by winit");
not(target_os = "freebsd"), not(target_os = "openbsd")))]
use this_platform_is_not_supported;

407
src/platform/windows/callback.rs Normal file
View File

@@ -0,0 +1,407 @@
use std::mem;
use std::ptr;
use std::cell::RefCell;
use std::sync::mpsc::Sender;
use std::sync::{Arc, Mutex};
use std::ffi::OsString;
use std::os::windows::ffi::OsStringExt;
use CursorState;
use WindowEvent as Event;
use events::ModifiersState;
use super::event;
use super::WindowState;
use user32;
use shell32;
use winapi;
/// There's no parameters passed to the callback function, so it needs to get
/// its context (the HWND, the Sender for events, etc.) stashed in
/// a thread-local variable.
thread_local!(pub static CONTEXT_STASH: RefCell<Option<ThreadLocalData>> = RefCell::new(None));
pub struct ThreadLocalData {
pub win: winapi::HWND,
pub sender: Sender<Event>,
pub window_state: Arc<Mutex<WindowState>>,
pub mouse_in_window: bool
}
/// Equivalent to the windows api [MINMAXINFO](https://msdn.microsoft.com/en-us/library/windows/desktop/ms632605%28v=vs.85%29.aspx)
/// struct. Used because winapi-rs doesn't have this declared.
#[repr(C)]
#[allow(dead_code)]
struct MinMaxInfo {
reserved: winapi::POINT, // Do not use/change
max_size: winapi::POINT,
max_position: winapi::POINT,
min_track: winapi::POINT,
max_track: winapi::POINT
}
/// Checks that the window is the good one, and if so send the event to it.
fn send_event(input_window: winapi::HWND, event: Event) {
CONTEXT_STASH.with(|context_stash| {
let context_stash = context_stash.borrow();
let stored = match *context_stash {
None => return,
Some(ref v) => v
};
let &ThreadLocalData { ref win, ref sender, .. } = stored;
if win != &input_window {
return;
}
sender.send(event).ok(); // ignoring if closed
});
}
/// 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 unsafe extern "system" fn callback(window: winapi::HWND, msg: winapi::UINT,
wparam: winapi::WPARAM, lparam: winapi::LPARAM)
-> winapi::LRESULT
{
match msg {
winapi::WM_DESTROY => {
use events::WindowEvent::Closed;
CONTEXT_STASH.with(|context_stash| {
let context_stash = context_stash.borrow();
let stored = match *context_stash {
None => return,
Some(ref v) => v
};
let &ThreadLocalData { ref win, .. } = stored;
if win == &window {
user32::PostQuitMessage(0);
}
});
send_event(window, Closed);
0
},
winapi::WM_ERASEBKGND => {
1
},
winapi::WM_SIZE => {
use events::WindowEvent::Resized;
let w = winapi::LOWORD(lparam as winapi::DWORD) as u32;
let h = winapi::HIWORD(lparam as winapi::DWORD) as u32;
send_event(window, Resized(w, h));
0
},
winapi::WM_MOVE => {
use events::WindowEvent::Moved;
let x = winapi::LOWORD(lparam as winapi::DWORD) as i32;
let y = winapi::HIWORD(lparam as winapi::DWORD) as i32;
send_event(window, Moved(x, y));
0
},
winapi::WM_CHAR => {
use std::mem;
use events::WindowEvent::ReceivedCharacter;
let chr: char = mem::transmute(wparam as u32);
send_event(window, ReceivedCharacter(chr));
0
},
// Prevents default windows menu hotkeys playing unwanted
// "ding" sounds. Alternatively could check for WM_SYSCOMMAND
// with wparam being SC_KEYMENU, but this may prevent some
// other unwanted default hotkeys as well.
winapi::WM_SYSCHAR => {
0
}
winapi::WM_MOUSEMOVE => {
use events::WindowEvent::{MouseEntered, MouseMoved};
let mouse_outside_window = CONTEXT_STASH.with(|context_stash| {
let mut context_stash = context_stash.borrow_mut();
if let Some(context_stash) = context_stash.as_mut() {
if !context_stash.mouse_in_window {
context_stash.mouse_in_window = true;
return true;
}
}
false
});
if mouse_outside_window {
send_event(window, MouseEntered);
// Calling TrackMouseEvent in order to receive mouse leave events.
user32::TrackMouseEvent(&mut winapi::TRACKMOUSEEVENT {
cbSize: mem::size_of::<winapi::TRACKMOUSEEVENT>() as winapi::DWORD,
dwFlags: winapi::TME_LEAVE,
hwndTrack: window,
dwHoverTime: winapi::HOVER_DEFAULT,
});
}
let x = winapi::GET_X_LPARAM(lparam) as i32;
let y = winapi::GET_Y_LPARAM(lparam) as i32;
send_event(window, MouseMoved(x, y));
0
},
winapi::WM_MOUSELEAVE => {
use events::WindowEvent::MouseLeft;
let mouse_in_window = CONTEXT_STASH.with(|context_stash| {
let mut context_stash = context_stash.borrow_mut();
if let Some(context_stash) = context_stash.as_mut() {
if context_stash.mouse_in_window {
context_stash.mouse_in_window = false;
return true;
}
}
false
});
if mouse_in_window {
send_event(window, MouseLeft);
}
0
},
winapi::WM_MOUSEWHEEL => {
use events::WindowEvent::MouseWheel;
use events::MouseScrollDelta::LineDelta;
use events::TouchPhase;
let value = (wparam >> 16) as i16;
let value = value as i32;
let value = value as f32 / winapi::WHEEL_DELTA as f32;
send_event(window, MouseWheel(LineDelta(0.0, value), TouchPhase::Moved));
0
},
winapi::WM_KEYDOWN | winapi::WM_SYSKEYDOWN => {
use events::WindowEvent::KeyboardInput;
use events::ElementState::Pressed;
if msg == winapi::WM_SYSKEYDOWN && wparam as i32 == winapi::VK_F4 {
user32::DefWindowProcW(window, msg, wparam, lparam)
} else {
let (scancode, vkey) = event::vkeycode_to_element(wparam, lparam);
send_event(window, KeyboardInput(Pressed, scancode, vkey, event::get_key_mods()));
0
}
},
winapi::WM_KEYUP | winapi::WM_SYSKEYUP => {
use events::WindowEvent::KeyboardInput;
use events::ElementState::Released;
let (scancode, vkey) = event::vkeycode_to_element(wparam, lparam);
send_event(window, KeyboardInput(Released, scancode, vkey, event::get_key_mods()));
0
},
winapi::WM_LBUTTONDOWN => {
use events::WindowEvent::MouseInput;
use events::MouseButton::Left;
use events::ElementState::Pressed;
send_event(window, MouseInput(Pressed, Left));
0
},
winapi::WM_LBUTTONUP => {
use events::WindowEvent::MouseInput;
use events::MouseButton::Left;
use events::ElementState::Released;
send_event(window, MouseInput(Released, Left));
0
},
winapi::WM_RBUTTONDOWN => {
use events::WindowEvent::MouseInput;
use events::MouseButton::Right;
use events::ElementState::Pressed;
send_event(window, MouseInput(Pressed, Right));
0
},
winapi::WM_RBUTTONUP => {
use events::WindowEvent::MouseInput;
use events::MouseButton::Right;
use events::ElementState::Released;
send_event(window, MouseInput(Released, Right));
0
},
winapi::WM_MBUTTONDOWN => {
use events::WindowEvent::MouseInput;
use events::MouseButton::Middle;
use events::ElementState::Pressed;
send_event(window, MouseInput(Pressed, Middle));
0
},
winapi::WM_MBUTTONUP => {
use events::WindowEvent::MouseInput;
use events::MouseButton::Middle;
use events::ElementState::Released;
send_event(window, MouseInput(Released, Middle));
0
},
winapi::WM_XBUTTONDOWN => {
use events::WindowEvent::MouseInput;
use events::MouseButton::Other;
use events::ElementState::Pressed;
let xbutton = winapi::HIWORD(wparam as winapi::DWORD) as winapi::c_int; // waiting on PR for winapi to add GET_XBUTTON_WPARAM
send_event(window, MouseInput(Pressed, Other(xbutton as u8)));
0
},
winapi::WM_XBUTTONUP => {
use events::WindowEvent::MouseInput;
use events::MouseButton::Other;
use events::ElementState::Released;
let xbutton = winapi::HIWORD(wparam as winapi::DWORD) as winapi::c_int;
send_event(window, MouseInput(Released, Other(xbutton as u8)));
0
},
winapi::WM_INPUT => {
let mut data: winapi::RAWINPUT = mem::uninitialized();
let mut data_size = mem::size_of::<winapi::RAWINPUT>() as winapi::UINT;
user32::GetRawInputData(mem::transmute(lparam), winapi::RID_INPUT,
mem::transmute(&mut data), &mut data_size,
mem::size_of::<winapi::RAWINPUTHEADER>() as winapi::UINT);
if data.header.dwType == winapi::RIM_TYPEMOUSE {
let _x = data.mouse.lLastX; // FIXME: this is not always the relative movement
let _y = data.mouse.lLastY;
// TODO:
//send_event(window, Event::MouseRawMovement { x: x, y: y });
0
} else {
user32::DefWindowProcW(window, msg, wparam, lparam)
}
},
winapi::WM_SETFOCUS => {
use events::WindowEvent::Focused;
send_event(window, Focused(true));
0
},
winapi::WM_KILLFOCUS => {
use events::WindowEvent::Focused;
send_event(window, Focused(false));
0
},
winapi::WM_SETCURSOR => {
let call_def_window_proc = CONTEXT_STASH.with(|context_stash| {
let cstash = context_stash.borrow();
let mut call_def_window_proc = false;
if let Some(cstash) = cstash.as_ref() {
if let Ok(window_state) = cstash.window_state.lock() {
if cstash.mouse_in_window {
match window_state.cursor_state {
CursorState::Normal => {
user32::SetCursor(user32::LoadCursorW(
ptr::null_mut(),
window_state.cursor));
},
CursorState::Grab | CursorState::Hide => {
user32::SetCursor(ptr::null_mut());
}
}
} else {
call_def_window_proc = true;
}
}
}
call_def_window_proc
});
if call_def_window_proc {
user32::DefWindowProcW(window, msg, wparam, lparam)
} else {
0
}
},
winapi::WM_DROPFILES => {
use events::WindowEvent::DroppedFile;
let hdrop = wparam as winapi::HDROP;
let mut pathbuf: [u16; winapi::MAX_PATH] = mem::uninitialized();
let num_drops = shell32::DragQueryFileW(hdrop, 0xFFFFFFFF, ptr::null_mut(), 0);
for i in 0..num_drops {
let nch = shell32::DragQueryFileW(hdrop, i, pathbuf.as_mut_ptr(),
winapi::MAX_PATH as u32) as usize;
if nch > 0 {
send_event(window, DroppedFile(OsString::from_wide(&pathbuf[0..nch]).into()));
}
}
shell32::DragFinish(hdrop);
0
},
winapi::WM_GETMINMAXINFO => {
let mmi = lparam as *mut MinMaxInfo;
//(*mmi).max_position = winapi::POINT { x: -8, y: -8 }; // The upper left corner of the window if it were maximized on the primary monitor.
//(*mmi).max_size = winapi::POINT { x: .., y: .. }; // The dimensions of the primary monitor.
CONTEXT_STASH.with(|context_stash| {
match context_stash.borrow().as_ref() {
Some(cstash) => {
let window_state = cstash.window_state.lock().unwrap();
match window_state.attributes.min_dimensions {
Some((width, height)) => {
(*mmi).min_track = winapi::POINT { x: width as i32, y: height as i32 };
},
None => { }
}
match window_state.attributes.max_dimensions {
Some((width, height)) => {
(*mmi).max_track = winapi::POINT { x: width as i32, y: height as i32 };
},
None => { }
}
},
None => { }
}
});
0
},
x if x == *super::WAKEUP_MSG_ID => {
use events::WindowEvent::Awakened;
send_event(window, Awakened);
0
},
_ => {
user32::DefWindowProcW(window, msg, wparam, lparam)
}
}
}

189
src/platform/windows/dpi.rs
View File

@@ -1,189 +0,0 @@
#![allow(non_snake_case, unused_unsafe)]
use std::mem;
use std::os::raw::c_void;
use std::sync::{Once, ONCE_INIT};
use winapi::shared::minwindef::{BOOL, UINT, FALSE};
use winapi::shared::windef::{
DPI_AWARENESS_CONTEXT,
DPI_AWARENESS_CONTEXT_PER_MONITOR_AWARE,
HMONITOR,
HWND,
};
use winapi::shared::winerror::S_OK;
use winapi::um::libloaderapi::{GetProcAddress, LoadLibraryA};
use winapi::um::shellscalingapi::{
MDT_EFFECTIVE_DPI,
MONITOR_DPI_TYPE,
PROCESS_DPI_AWARENESS,
PROCESS_PER_MONITOR_DPI_AWARE,
};
use winapi::um::wingdi::{GetDeviceCaps, LOGPIXELSX};
use winapi::um::winnt::{HRESULT, LPCSTR};
use winapi::um::winuser::{self, MONITOR_DEFAULTTONEAREST};
const DPI_AWARENESS_CONTEXT_PER_MONITOR_AWARE_V2: DPI_AWARENESS_CONTEXT = -4isize as _;
type SetProcessDPIAware = unsafe extern "system" fn () -> BOOL;
type SetProcessDpiAwareness = unsafe extern "system" fn (
value: PROCESS_DPI_AWARENESS,
) -> HRESULT;
type SetProcessDpiAwarenessContext = unsafe extern "system" fn (
value: DPI_AWARENESS_CONTEXT,
) -> BOOL;
type GetDpiForWindow = unsafe extern "system" fn (hwnd: HWND) -> UINT;
type GetDpiForMonitor = unsafe extern "system" fn (
hmonitor: HMONITOR,
dpi_type: MONITOR_DPI_TYPE,
dpi_x: *mut UINT,
dpi_y: *mut UINT,
) -> HRESULT;
type EnableNonClientDpiScaling = unsafe extern "system" fn (hwnd: HWND) -> BOOL;
// Helper function to dynamically load function pointer.
// `library` and `function` must be zero-terminated.
fn get_function_impl(library: &str, function: &str) -> Option<*const c_void> {
assert_eq!(library.chars().last(), Some('\0'));
assert_eq!(function.chars().last(), Some('\0'));
// Library names we will use are ASCII so we can use the A version to avoid string conversion.
let module = unsafe { LoadLibraryA(library.as_ptr() as LPCSTR) };
if module.is_null() {
return None;
}
let function_ptr = unsafe { GetProcAddress(module, function.as_ptr() as LPCSTR) };
if function_ptr.is_null() {
return None;
}
Some(function_ptr as _)
}
macro_rules! get_function {
($lib:expr, $func:ident) => {
get_function_impl(concat!($lib, '\0'), concat!(stringify!($func), '\0'))
.map(|f| unsafe { mem::transmute::<*const _, $func>(f) })
}
}
lazy_static! {
static ref GET_DPI_FOR_WINDOW: Option<GetDpiForWindow> = get_function!(
"user32.dll",
GetDpiForWindow
);
static ref GET_DPI_FOR_MONITOR: Option<GetDpiForMonitor> = get_function!(
"shcore.dll",
GetDpiForMonitor
);
static ref ENABLE_NON_CLIENT_DPI_SCALING: Option<EnableNonClientDpiScaling> = get_function!(
"user32.dll",
EnableNonClientDpiScaling
);
}
pub fn become_dpi_aware(enable: bool) {
if !enable { return; }
static ENABLE_DPI_AWARENESS: Once = ONCE_INIT;
ENABLE_DPI_AWARENESS.call_once(|| { unsafe {
if let Some(SetProcessDpiAwarenessContext) = get_function!(
"user32.dll",
SetProcessDpiAwarenessContext
) {
// We are on Windows 10 Anniversary Update (1607) or later.
if SetProcessDpiAwarenessContext(DPI_AWARENESS_CONTEXT_PER_MONITOR_AWARE_V2)
== FALSE {
// V2 only works with Windows 10 Creators Update (1703). Try using the older
// V1 if we can't set V2.
SetProcessDpiAwarenessContext(DPI_AWARENESS_CONTEXT_PER_MONITOR_AWARE);
}
} else if let Some(SetProcessDpiAwareness) = get_function!(
"shcore.dll",
SetProcessDpiAwareness
) {
// We are on Windows 8.1 or later.
SetProcessDpiAwareness(PROCESS_PER_MONITOR_DPI_AWARE);
} else if let Some(SetProcessDPIAware) = get_function!(
"user32.dll",
SetProcessDPIAware
) {
// We are on Vista or later.
SetProcessDPIAware();
}
} });
}
pub fn enable_non_client_dpi_scaling(hwnd: HWND) {
unsafe {
if let Some(EnableNonClientDpiScaling) = *ENABLE_NON_CLIENT_DPI_SCALING {
EnableNonClientDpiScaling(hwnd);
}
}
}
pub fn get_monitor_dpi(hmonitor: HMONITOR) -> Option<u32> {
unsafe {
if let Some(GetDpiForMonitor) = *GET_DPI_FOR_MONITOR {
// We are on Windows 8.1 or later.
let mut dpi_x = 0;
let mut dpi_y = 0;
if GetDpiForMonitor(hmonitor, MDT_EFFECTIVE_DPI, &mut dpi_x, &mut dpi_y) == S_OK {
// MSDN says that "the values of *dpiX and *dpiY are identical. You only need to
// record one of the values to determine the DPI and respond appropriately".
// https://msdn.microsoft.com/en-us/library/windows/desktop/dn280510(v=vs.85).aspx
return Some(dpi_x as u32)
}
}
}
None
}
pub const BASE_DPI: u32 = 96;
pub fn dpi_to_scale_factor(dpi: u32) -> f64 {
dpi as f64 / BASE_DPI as f64
}
pub unsafe fn get_hwnd_dpi(hwnd: HWND) -> u32 {
let hdc = winuser::GetDC(hwnd);
if hdc.is_null() {
panic!("[winit] `GetDC` returned null!");
}
if let Some(GetDpiForWindow) = *GET_DPI_FOR_WINDOW {
// We are on Windows 10 Anniversary Update (1607) or later.
match GetDpiForWindow(hwnd) {
0 => BASE_DPI, // 0 is returned if hwnd is invalid
dpi => dpi as u32,
}
} else if let Some(GetDpiForMonitor) = *GET_DPI_FOR_MONITOR {
// We are on Windows 8.1 or later.
let monitor = winuser::MonitorFromWindow(hwnd, MONITOR_DEFAULTTONEAREST);
if monitor.is_null() {
return BASE_DPI;
}
let mut dpi_x = 0;
let mut dpi_y = 0;
if GetDpiForMonitor(monitor, MDT_EFFECTIVE_DPI, &mut dpi_x, &mut dpi_y) == S_OK {
dpi_x as u32
} else {
BASE_DPI
}
} else {
// We are on Vista or later.
if winuser::IsProcessDPIAware() != FALSE {
// If the process is DPI aware, then scaling must be handled by the application using
// this DPI value.
GetDeviceCaps(hdc, LOGPIXELSX) as u32
} else {
// If the process is DPI unaware, then scaling is performed by the OS; we thus return
// 96 (scale factor 1.0) to prevent the window from being re-scaled by both the
// application and the WM.
BASE_DPI
}
}
}
pub fn get_hwnd_scale_factor(hwnd: HWND) -> f64 {
dpi_to_scale_factor(unsafe { get_hwnd_dpi(hwnd) })
}

363
src/platform/windows/event.rs
View File

@@ -1,82 +1,86 @@
use std::char;
use std::os::raw::c_int;
use events::VirtualKeyCode;
use events::ModifiersState;
use winapi::shared::minwindef::{WPARAM, LPARAM, UINT};
use winapi::um::winuser;
use winapi;
use user32;
use ScanCode;
const MAPVK_VSC_TO_VK_EX: u32 = 3;
pub fn get_key_mods() -> ModifiersState {
let mut mods = ModifiersState::default();
unsafe {
if winuser::GetKeyState(winuser::VK_SHIFT) & (1 << 15) == (1 << 15) {
if user32::GetKeyState(winapi::VK_SHIFT) & (1 << 15) == (1 << 15) {
mods.shift = true;
}
if winuser::GetKeyState(winuser::VK_CONTROL) & (1 << 15) == (1 << 15) {
if user32::GetKeyState(winapi::VK_CONTROL) & (1 << 15) == (1 << 15) {
mods.ctrl = true;
}
if winuser::GetKeyState(winuser::VK_MENU) & (1 << 15) == (1 << 15) {
if user32::GetKeyState(winapi::VK_MENU) & (1 << 15) == (1 << 15) {
mods.alt = true;
}
if (winuser::GetKeyState(winuser::VK_LWIN) | winuser::GetKeyState(winuser::VK_RWIN)) & (1 << 15) == (1 << 15) {
if (user32::GetKeyState(winapi::VK_LWIN) | user32::GetKeyState(winapi::VK_RWIN)) & (1 << 15) == (1 << 15) {
mods.logo = true;
}
}
mods
}
pub fn vkey_to_winit_vkey(vkey: c_int) -> Option<VirtualKeyCode> {
// VK_* codes are documented here https://msdn.microsoft.com/en-us/library/windows/desktop/dd375731(v=vs.85).aspx
match vkey {
//winuser::VK_LBUTTON => Some(VirtualKeyCode::Lbutton),
//winuser::VK_RBUTTON => Some(VirtualKeyCode::Rbutton),
//winuser::VK_CANCEL => Some(VirtualKeyCode::Cancel),
//winuser::VK_MBUTTON => Some(VirtualKeyCode::Mbutton),
//winuser::VK_XBUTTON1 => Some(VirtualKeyCode::Xbutton1),
//winuser::VK_XBUTTON2 => Some(VirtualKeyCode::Xbutton2),
winuser::VK_BACK => Some(VirtualKeyCode::Back),
winuser::VK_TAB => Some(VirtualKeyCode::Tab),
//winuser::VK_CLEAR => Some(VirtualKeyCode::Clear),
winuser::VK_RETURN => Some(VirtualKeyCode::Return),
winuser::VK_LSHIFT => Some(VirtualKeyCode::LShift),
winuser::VK_RSHIFT => Some(VirtualKeyCode::RShift),
winuser::VK_LCONTROL => Some(VirtualKeyCode::LControl),
winuser::VK_RCONTROL => Some(VirtualKeyCode::RControl),
winuser::VK_LMENU => Some(VirtualKeyCode::LAlt),
winuser::VK_RMENU => Some(VirtualKeyCode::RAlt),
winuser::VK_PAUSE => Some(VirtualKeyCode::Pause),
winuser::VK_CAPITAL => Some(VirtualKeyCode::Capital),
winuser::VK_KANA => Some(VirtualKeyCode::Kana),
//winuser::VK_HANGUEL => Some(VirtualKeyCode::Hanguel),
//winuser::VK_HANGUL => Some(VirtualKeyCode::Hangul),
//winuser::VK_JUNJA => Some(VirtualKeyCode::Junja),
//winuser::VK_FINAL => Some(VirtualKeyCode::Final),
//winuser::VK_HANJA => Some(VirtualKeyCode::Hanja),
winuser::VK_KANJI => Some(VirtualKeyCode::Kanji),
winuser::VK_ESCAPE => Some(VirtualKeyCode::Escape),
winuser::VK_CONVERT => Some(VirtualKeyCode::Convert),
winuser::VK_NONCONVERT => Some(VirtualKeyCode::NoConvert),
//winuser::VK_ACCEPT => Some(VirtualKeyCode::Accept),
//winuser::VK_MODECHANGE => Some(VirtualKeyCode::Modechange),
winuser::VK_SPACE => Some(VirtualKeyCode::Space),
winuser::VK_PRIOR => Some(VirtualKeyCode::PageUp),
winuser::VK_NEXT => Some(VirtualKeyCode::PageDown),
winuser::VK_END => Some(VirtualKeyCode::End),
winuser::VK_HOME => Some(VirtualKeyCode::Home),
winuser::VK_LEFT => Some(VirtualKeyCode::Left),
winuser::VK_UP => Some(VirtualKeyCode::Up),
winuser::VK_RIGHT => Some(VirtualKeyCode::Right),
winuser::VK_DOWN => Some(VirtualKeyCode::Down),
//winuser::VK_SELECT => Some(VirtualKeyCode::Select),
//winuser::VK_PRINT => Some(VirtualKeyCode::Print),
//winuser::VK_EXECUTE => Some(VirtualKeyCode::Execute),
winuser::VK_SNAPSHOT => Some(VirtualKeyCode::Snapshot),
winuser::VK_INSERT => Some(VirtualKeyCode::Insert),
winuser::VK_DELETE => Some(VirtualKeyCode::Delete),
//winuser::VK_HELP => Some(VirtualKeyCode::Help),
pub fn vkeycode_to_element(wparam: winapi::WPARAM, lparam: winapi::LPARAM) -> (ScanCode, Option<VirtualKeyCode>) {
let scancode = ((lparam >> 16) & 0xff) as u8;
let extended = (lparam & 0x01000000) != 0;
let vk = match wparam as i32 {
winapi::VK_SHIFT => unsafe { user32::MapVirtualKeyA(scancode as u32, MAPVK_VSC_TO_VK_EX) as i32 },
winapi::VK_CONTROL => if extended { winapi::VK_RCONTROL } else { winapi::VK_LCONTROL },
winapi::VK_MENU => if extended { winapi::VK_RMENU } else { winapi::VK_LMENU },
other => other
};
(scancode, match vk {
//winapi::VK_LBUTTON => Some(VirtualKeyCode::Lbutton),
//winapi::VK_RBUTTON => Some(VirtualKeyCode::Rbutton),
//winapi::VK_CANCEL => Some(VirtualKeyCode::Cancel),
//winapi::VK_MBUTTON => Some(VirtualKeyCode::Mbutton),
//winapi::VK_XBUTTON1 => Some(VirtualKeyCode::Xbutton1),
//winapi::VK_XBUTTON2 => Some(VirtualKeyCode::Xbutton2),
winapi::VK_BACK => Some(VirtualKeyCode::Back),
winapi::VK_TAB => Some(VirtualKeyCode::Tab),
//winapi::VK_CLEAR => Some(VirtualKeyCode::Clear),
winapi::VK_RETURN => Some(VirtualKeyCode::Return),
winapi::VK_LSHIFT => Some(VirtualKeyCode::LShift),
winapi::VK_RSHIFT => Some(VirtualKeyCode::RShift),
winapi::VK_LCONTROL => Some(VirtualKeyCode::LControl),
winapi::VK_RCONTROL => Some(VirtualKeyCode::RControl),
winapi::VK_LMENU => Some(VirtualKeyCode::LMenu),
winapi::VK_RMENU => Some(VirtualKeyCode::RMenu),
winapi::VK_PAUSE => Some(VirtualKeyCode::Pause),
winapi::VK_CAPITAL => Some(VirtualKeyCode::Capital),
winapi::VK_KANA => Some(VirtualKeyCode::Kana),
//winapi::VK_HANGUEL => Some(VirtualKeyCode::Hanguel),
//winapi::VK_HANGUL => Some(VirtualKeyCode::Hangul),
//winapi::VK_JUNJA => Some(VirtualKeyCode::Junja),
//winapi::VK_FINAL => Some(VirtualKeyCode::Final),
//winapi::VK_HANJA => Some(VirtualKeyCode::Hanja),
winapi::VK_KANJI => Some(VirtualKeyCode::Kanji),
winapi::VK_ESCAPE => Some(VirtualKeyCode::Escape),
winapi::VK_CONVERT => Some(VirtualKeyCode::Convert),
winapi::VK_NONCONVERT => Some(VirtualKeyCode::NoConvert),
//winapi::VK_ACCEPT => Some(VirtualKeyCode::Accept),
//winapi::VK_MODECHANGE => Some(VirtualKeyCode::Modechange),
winapi::VK_SPACE => Some(VirtualKeyCode::Space),
winapi::VK_PRIOR => Some(VirtualKeyCode::PageUp),
winapi::VK_NEXT => Some(VirtualKeyCode::PageDown),
winapi::VK_END => Some(VirtualKeyCode::End),
winapi::VK_HOME => Some(VirtualKeyCode::Home),
winapi::VK_LEFT => Some(VirtualKeyCode::Left),
winapi::VK_UP => Some(VirtualKeyCode::Up),
winapi::VK_RIGHT => Some(VirtualKeyCode::Right),
winapi::VK_DOWN => Some(VirtualKeyCode::Down),
//winapi::VK_SELECT => Some(VirtualKeyCode::Select),
//winapi::VK_PRINT => Some(VirtualKeyCode::Print),
//winapi::VK_EXECUTE => Some(VirtualKeyCode::Execute),
winapi::VK_SNAPSHOT => Some(VirtualKeyCode::Snapshot),
winapi::VK_INSERT => Some(VirtualKeyCode::Insert),
winapi::VK_DELETE => Some(VirtualKeyCode::Delete),
//winapi::VK_HELP => Some(VirtualKeyCode::Help),
0x30 => Some(VirtualKeyCode::Key0),
0x31 => Some(VirtualKeyCode::Key1),
0x32 => Some(VirtualKeyCode::Key2),
@@ -113,155 +117,94 @@ pub fn vkey_to_winit_vkey(vkey: c_int) -> Option<VirtualKeyCode> {
0x58 => Some(VirtualKeyCode::X),
0x59 => Some(VirtualKeyCode::Y),
0x5A => Some(VirtualKeyCode::Z),
//winuser::VK_LWIN => Some(VirtualKeyCode::Lwin),
//winuser::VK_RWIN => Some(VirtualKeyCode::Rwin),
winuser::VK_APPS => Some(VirtualKeyCode::Apps),
winuser::VK_SLEEP => Some(VirtualKeyCode::Sleep),
winuser::VK_NUMPAD0 => Some(VirtualKeyCode::Numpad0),
winuser::VK_NUMPAD1 => Some(VirtualKeyCode::Numpad1),
winuser::VK_NUMPAD2 => Some(VirtualKeyCode::Numpad2),
winuser::VK_NUMPAD3 => Some(VirtualKeyCode::Numpad3),
winuser::VK_NUMPAD4 => Some(VirtualKeyCode::Numpad4),
winuser::VK_NUMPAD5 => Some(VirtualKeyCode::Numpad5),
winuser::VK_NUMPAD6 => Some(VirtualKeyCode::Numpad6),
winuser::VK_NUMPAD7 => Some(VirtualKeyCode::Numpad7),
winuser::VK_NUMPAD8 => Some(VirtualKeyCode::Numpad8),
winuser::VK_NUMPAD9 => Some(VirtualKeyCode::Numpad9),
winuser::VK_MULTIPLY => Some(VirtualKeyCode::Multiply),
winuser::VK_ADD => Some(VirtualKeyCode::Add),
//winuser::VK_SEPARATOR => Some(VirtualKeyCode::Separator),
winuser::VK_SUBTRACT => Some(VirtualKeyCode::Subtract),
winuser::VK_DECIMAL => Some(VirtualKeyCode::Decimal),
winuser::VK_DIVIDE => Some(VirtualKeyCode::Divide),
winuser::VK_F1 => Some(VirtualKeyCode::F1),
winuser::VK_F2 => Some(VirtualKeyCode::F2),
winuser::VK_F3 => Some(VirtualKeyCode::F3),
winuser::VK_F4 => Some(VirtualKeyCode::F4),
winuser::VK_F5 => Some(VirtualKeyCode::F5),
winuser::VK_F6 => Some(VirtualKeyCode::F6),
winuser::VK_F7 => Some(VirtualKeyCode::F7),
winuser::VK_F8 => Some(VirtualKeyCode::F8),
winuser::VK_F9 => Some(VirtualKeyCode::F9),
winuser::VK_F10 => Some(VirtualKeyCode::F10),
winuser::VK_F11 => Some(VirtualKeyCode::F11),
winuser::VK_F12 => Some(VirtualKeyCode::F12),
winuser::VK_F13 => Some(VirtualKeyCode::F13),
winuser::VK_F14 => Some(VirtualKeyCode::F14),
winuser::VK_F15 => Some(VirtualKeyCode::F15),
/*winuser::VK_F16 => Some(VirtualKeyCode::F16),
winuser::VK_F17 => Some(VirtualKeyCode::F17),
winuser::VK_F18 => Some(VirtualKeyCode::F18),
winuser::VK_F19 => Some(VirtualKeyCode::F19),
winuser::VK_F20 => Some(VirtualKeyCode::F20),
winuser::VK_F21 => Some(VirtualKeyCode::F21),
winuser::VK_F22 => Some(VirtualKeyCode::F22),
winuser::VK_F23 => Some(VirtualKeyCode::F23),
winuser::VK_F24 => Some(VirtualKeyCode::F24),*/
winuser::VK_NUMLOCK => Some(VirtualKeyCode::Numlock),
winuser::VK_SCROLL => Some(VirtualKeyCode::Scroll),
winuser::VK_BROWSER_BACK => Some(VirtualKeyCode::NavigateBackward),
winuser::VK_BROWSER_FORWARD => Some(VirtualKeyCode::NavigateForward),
winuser::VK_BROWSER_REFRESH => Some(VirtualKeyCode::WebRefresh),
winuser::VK_BROWSER_STOP => Some(VirtualKeyCode::WebStop),
winuser::VK_BROWSER_SEARCH => Some(VirtualKeyCode::WebSearch),
winuser::VK_BROWSER_FAVORITES => Some(VirtualKeyCode::WebFavorites),
winuser::VK_BROWSER_HOME => Some(VirtualKeyCode::WebHome),
winuser::VK_VOLUME_MUTE => Some(VirtualKeyCode::Mute),
winuser::VK_VOLUME_DOWN => Some(VirtualKeyCode::VolumeDown),
winuser::VK_VOLUME_UP => Some(VirtualKeyCode::VolumeUp),
winuser::VK_MEDIA_NEXT_TRACK => Some(VirtualKeyCode::NextTrack),
winuser::VK_MEDIA_PREV_TRACK => Some(VirtualKeyCode::PrevTrack),
winuser::VK_MEDIA_STOP => Some(VirtualKeyCode::MediaStop),
winuser::VK_MEDIA_PLAY_PAUSE => Some(VirtualKeyCode::PlayPause),
winuser::VK_LAUNCH_MAIL => Some(VirtualKeyCode::Mail),
winuser::VK_LAUNCH_MEDIA_SELECT => Some(VirtualKeyCode::MediaSelect),
/*winuser::VK_LAUNCH_APP1 => Some(VirtualKeyCode::Launch_app1),
winuser::VK_LAUNCH_APP2 => Some(VirtualKeyCode::Launch_app2),*/
winuser::VK_OEM_PLUS => Some(VirtualKeyCode::Equals),
winuser::VK_OEM_COMMA => Some(VirtualKeyCode::Comma),
winuser::VK_OEM_MINUS => Some(VirtualKeyCode::Minus),
winuser::VK_OEM_PERIOD => Some(VirtualKeyCode::Period),
winuser::VK_OEM_1 => map_text_keys(vkey),
winuser::VK_OEM_2 => map_text_keys(vkey),
winuser::VK_OEM_3 => map_text_keys(vkey),
winuser::VK_OEM_4 => map_text_keys(vkey),
winuser::VK_OEM_5 => map_text_keys(vkey),
winuser::VK_OEM_6 => map_text_keys(vkey),
winuser::VK_OEM_7 => map_text_keys(vkey),
/*winuser::VK_OEM_8 => Some(VirtualKeyCode::Oem_8), */
winuser::VK_OEM_102 => Some(VirtualKeyCode::OEM102),
/*winuser::VK_PROCESSKEY => Some(VirtualKeyCode::Processkey),
winuser::VK_PACKET => Some(VirtualKeyCode::Packet),
winuser::VK_ATTN => Some(VirtualKeyCode::Attn),
winuser::VK_CRSEL => Some(VirtualKeyCode::Crsel),
winuser::VK_EXSEL => Some(VirtualKeyCode::Exsel),
winuser::VK_EREOF => Some(VirtualKeyCode::Ereof),
winuser::VK_PLAY => Some(VirtualKeyCode::Play),
winuser::VK_ZOOM => Some(VirtualKeyCode::Zoom),
winuser::VK_NONAME => Some(VirtualKeyCode::Noname),
winuser::VK_PA1 => Some(VirtualKeyCode::Pa1),
winuser::VK_OEM_CLEAR => Some(VirtualKeyCode::Oem_clear),*/
//winapi::VK_LWIN => Some(VirtualKeyCode::Lwin),
//winapi::VK_RWIN => Some(VirtualKeyCode::Rwin),
winapi::VK_APPS => Some(VirtualKeyCode::Apps),
winapi::VK_SLEEP => Some(VirtualKeyCode::Sleep),
winapi::VK_NUMPAD0 => Some(VirtualKeyCode::Numpad0),
winapi::VK_NUMPAD1 => Some(VirtualKeyCode::Numpad1),
winapi::VK_NUMPAD2 => Some(VirtualKeyCode::Numpad2),
winapi::VK_NUMPAD3 => Some(VirtualKeyCode::Numpad3),
winapi::VK_NUMPAD4 => Some(VirtualKeyCode::Numpad4),
winapi::VK_NUMPAD5 => Some(VirtualKeyCode::Numpad5),
winapi::VK_NUMPAD6 => Some(VirtualKeyCode::Numpad6),
winapi::VK_NUMPAD7 => Some(VirtualKeyCode::Numpad7),
winapi::VK_NUMPAD8 => Some(VirtualKeyCode::Numpad8),
winapi::VK_NUMPAD9 => Some(VirtualKeyCode::Numpad9),
winapi::VK_MULTIPLY => Some(VirtualKeyCode::Multiply),
winapi::VK_ADD => Some(VirtualKeyCode::Add),
//winapi::VK_SEPARATOR => Some(VirtualKeyCode::Separator),
winapi::VK_SUBTRACT => Some(VirtualKeyCode::Subtract),
winapi::VK_DECIMAL => Some(VirtualKeyCode::Decimal),
winapi::VK_DIVIDE => Some(VirtualKeyCode::Divide),
winapi::VK_F1 => Some(VirtualKeyCode::F1),
winapi::VK_F2 => Some(VirtualKeyCode::F2),
winapi::VK_F3 => Some(VirtualKeyCode::F3),
winapi::VK_F4 => Some(VirtualKeyCode::F4),
winapi::VK_F5 => Some(VirtualKeyCode::F5),
winapi::VK_F6 => Some(VirtualKeyCode::F6),
winapi::VK_F7 => Some(VirtualKeyCode::F7),
winapi::VK_F8 => Some(VirtualKeyCode::F8),
winapi::VK_F9 => Some(VirtualKeyCode::F9),
winapi::VK_F10 => Some(VirtualKeyCode::F10),
winapi::VK_F11 => Some(VirtualKeyCode::F11),
winapi::VK_F12 => Some(VirtualKeyCode::F12),
winapi::VK_F13 => Some(VirtualKeyCode::F13),
winapi::VK_F14 => Some(VirtualKeyCode::F14),
winapi::VK_F15 => Some(VirtualKeyCode::F15),
/*winapi::VK_F16 => Some(VirtualKeyCode::F16),
winapi::VK_F17 => Some(VirtualKeyCode::F17),
winapi::VK_F18 => Some(VirtualKeyCode::F18),
winapi::VK_F19 => Some(VirtualKeyCode::F19),
winapi::VK_F20 => Some(VirtualKeyCode::F20),
winapi::VK_F21 => Some(VirtualKeyCode::F21),
winapi::VK_F22 => Some(VirtualKeyCode::F22),
winapi::VK_F23 => Some(VirtualKeyCode::F23),
winapi::VK_F24 => Some(VirtualKeyCode::F24),*/
winapi::VK_NUMLOCK => Some(VirtualKeyCode::Numlock),
winapi::VK_SCROLL => Some(VirtualKeyCode::Scroll),
winapi::VK_BROWSER_BACK => Some(VirtualKeyCode::NavigateBackward),
winapi::VK_BROWSER_FORWARD => Some(VirtualKeyCode::NavigateForward),
winapi::VK_BROWSER_REFRESH => Some(VirtualKeyCode::WebRefresh),
winapi::VK_BROWSER_STOP => Some(VirtualKeyCode::WebStop),
winapi::VK_BROWSER_SEARCH => Some(VirtualKeyCode::WebSearch),
winapi::VK_BROWSER_FAVORITES => Some(VirtualKeyCode::WebFavorites),
winapi::VK_BROWSER_HOME => Some(VirtualKeyCode::WebHome),
winapi::VK_VOLUME_MUTE => Some(VirtualKeyCode::Mute),
winapi::VK_VOLUME_DOWN => Some(VirtualKeyCode::VolumeDown),
winapi::VK_VOLUME_UP => Some(VirtualKeyCode::VolumeUp),
winapi::VK_MEDIA_NEXT_TRACK => Some(VirtualKeyCode::NextTrack),
winapi::VK_MEDIA_PREV_TRACK => Some(VirtualKeyCode::PrevTrack),
winapi::VK_MEDIA_STOP => Some(VirtualKeyCode::MediaStop),
winapi::VK_MEDIA_PLAY_PAUSE => Some(VirtualKeyCode::PlayPause),
winapi::VK_LAUNCH_MAIL => Some(VirtualKeyCode::Mail),
winapi::VK_LAUNCH_MEDIA_SELECT => Some(VirtualKeyCode::MediaSelect),
/*winapi::VK_LAUNCH_APP1 => Some(VirtualKeyCode::Launch_app1),
winapi::VK_LAUNCH_APP2 => Some(VirtualKeyCode::Launch_app2),*/
winapi::VK_OEM_PLUS => Some(VirtualKeyCode::Equals),
winapi::VK_OEM_COMMA => Some(VirtualKeyCode::Comma),
winapi::VK_OEM_MINUS => Some(VirtualKeyCode::Minus),
winapi::VK_OEM_PERIOD => Some(VirtualKeyCode::Period),
/*winapi::VK_OEM_1 => Some(VirtualKeyCode::Oem_1),
winapi::VK_OEM_2 => Some(VirtualKeyCode::Oem_2),
winapi::VK_OEM_3 => Some(VirtualKeyCode::Oem_3),
winapi::VK_OEM_4 => Some(VirtualKeyCode::Oem_4),
winapi::VK_OEM_5 => Some(VirtualKeyCode::Oem_5),
winapi::VK_OEM_6 => Some(VirtualKeyCode::Oem_6),
winapi::VK_OEM_7 => Some(VirtualKeyCode::Oem_7),
winapi::VK_OEM_8 => Some(VirtualKeyCode::Oem_8), */
winapi::VK_OEM_102 => Some(VirtualKeyCode::OEM102),
/*winapi::VK_PROCESSKEY => Some(VirtualKeyCode::Processkey),
winapi::VK_PACKET => Some(VirtualKeyCode::Packet),
winapi::VK_ATTN => Some(VirtualKeyCode::Attn),
winapi::VK_CRSEL => Some(VirtualKeyCode::Crsel),
winapi::VK_EXSEL => Some(VirtualKeyCode::Exsel),
winapi::VK_EREOF => Some(VirtualKeyCode::Ereof),
winapi::VK_PLAY => Some(VirtualKeyCode::Play),
winapi::VK_ZOOM => Some(VirtualKeyCode::Zoom),
winapi::VK_NONAME => Some(VirtualKeyCode::Noname),
winapi::VK_PA1 => Some(VirtualKeyCode::Pa1),
winapi::VK_OEM_CLEAR => Some(VirtualKeyCode::Oem_clear),*/
_ => None
}
}
pub fn handle_extended_keys(vkey: c_int, mut scancode: UINT, extended: bool) -> Option<(c_int, UINT)> {
// Welcome to hell https://blog.molecular-matters.com/2011/09/05/properly-handling-keyboard-input/
let vkey = match vkey {
winuser::VK_SHIFT => unsafe { winuser::MapVirtualKeyA(
scancode,
winuser::MAPVK_VSC_TO_VK_EX,
) as _ },
winuser::VK_CONTROL => if extended {
winuser::VK_RCONTROL
} else {
winuser::VK_LCONTROL
},
winuser::VK_MENU => if extended {
winuser::VK_RMENU
} else {
winuser::VK_LMENU
},
_ => match scancode {
// This is only triggered when using raw input. Without this check, we get two events whenever VK_PAUSE is
// pressed, the first one having scancode 0x1D but vkey VK_PAUSE...
0x1D if vkey == winuser::VK_PAUSE => return None,
// ...and the second having scancode 0x45 but an unmatched vkey!
0x45 => winuser::VK_PAUSE,
// VK_PAUSE and VK_SCROLL have the same scancode when using modifiers, alongside incorrect vkey values.
0x46 => {
if extended {
scancode = 0x45;
winuser::VK_PAUSE
} else {
winuser::VK_SCROLL
}
},
_ => vkey,
},
};
Some((vkey, scancode))
}
pub fn process_key_params(wparam: WPARAM, lparam: LPARAM) -> Option<(ScanCode, Option<VirtualKeyCode>)> {
let scancode = ((lparam >> 16) & 0xff) as UINT;
let extended = (lparam & 0x01000000) != 0;
handle_extended_keys(wparam as _, scancode, extended)
.map(|(vkey, scancode)| (scancode, vkey_to_winit_vkey(vkey)))
}
// This is needed as windows doesn't properly distinguish
// some virtual key codes for different keyboard layouts
fn map_text_keys(win_virtual_key: i32) -> Option<VirtualKeyCode> {
let char_key = unsafe { winuser::MapVirtualKeyA(win_virtual_key as u32, winuser::MAPVK_VK_TO_CHAR) } & 0x7FFF;
match char::from_u32(char_key) {
Some(';') => Some(VirtualKeyCode::Semicolon),
Some('/') => Some(VirtualKeyCode::Slash),
Some('`') => Some(VirtualKeyCode::Grave),
Some('[') => Some(VirtualKeyCode::LBracket),
Some(']') => Some(VirtualKeyCode::RBracket),
Some('\'') => Some(VirtualKeyCode::Apostrophe),
Some('\\') => Some(VirtualKeyCode::Backslash),
_ => None
}
})
}

1206
src/platform/windows/events_loop.rs
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File diff suppressed because it is too large Load Diff

114
src/platform/windows/icon.rs
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@@ -1,114 +0,0 @@
use std::{self, mem, ptr};
use std::os::windows::ffi::OsStrExt;
use std::path::Path;
use winapi::ctypes::{c_int, wchar_t};
use winapi::shared::minwindef::{BYTE, LPARAM, WPARAM};
use winapi::shared::windef::{HICON, HWND};
use winapi::um::winuser;
use {Pixel, PIXEL_SIZE, Icon};
use platform::platform::util;
impl Pixel {
fn to_bgra(&mut self) {
mem::swap(&mut self.r, &mut self.b);
}
}
#[derive(Debug)]
pub enum IconType {
Small = winuser::ICON_SMALL as isize,
Big = winuser::ICON_BIG as isize,
}
#[derive(Clone, Debug)]
pub struct WinIcon {
pub handle: HICON,
}
unsafe impl Send for WinIcon {}
impl WinIcon {
#[allow(dead_code)]
pub fn from_path<P: AsRef<Path>>(path: P) -> Result<Self, util::WinError> {
let wide_path: Vec<u16> = path.as_ref().as_os_str().encode_wide().collect();
let handle = unsafe {
winuser::LoadImageW(
ptr::null_mut(),
wide_path.as_ptr() as *const wchar_t,
winuser::IMAGE_ICON,
0, // 0 indicates that we want to use the actual width
0, // and height
winuser::LR_LOADFROMFILE,
) as HICON
};
if !handle.is_null() {
Ok(WinIcon { handle })
} else {
Err(util::WinError::from_last_error())
}
}
pub fn from_icon(icon: Icon) -> Result<Self, util::WinError> {
Self::from_rgba(icon.rgba, icon.width, icon.height)
}
pub fn from_rgba(mut rgba: Vec<u8>, width: u32, height: u32) -> Result<Self, util::WinError> {
assert_eq!(rgba.len() % PIXEL_SIZE, 0);
let pixel_count = rgba.len() / PIXEL_SIZE;
assert_eq!(pixel_count, (width * height) as usize);
let mut and_mask = Vec::with_capacity(pixel_count);
let pixels = rgba.as_mut_ptr() as *mut Pixel; // how not to write idiomatic Rust
for pixel_index in 0..pixel_count {
let pixel = unsafe { &mut *pixels.offset(pixel_index as isize) };
and_mask.push(pixel.a.wrapping_sub(std::u8::MAX)); // invert alpha channel
pixel.to_bgra();
}
assert_eq!(and_mask.len(), pixel_count);
let handle = unsafe {
winuser::CreateIcon(
ptr::null_mut(),
width as c_int,
height as c_int,
1,
(PIXEL_SIZE * 8) as BYTE,
and_mask.as_ptr() as *const BYTE,
rgba.as_ptr() as *const BYTE,
) as HICON
};
if !handle.is_null() {
Ok(WinIcon { handle })
} else {
Err(util::WinError::from_last_error())
}
}
pub fn set_for_window(&self, hwnd: HWND, icon_type: IconType) {
unsafe {
winuser::SendMessageW(
hwnd,
winuser::WM_SETICON,
icon_type as WPARAM,
self.handle as LPARAM,
);
}
}
}
impl Drop for WinIcon {
fn drop(&mut self) {
unsafe { winuser::DestroyIcon(self.handle) };
}
}
pub fn unset_for_window(hwnd: HWND, icon_type: IconType) {
unsafe {
winuser::SendMessageW(
hwnd,
winuser::WM_SETICON,
icon_type as WPARAM,
0 as LPARAM,
);
}
}

259
src/platform/windows/init.rs Normal file
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@@ -0,0 +1,259 @@
use std::sync::{Arc, Mutex};
use std::io;
use std::ptr;
use std::mem;
use std::thread;
use super::callback;
use super::WindowState;
use super::Window;
use super::MonitorId;
use super::WindowWrapper;
use super::PlatformSpecificWindowBuilderAttributes;
use CreationError;
use CreationError::OsError;
use CursorState;
use WindowAttributes;
use std::ffi::{OsStr};
use std::os::windows::ffi::OsStrExt;
use std::sync::mpsc::channel;
use winapi;
use kernel32;
use dwmapi;
use user32;
pub fn new_window(window: &WindowAttributes, pl_attribs: &PlatformSpecificWindowBuilderAttributes) -> Result<Window, CreationError> {
let window = window.clone();
let attribs = pl_attribs.clone();
// initializing variables to be sent to the task
let title = OsStr::new(&window.title).encode_wide().chain(Some(0).into_iter())
.collect::<Vec<_>>();
let (tx, rx) = channel();
// `GetMessage` must be called in the same thread as CreateWindow, so we create a new thread
// dedicated to this window.
thread::spawn(move || {
unsafe {
// creating and sending the `Window`
match init(title, &window, attribs) {
Ok(w) => tx.send(Ok(w)).ok(),
Err(e) => {
tx.send(Err(e)).ok();
return;
}
};
// now that the `Window` struct is initialized, the main `Window::new()` function will
// return and this events loop will run in parallel
loop {
let mut msg = mem::uninitialized();
if user32::GetMessageW(&mut msg, ptr::null_mut(), 0, 0) == 0 {
break;
}
user32::TranslateMessage(&msg);
user32::DispatchMessageW(&msg); // calls `callback` (see the callback module)
}
}
});
rx.recv().unwrap()
}
unsafe fn init(title: Vec<u16>, window: &WindowAttributes, pl_attribs: PlatformSpecificWindowBuilderAttributes) -> Result<Window, CreationError> {
// registering the window class
let class_name = register_window_class();
// building a RECT object with coordinates
let mut rect = winapi::RECT {
left: 0, right: window.dimensions.unwrap_or((1024, 768)).0 as winapi::LONG,
top: 0, bottom: window.dimensions.unwrap_or((1024, 768)).1 as winapi::LONG,
};
// switching to fullscreen if necessary
// this means adjusting the window's position so that it overlaps the right monitor,
// and change the monitor's resolution if necessary
if window.monitor.is_some() {
let monitor = window.monitor.as_ref().unwrap();
try!(switch_to_fullscreen(&mut rect, monitor));
}
// computing the style and extended style of the window
let (ex_style, style) = if window.monitor.is_some() || !window.decorations {
(winapi::WS_EX_APPWINDOW,
//winapi::WS_POPUP is incompatible with winapi::WS_CHILD
if pl_attribs.parent.is_some() {
winapi::WS_CLIPSIBLINGS | winapi::WS_CLIPCHILDREN
}
else {
winapi::WS_POPUP | winapi::WS_CLIPSIBLINGS | winapi::WS_CLIPCHILDREN
}
)
} else {
(winapi::WS_EX_APPWINDOW | winapi::WS_EX_WINDOWEDGE,
winapi::WS_OVERLAPPEDWINDOW | winapi::WS_CLIPSIBLINGS | winapi::WS_CLIPCHILDREN)
};
// adjusting the window coordinates using the style
user32::AdjustWindowRectEx(&mut rect, style, 0, ex_style);
// creating the real window this time, by using the functions in `extra_functions`
let real_window = {
let (width, height) = if window.monitor.is_some() || window.dimensions.is_some() {
(Some(rect.right - rect.left), Some(rect.bottom - rect.top))
} else {
(None, None)
};
let (x, y) = if window.monitor.is_some() {
(Some(rect.left), Some(rect.top))
} else {
(None, None)
};
let mut style = if !window.visible {
style
} else {
style | winapi::WS_VISIBLE
};
if pl_attribs.parent.is_some() {
style |= winapi::WS_CHILD;
}
let handle = user32::CreateWindowExW(ex_style | winapi::WS_EX_ACCEPTFILES,
class_name.as_ptr(),
title.as_ptr() as winapi::LPCWSTR,
style | winapi::WS_CLIPSIBLINGS | winapi::WS_CLIPCHILDREN,
x.unwrap_or(winapi::CW_USEDEFAULT), y.unwrap_or(winapi::CW_USEDEFAULT),
width.unwrap_or(winapi::CW_USEDEFAULT), height.unwrap_or(winapi::CW_USEDEFAULT),
pl_attribs.parent.unwrap_or(ptr::null_mut()),
ptr::null_mut(), kernel32::GetModuleHandleW(ptr::null()),
ptr::null_mut());
if handle.is_null() {
return Err(OsError(format!("CreateWindowEx function failed: {}",
format!("{}", io::Error::last_os_error()))));
}
let hdc = user32::GetDC(handle);
if hdc.is_null() {
return Err(OsError(format!("GetDC function failed: {}",
format!("{}", io::Error::last_os_error()))));
}
WindowWrapper(handle, hdc)
};
// making the window transparent
if window.transparent {
let bb = winapi::DWM_BLURBEHIND {
dwFlags: 0x1, // FIXME: DWM_BB_ENABLE;
fEnable: 1,
hRgnBlur: ptr::null_mut(),
fTransitionOnMaximized: 0,
};
dwmapi::DwmEnableBlurBehindWindow(real_window.0, &bb);
}
// calling SetForegroundWindow if fullscreen
if window.monitor.is_some() {
user32::SetForegroundWindow(real_window.0);
}
// Creating a mutex to track the current window state
let window_state = Arc::new(Mutex::new(WindowState {
cursor: winapi::IDC_ARROW, // use arrow by default
cursor_state: CursorState::Normal,
attributes: window.clone()
}));
// filling the CONTEXT_STASH task-local storage so that we can start receiving events
let events_receiver = {
let (tx, rx) = channel();
let mut tx = Some(tx);
callback::CONTEXT_STASH.with(|context_stash| {
let data = callback::ThreadLocalData {
win: real_window.0,
sender: tx.take().unwrap(),
window_state: window_state.clone(),
mouse_in_window: false
};
(*context_stash.borrow_mut()) = Some(data);
});
rx
};
// building the struct
Ok(Window {
window: real_window,
events_receiver: events_receiver,
window_state: window_state,
})
}
unsafe fn register_window_class() -> Vec<u16> {
let class_name = OsStr::new("Window Class").encode_wide().chain(Some(0).into_iter())
.collect::<Vec<_>>();
let class = winapi::WNDCLASSEXW {
cbSize: mem::size_of::<winapi::WNDCLASSEXW>() as winapi::UINT,
style: winapi::CS_HREDRAW | winapi::CS_VREDRAW | winapi::CS_OWNDC,
lpfnWndProc: Some(callback::callback),
cbClsExtra: 0,
cbWndExtra: 0,
hInstance: kernel32::GetModuleHandleW(ptr::null()),
hIcon: ptr::null_mut(),
hCursor: ptr::null_mut(), // must be null in order for cursor state to work properly
hbrBackground: ptr::null_mut(),
lpszMenuName: ptr::null(),
lpszClassName: class_name.as_ptr(),
hIconSm: ptr::null_mut(),
};
// We ignore errors because registering the same window class twice would trigger
// an error, and because errors here are detected during CreateWindowEx anyway.
// Also since there is no weird element in the struct, there is no reason for this
// call to fail.
user32::RegisterClassExW(&class);
class_name
}
unsafe fn switch_to_fullscreen(rect: &mut winapi::RECT, monitor: &MonitorId)
-> Result<(), CreationError>
{
// adjusting the rect
{
let pos = monitor.get_position();
rect.left += pos.0 as winapi::LONG;
rect.right += pos.0 as winapi::LONG;
rect.top += pos.1 as winapi::LONG;
rect.bottom += pos.1 as winapi::LONG;
}
// changing device settings
let mut screen_settings: winapi::DEVMODEW = mem::zeroed();
screen_settings.dmSize = mem::size_of::<winapi::DEVMODEW>() as winapi::WORD;
screen_settings.dmPelsWidth = (rect.right - rect.left) as winapi::DWORD;
screen_settings.dmPelsHeight = (rect.bottom - rect.top) as winapi::DWORD;
screen_settings.dmBitsPerPel = 32; // TODO: ?
screen_settings.dmFields = winapi::DM_BITSPERPEL | winapi::DM_PELSWIDTH | winapi::DM_PELSHEIGHT;
let result = user32::ChangeDisplaySettingsExW(monitor.get_adapter_name().as_ptr(),
&mut screen_settings, ptr::null_mut(),
winapi::CDS_FULLSCREEN, ptr::null_mut());
if result != winapi::DISP_CHANGE_SUCCESSFUL {
return Err(OsError(format!("ChangeDisplaySettings failed: {}", result)));
}
Ok(())
}

403
src/platform/windows/mod.rs
View File

@@ -1,58 +1,385 @@
#![cfg(target_os = "windows")]
use winapi;
use winapi::shared::windef::HWND;
use std::mem;
use std::ptr;
use std::ffi::OsStr;
use std::os::windows::ffi::OsStrExt;
use std::os::raw::c_int;
use std::sync::{
Arc,
Mutex
};
use std::sync::mpsc::Receiver;
use {CreationError, WindowEvent as Event, MouseCursor};
use CursorState;
pub use self::events_loop::{EventsLoop, EventsLoopProxy};
pub use self::monitor::MonitorId;
pub use self::window::Window;
use WindowAttributes;
gen_api_transition!();
#[derive(Clone, Default)]
pub struct PlatformSpecificWindowBuilderAttributes {
pub parent: Option<HWND>,
pub taskbar_icon: Option<::Icon>,
pub no_redirection_bitmap: bool,
pub parent: Option<winapi::HWND>,
}
unsafe impl Send for PlatformSpecificWindowBuilderAttributes {}
unsafe impl Sync for PlatformSpecificWindowBuilderAttributes {}
// Cursor name in UTF-16. Used to set cursor in `WM_SETCURSOR`.
#[derive(Debug, Clone)]
pub struct Cursor(pub *const winapi::ctypes::wchar_t);
unsafe impl Send for Cursor {}
unsafe impl Sync for Cursor {}
#[derive(Clone, Default)]
pub struct PlatformSpecificHeadlessBuilderAttributes;
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct DeviceId(u32);
pub use self::monitor::{MonitorId, get_available_monitors, get_primary_monitor};
impl DeviceId {
pub fn get_persistent_identifier(&self) -> Option<String> {
if self.0 != 0 {
raw_input::get_raw_input_device_name(self.0 as _)
} else {
None
use winapi;
use user32;
use kernel32;
mod callback;
mod event;
mod init;
mod monitor;
lazy_static! {
static ref WAKEUP_MSG_ID: u32 = unsafe { user32::RegisterWindowMessageA("Glutin::EventID".as_ptr() as *const i8) };
}
/// Cursor
pub type Cursor = *const winapi::wchar_t;
/// Contains information about states and the window for the callback.
#[derive(Clone)]
pub struct WindowState {
pub cursor: Cursor,
pub cursor_state: CursorState,
pub attributes: WindowAttributes
}
/// The Win32 implementation of the main `Window` object.
pub struct Window {
/// Main handle for the window.
window: WindowWrapper,
/// Receiver for the events dispatched by the window callback.
events_receiver: Receiver<Event>,
/// The current window state.
window_state: Arc<Mutex<WindowState>>,
}
unsafe impl Send for Window {}
unsafe impl Sync for Window {}
/// A simple wrapper that destroys the window when it is destroyed.
#[doc(hidden)]
pub struct WindowWrapper(winapi::HWND, winapi::HDC);
impl Drop for WindowWrapper {
#[inline]
fn drop(&mut self) {
unsafe {
user32::DestroyWindow(self.0);
}
}
}
// Constant device ID, to be removed when this backend is updated to report real device IDs.
const DEVICE_ID: ::DeviceId = ::DeviceId(DeviceId(0));
fn wrap_device_id(id: u32) -> ::DeviceId {
::DeviceId(DeviceId(id))
#[derive(Clone)]
pub struct WindowProxy {
hwnd: winapi::HWND,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WindowId(HWND);
unsafe impl Send for WindowId {}
unsafe impl Sync for WindowId {}
unsafe impl Send for WindowProxy {}
unsafe impl Sync for WindowProxy {}
mod dpi;
mod event;
mod events_loop;
mod icon;
mod monitor;
mod raw_input;
mod util;
mod window;
impl WindowProxy {
#[inline]
pub fn wakeup_event_loop(&self) {
unsafe {
user32::PostMessageA(self.hwnd, *WAKEUP_MSG_ID, 0, 0);
}
}
}
impl Window {
/// See the docs in the crate root file.
pub fn new(window: &WindowAttributes, pl_attribs: &PlatformSpecificWindowBuilderAttributes)
-> Result<Window, CreationError>
{
init::new_window(window, pl_attribs)
}
/// See the docs in the crate root file.
///
/// Calls SetWindowText on the HWND.
pub fn set_title(&self, text: &str) {
let text = OsStr::new(text).encode_wide().chain(Some(0).into_iter())
.collect::<Vec<_>>();
unsafe {
user32::SetWindowTextW(self.window.0, text.as_ptr() as winapi::LPCWSTR);
}
}
#[inline]
pub fn show(&self) {
unsafe {
user32::ShowWindow(self.window.0, winapi::SW_SHOW);
}
}
#[inline]
pub fn hide(&self) {
unsafe {
user32::ShowWindow(self.window.0, winapi::SW_HIDE);
}
}
/// See the docs in the crate root file.
pub fn get_position(&self) -> Option<(i32, i32)> {
use std::mem;
let mut placement: winapi::WINDOWPLACEMENT = unsafe { mem::zeroed() };
placement.length = mem::size_of::<winapi::WINDOWPLACEMENT>() as winapi::UINT;
if unsafe { user32::GetWindowPlacement(self.window.0, &mut placement) } == 0 {
return None
}
let ref rect = placement.rcNormalPosition;
Some((rect.left as i32, rect.top as i32))
}
/// See the docs in the crate root file.
pub fn set_position(&self, x: i32, y: i32) {
unsafe {
user32::SetWindowPos(self.window.0, ptr::null_mut(), x as c_int, y as c_int,
0, 0, winapi::SWP_NOZORDER | winapi::SWP_NOSIZE);
user32::UpdateWindow(self.window.0);
}
}
/// See the docs in the crate root file.
#[inline]
pub fn get_inner_size(&self) -> Option<(u32, u32)> {
let mut rect: winapi::RECT = unsafe { mem::uninitialized() };
if unsafe { user32::GetClientRect(self.window.0, &mut rect) } == 0 {
return None
}
Some((
(rect.right - rect.left) as u32,
(rect.bottom - rect.top) as u32
))
}
/// See the docs in the crate root file.
#[inline]
pub fn get_outer_size(&self) -> Option<(u32, u32)> {
let mut rect: winapi::RECT = unsafe { mem::uninitialized() };
if unsafe { user32::GetWindowRect(self.window.0, &mut rect) } == 0 {
return None
}
Some((
(rect.right - rect.left) as u32,
(rect.bottom - rect.top) as u32
))
}
/// See the docs in the crate root file.
pub fn set_inner_size(&self, x: u32, y: u32) {
unsafe {
// Calculate the outer size based upon the specified inner size
let mut rect = winapi::RECT { top: 0, left: 0, bottom: y as winapi::LONG, right: x as winapi::LONG };
let dw_style = user32::GetWindowLongA(self.window.0, winapi::GWL_STYLE) as winapi::DWORD;
let b_menu = !user32::GetMenu(self.window.0).is_null() as winapi::BOOL;
let dw_style_ex = user32::GetWindowLongA(self.window.0, winapi::GWL_EXSTYLE) as winapi::DWORD;
user32::AdjustWindowRectEx(&mut rect, dw_style, b_menu, dw_style_ex);
let outer_x = (rect.right - rect.left).abs() as c_int;
let outer_y = (rect.top - rect.bottom).abs() as c_int;
user32::SetWindowPos(self.window.0, ptr::null_mut(), 0, 0, outer_x, outer_y,
winapi::SWP_NOZORDER | winapi::SWP_NOREPOSITION | winapi::SWP_NOMOVE);
user32::UpdateWindow(self.window.0);
}
}
#[inline]
pub fn create_window_proxy(&self) -> WindowProxy {
WindowProxy { hwnd: self.window.0 }
}
/// See the docs in the crate root file.
#[inline]
pub fn poll_events(&self) -> PollEventsIterator {
PollEventsIterator {
window: self,
}
}
/// See the docs in the crate root file.
#[inline]
pub fn wait_events(&self) -> WaitEventsIterator {
WaitEventsIterator {
window: self,
}
}
#[inline]
pub fn platform_display(&self) -> *mut ::libc::c_void {
// What should this return on win32?
// It could be GetDC(NULL), but that requires a ReleaseDC()
// to avoid leaking the DC.
ptr::null_mut()
}
#[inline]
pub fn platform_window(&self) -> *mut ::libc::c_void {
self.window.0 as *mut ::libc::c_void
}
#[inline]
pub fn set_window_resize_callback(&mut self, _: Option<fn(u32, u32)>) {
}
#[inline]
pub fn set_cursor(&self, _cursor: MouseCursor) {
let cursor_id = match _cursor {
MouseCursor::Arrow | MouseCursor::Default => winapi::IDC_ARROW,
MouseCursor::Hand => winapi::IDC_HAND,
MouseCursor::Crosshair => winapi::IDC_CROSS,
MouseCursor::Text | MouseCursor::VerticalText => winapi::IDC_IBEAM,
MouseCursor::NotAllowed | MouseCursor::NoDrop => winapi::IDC_NO,
MouseCursor::EResize => winapi::IDC_SIZEWE,
MouseCursor::NResize => winapi::IDC_SIZENS,
MouseCursor::WResize => winapi::IDC_SIZEWE,
MouseCursor::SResize => winapi::IDC_SIZENS,
MouseCursor::EwResize | MouseCursor::ColResize => winapi::IDC_SIZEWE,
MouseCursor::NsResize | MouseCursor::RowResize => winapi::IDC_SIZENS,
MouseCursor::Wait | MouseCursor::Progress => winapi::IDC_WAIT,
MouseCursor::Help => winapi::IDC_HELP,
_ => winapi::IDC_ARROW, // use arrow for the missing cases.
};
let mut cur = self.window_state.lock().unwrap();
cur.cursor = cursor_id;
}
pub fn set_cursor_state(&self, state: CursorState) -> Result<(), String> {
let mut current_state = self.window_state.lock().unwrap();
let foreground_thread_id = unsafe { user32::GetWindowThreadProcessId(self.window.0, ptr::null_mut()) };
let current_thread_id = unsafe { kernel32::GetCurrentThreadId() };
unsafe { user32::AttachThreadInput(foreground_thread_id, current_thread_id, 1) };
let res = match (state, current_state.cursor_state) {
(CursorState::Normal, CursorState::Normal) => Ok(()),
(CursorState::Hide, CursorState::Hide) => Ok(()),
(CursorState::Grab, CursorState::Grab) => Ok(()),
(CursorState::Hide, CursorState::Normal) => {
current_state.cursor_state = CursorState::Hide;
Ok(())
},
(CursorState::Normal, CursorState::Hide) => {
current_state.cursor_state = CursorState::Normal;
Ok(())
},
(CursorState::Grab, CursorState::Normal) | (CursorState::Grab, CursorState::Hide) => {
unsafe {
let mut rect = mem::uninitialized();
if user32::GetClientRect(self.window.0, &mut rect) == 0 {
return Err(format!("GetWindowRect failed"));
}
user32::ClientToScreen(self.window.0, mem::transmute(&mut rect.left));
user32::ClientToScreen(self.window.0, mem::transmute(&mut rect.right));
if user32::ClipCursor(&rect) == 0 {
return Err(format!("ClipCursor failed"));
}
current_state.cursor_state = CursorState::Grab;
Ok(())
}
},
(CursorState::Normal, CursorState::Grab) => {
unsafe {
if user32::ClipCursor(ptr::null()) == 0 {
return Err(format!("ClipCursor failed"));
}
current_state.cursor_state = CursorState::Normal;
Ok(())
}
},
_ => unimplemented!(),
};
unsafe { user32::AttachThreadInput(foreground_thread_id, current_thread_id, 0) };
res
}
#[inline]
pub fn hidpi_factor(&self) -> f32 {
1.0
}
pub fn set_cursor_position(&self, x: i32, y: i32) -> Result<(), ()> {
let mut point = winapi::POINT {
x: x,
y: y,
};
unsafe {
if user32::ClientToScreen(self.window.0, &mut point) == 0 {
return Err(());
}
if user32::SetCursorPos(point.x, point.y) == 0 {
return Err(());
}
}
Ok(())
}
}
impl Drop for Window {
#[inline]
fn drop(&mut self) {
unsafe {
user32::PostMessageW(self.window.0, winapi::WM_DESTROY, 0, 0);
}
}
}
pub struct PollEventsIterator<'a> {
window: &'a Window,
}
impl<'a> Iterator for PollEventsIterator<'a> {
type Item = Event;
#[inline]
fn next(&mut self) -> Option<Event> {
self.window.events_receiver.try_recv().ok()
}
}
pub struct WaitEventsIterator<'a> {
window: &'a Window,
}
impl<'a> Iterator for WaitEventsIterator<'a> {
type Item = Event;
#[inline]
fn next(&mut self) -> Option<Event> {
self.window.events_receiver.recv().ok()
}
}

313
src/platform/windows/monitor.rs
View File

@@ -1,173 +1,186 @@
use winapi::shared::minwindef::{BOOL, DWORD, LPARAM, TRUE};
use winapi::shared::windef::{HDC, HMONITOR, HWND, LPRECT, POINT};
use winapi::um::winnt::LONG;
use winapi::um::winuser;
use winapi;
use user32;
use std::{mem, ptr};
use std::collections::VecDeque;
use std::mem;
use super::{EventsLoop, util};
use dpi::{PhysicalPosition, PhysicalSize};
use platform::platform::dpi::{dpi_to_scale_factor, get_monitor_dpi};
use platform::platform::window::Window;
use native_monitor::NativeMonitorId;
/// Win32 implementation of the main `MonitorId` object.
#[derive(Debug, Clone)]
#[derive(Clone)]
pub struct MonitorId {
/// Monitor handle.
hmonitor: HMonitor,
/// The system name of the adapter.
adapter_name: [winapi::WCHAR; 32],
/// The system name of the monitor.
monitor_name: String,
/// Name to give to the user.
readable_name: String,
/// See the `StateFlags` element here:
/// http://msdn.microsoft.com/en-us/library/dd183569(v=vs.85).aspx
flags: winapi::DWORD,
/// True if this is the primary monitor.
primary: bool,
/// The position of the monitor in pixels on the desktop.
///
/// A window that is positioned at these coordinates will overlap the monitor.
position: (i32, i32),
/// A window that is positionned at these coordinates will overlap the monitor.
position: (u32, u32),
/// The current resolution in pixels on the monitor.
dimensions: (u32, u32),
/// DPI scale factor.
hidpi_factor: f64,
}
// Send is not implemented for HMONITOR, we have to wrap it and implement it manually.
// For more info see:
// https://github.com/retep998/winapi-rs/issues/360
// https://github.com/retep998/winapi-rs/issues/396
#[derive(Debug, Clone)]
struct HMonitor(HMONITOR);
unsafe impl Send for HMonitor {}
unsafe extern "system" fn monitor_enum_proc(
hmonitor: HMONITOR,
_hdc: HDC,
_place: LPRECT,
data: LPARAM,
) -> BOOL {
let monitors = data as *mut VecDeque<MonitorId>;
(*monitors).push_back(MonitorId::from_hmonitor(hmonitor));
TRUE // continue enumeration
struct DeviceEnumerator {
parent_device: *const winapi::WCHAR,
current_index: u32,
}
pub fn get_available_monitors() -> VecDeque<MonitorId> {
let mut monitors: VecDeque<MonitorId> = VecDeque::new();
unsafe {
winuser::EnumDisplayMonitors(
ptr::null_mut(),
ptr::null_mut(),
Some(monitor_enum_proc),
&mut monitors as *mut _ as LPARAM,
);
}
monitors
}
pub fn get_primary_monitor() -> MonitorId {
const ORIGIN: POINT = POINT { x: 0, y: 0 };
let hmonitor = unsafe {
winuser::MonitorFromPoint(ORIGIN, winuser::MONITOR_DEFAULTTOPRIMARY)
};
MonitorId::from_hmonitor(hmonitor)
}
impl EventsLoop {
// TODO: Investigate opportunities for caching
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
get_available_monitors()
}
pub fn get_current_monitor(hwnd: HWND) -> MonitorId {
let hmonitor = unsafe {
winuser::MonitorFromWindow(hwnd, winuser::MONITOR_DEFAULTTONEAREST)
};
MonitorId::from_hmonitor(hmonitor)
}
pub fn get_primary_monitor(&self) -> MonitorId {
get_primary_monitor()
}
}
impl Window {
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
get_available_monitors()
}
pub fn get_primary_monitor(&self) -> MonitorId {
get_primary_monitor()
}
}
fn get_monitor_info(hmonitor: HMONITOR) -> Result<winuser::MONITORINFOEXW, util::WinError> {
let mut monitor_info: winuser::MONITORINFOEXW = unsafe { mem::uninitialized() };
monitor_info.cbSize = mem::size_of::<winuser::MONITORINFOEXW>() as DWORD;
let status = unsafe {
winuser::GetMonitorInfoW(
hmonitor,
&mut monitor_info as *mut winuser::MONITORINFOEXW as *mut winuser::MONITORINFO,
)
};
if status == 0 {
Err(util::WinError::from_last_error())
} else {
Ok(monitor_info)
}
}
impl MonitorId {
pub(crate) fn from_hmonitor(hmonitor: HMONITOR) -> Self {
let monitor_info = get_monitor_info(hmonitor).expect("`GetMonitorInfoW` failed");
let place = monitor_info.rcMonitor;
let dimensions = (
(place.right - place.left) as u32,
(place.bottom - place.top) as u32,
);
MonitorId {
hmonitor: HMonitor(hmonitor),
monitor_name: util::wchar_ptr_to_string(monitor_info.szDevice.as_ptr()),
primary: util::has_flag(monitor_info.dwFlags, winuser::MONITORINFOF_PRIMARY),
position: (place.left as i32, place.top as i32),
dimensions,
hidpi_factor: dpi_to_scale_factor(get_monitor_dpi(hmonitor).unwrap_or(96)),
impl DeviceEnumerator {
fn adapters() -> DeviceEnumerator {
use std::ptr;
DeviceEnumerator {
parent_device: ptr::null(),
current_index: 0
}
}
pub(crate) fn contains_point(&self, point: &POINT) -> bool {
let left = self.position.0 as LONG;
let right = left + self.dimensions.0 as LONG;
let top = self.position.1 as LONG;
let bottom = top + self.dimensions.1 as LONG;
point.x >= left && point.x <= right && point.y >= top && point.y <= bottom
}
#[inline]
pub fn get_name(&self) -> Option<String> {
Some(self.monitor_name.clone())
}
#[inline]
pub fn get_native_identifier(&self) -> String {
self.monitor_name.clone()
}
#[inline]
pub fn get_hmonitor(&self) -> HMONITOR {
self.hmonitor.0
}
#[inline]
pub fn get_dimensions(&self) -> PhysicalSize {
self.dimensions.into()
}
#[inline]
pub fn get_position(&self) -> PhysicalPosition {
self.position.into()
}
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
self.hidpi_factor
fn monitors(adapter_name: *const winapi::WCHAR) -> DeviceEnumerator {
DeviceEnumerator {
parent_device: adapter_name,
current_index: 0
}
}
}
impl Iterator for DeviceEnumerator {
type Item = winapi::DISPLAY_DEVICEW;
fn next(&mut self) -> Option<winapi::DISPLAY_DEVICEW> {
use std::mem;
loop {
let mut output: winapi::DISPLAY_DEVICEW = unsafe { mem::zeroed() };
output.cb = mem::size_of::<winapi::DISPLAY_DEVICEW>() as winapi::DWORD;
if unsafe { user32::EnumDisplayDevicesW(self.parent_device,
self.current_index as winapi::DWORD, &mut output, 0) } == 0
{
// the device doesn't exist, which means we have finished enumerating
break;
}
self.current_index += 1;
if (output.StateFlags & winapi::DISPLAY_DEVICE_ACTIVE) == 0 ||
(output.StateFlags & winapi::DISPLAY_DEVICE_MIRRORING_DRIVER) != 0
{
// the device is not active
// the Win32 api usually returns a lot of inactive devices
continue;
}
return Some(output);
}
None
}
}
fn wchar_as_string(wchar: &[winapi::WCHAR]) -> String {
String::from_utf16_lossy(wchar)
.trim_right_matches(0 as char)
.to_string()
}
/// Win32 implementation of the main `get_available_monitors` function.
pub fn get_available_monitors() -> VecDeque<MonitorId> {
// return value
let mut result = VecDeque::new();
for adapter in DeviceEnumerator::adapters() {
// getting the position
let (position, dimensions) = unsafe {
let mut dev: winapi::DEVMODEW = mem::zeroed();
dev.dmSize = mem::size_of::<winapi::DEVMODEW>() as winapi::WORD;
if user32::EnumDisplaySettingsExW(adapter.DeviceName.as_ptr(),
winapi::ENUM_CURRENT_SETTINGS,
&mut dev, 0) == 0
{
continue;
}
let point: &winapi::POINTL = mem::transmute(&dev.union1);
let position = (point.x as u32, point.y as u32);
let dimensions = (dev.dmPelsWidth as u32, dev.dmPelsHeight as u32);
(position, dimensions)
};
for (num, monitor) in DeviceEnumerator::monitors(adapter.DeviceName.as_ptr()).enumerate() {
// adding to the resulting list
result.push_back(MonitorId {
adapter_name: adapter.DeviceName,
monitor_name: wchar_as_string(&monitor.DeviceName),
readable_name: wchar_as_string(&monitor.DeviceString),
flags: monitor.StateFlags,
primary: (adapter.StateFlags & winapi::DISPLAY_DEVICE_PRIMARY_DEVICE) != 0 &&
num == 0,
position: position,
dimensions: dimensions,
});
}
}
result
}
/// Win32 implementation of the main `get_primary_monitor` function.
pub fn get_primary_monitor() -> MonitorId {
// we simply get all available monitors and return the one with the `PRIMARY_DEVICE` flag
// TODO: it is possible to query the win32 API for the primary monitor, this should be done
// instead
for monitor in get_available_monitors().into_iter() {
if monitor.primary {
return monitor;
}
}
panic!("Failed to find the primary monitor")
}
impl MonitorId {
/// See the docs if the crate root file.
#[inline]
pub fn get_name(&self) -> Option<String> {
Some(self.readable_name.clone())
}
/// See the docs of the crate root file.
#[inline]
pub fn get_native_identifier(&self) -> NativeMonitorId {
NativeMonitorId::Name(self.monitor_name.clone())
}
/// See the docs if the crate root file.
#[inline]
pub fn get_dimensions(&self) -> (u32, u32) {
// TODO: retreive the dimensions every time this is called
self.dimensions
}
/// This is a Win32-only function for `MonitorId` that returns the system name of the adapter
/// device.
#[inline]
pub fn get_adapter_name(&self) -> &[winapi::WCHAR] {
&self.adapter_name
}
/// This is a Win32-only function for `MonitorId` that returns the position of the
/// monitor on the desktop.
/// A window that is positionned at these coordinates will overlap the monitor.
#[inline]
pub fn get_position(&self) -> (u32, u32) {
self.position
}
}

235
src/platform/windows/raw_input.rs
View File

@@ -1,235 +0,0 @@
use std::mem::{self, size_of};
use std::ptr;
use winapi::ctypes::wchar_t;
use winapi::shared::minwindef::{UINT, USHORT, TRUE};
use winapi::shared::hidusage::{
HID_USAGE_PAGE_GENERIC,
HID_USAGE_GENERIC_MOUSE,
HID_USAGE_GENERIC_KEYBOARD,
};
use winapi::shared::windef::HWND;
use winapi::um::winnt::HANDLE;
use winapi::um::winuser::{
self,
RAWINPUTDEVICELIST,
RID_DEVICE_INFO,
RID_DEVICE_INFO_MOUSE,
RID_DEVICE_INFO_KEYBOARD,
RID_DEVICE_INFO_HID,
RIM_TYPEMOUSE,
RIM_TYPEKEYBOARD,
RIM_TYPEHID,
RIDI_DEVICEINFO,
RIDI_DEVICENAME,
RAWINPUTDEVICE,
RIDEV_DEVNOTIFY,
RIDEV_INPUTSINK,
HRAWINPUT,
RAWINPUT,
RAWINPUTHEADER,
RID_INPUT,
};
use platform::platform::util;
use events::ElementState;
#[allow(dead_code)]
pub fn get_raw_input_device_list() -> Option<Vec<RAWINPUTDEVICELIST>> {
let list_size = size_of::<RAWINPUTDEVICELIST>() as UINT;
let mut num_devices = 0;
let status = unsafe { winuser::GetRawInputDeviceList(
ptr::null_mut(),
&mut num_devices,
list_size,
) };
if status == UINT::max_value() {
return None;
}
let mut buffer = Vec::with_capacity(num_devices as _);
let num_stored = unsafe { winuser::GetRawInputDeviceList(
buffer.as_ptr() as _,
&mut num_devices,
list_size,
) };
if num_stored == UINT::max_value() {
return None;
}
debug_assert_eq!(num_devices, num_stored);
unsafe { buffer.set_len(num_devices as _) };
Some(buffer)
}
#[allow(dead_code)]
pub enum RawDeviceInfo {
Mouse(RID_DEVICE_INFO_MOUSE),
Keyboard(RID_DEVICE_INFO_KEYBOARD),
Hid(RID_DEVICE_INFO_HID),
}
impl From<RID_DEVICE_INFO> for RawDeviceInfo {
fn from(info: RID_DEVICE_INFO) -> Self {
unsafe {
match info.dwType {
RIM_TYPEMOUSE => RawDeviceInfo::Mouse(*info.u.mouse()),
RIM_TYPEKEYBOARD => RawDeviceInfo::Keyboard(*info.u.keyboard()),
RIM_TYPEHID => RawDeviceInfo::Hid(*info.u.hid()),
_ => unreachable!(),
}
}
}
}
#[allow(dead_code)]
pub fn get_raw_input_device_info(handle: HANDLE) -> Option<RawDeviceInfo> {
let mut info: RID_DEVICE_INFO = unsafe { mem::uninitialized() };
let info_size = size_of::<RID_DEVICE_INFO>() as UINT;
info.cbSize = info_size;
let mut minimum_size = 0;
let status = unsafe { winuser::GetRawInputDeviceInfoW(
handle,
RIDI_DEVICEINFO,
&mut info as *mut _ as _,
&mut minimum_size,
) };
if status == UINT::max_value() || status == 0 {
return None;
}
debug_assert_eq!(info_size, status);
Some(info.into())
}
pub fn get_raw_input_device_name(handle: HANDLE) -> Option<String> {
let mut minimum_size = 0;
let status = unsafe { winuser::GetRawInputDeviceInfoW(
handle,
RIDI_DEVICENAME,
ptr::null_mut(),
&mut minimum_size,
) };
if status != 0 {
return None;
}
let mut name: Vec<wchar_t> = Vec::with_capacity(minimum_size as _);
let status = unsafe { winuser::GetRawInputDeviceInfoW(
handle,
RIDI_DEVICENAME,
name.as_ptr() as _,
&mut minimum_size,
) };
if status == UINT::max_value() || status == 0 {
return None;
}
debug_assert_eq!(minimum_size, status);
unsafe { name.set_len(minimum_size as _) };
Some(util::wchar_to_string(&name))
}
pub fn register_raw_input_devices(devices: &[RAWINPUTDEVICE]) -> bool {
let device_size = size_of::<RAWINPUTDEVICE>() as UINT;
let success = unsafe { winuser::RegisterRawInputDevices(
devices.as_ptr() as _,
devices.len() as _,
device_size,
) };
success == TRUE
}
pub fn register_all_mice_and_keyboards_for_raw_input(window_handle: HWND) -> bool {
// RIDEV_DEVNOTIFY: receive hotplug events
// RIDEV_INPUTSINK: receive events even if we're not in the foreground
let flags = RIDEV_DEVNOTIFY | RIDEV_INPUTSINK;
let devices: [RAWINPUTDEVICE; 2] = [
RAWINPUTDEVICE {
usUsagePage: HID_USAGE_PAGE_GENERIC,
usUsage: HID_USAGE_GENERIC_MOUSE,
dwFlags: flags,
hwndTarget: window_handle,
},
RAWINPUTDEVICE {
usUsagePage: HID_USAGE_PAGE_GENERIC,
usUsage: HID_USAGE_GENERIC_KEYBOARD,
dwFlags: flags,
hwndTarget: window_handle,
},
];
register_raw_input_devices(&devices)
}
pub fn get_raw_input_data(handle: HRAWINPUT) -> Option<RAWINPUT> {
let mut data: RAWINPUT = unsafe { mem::uninitialized() };
let mut data_size = size_of::<RAWINPUT>() as UINT;
let header_size = size_of::<RAWINPUTHEADER>() as UINT;
let status = unsafe { winuser::GetRawInputData(
handle,
RID_INPUT,
&mut data as *mut _ as _,
&mut data_size,
header_size,
) };
if status == UINT::max_value() || status == 0 {
return None;
}
Some(data)
}
fn button_flags_to_element_state(button_flags: USHORT, down_flag: USHORT, up_flag: USHORT)
-> Option<ElementState>
{
// We assume the same button won't be simultaneously pressed and released.
if util::has_flag(button_flags, down_flag) {
Some(ElementState::Pressed)
} else if util::has_flag(button_flags, up_flag) {
Some(ElementState::Released)
} else {
None
}
}
pub fn get_raw_mouse_button_state(button_flags: USHORT) -> [Option<ElementState>; 3] {
[
button_flags_to_element_state(
button_flags,
winuser::RI_MOUSE_LEFT_BUTTON_DOWN,
winuser::RI_MOUSE_LEFT_BUTTON_UP,
),
button_flags_to_element_state(
button_flags,
winuser::RI_MOUSE_MIDDLE_BUTTON_DOWN,
winuser::RI_MOUSE_MIDDLE_BUTTON_UP,
),
button_flags_to_element_state(
button_flags,
winuser::RI_MOUSE_RIGHT_BUTTON_DOWN,
winuser::RI_MOUSE_RIGHT_BUTTON_UP,
),
]
}

104
src/platform/windows/util.rs
View File

@@ -1,104 +0,0 @@
use std::{self, mem, ptr, slice};
use std::ops::BitAnd;
use winapi::ctypes::wchar_t;
use winapi::shared::minwindef::{BOOL, DWORD};
use winapi::shared::windef::{HWND, POINT, RECT};
use winapi::um::errhandlingapi::GetLastError;
use winapi::um::winbase::{
FormatMessageW,
FORMAT_MESSAGE_ALLOCATE_BUFFER,
FORMAT_MESSAGE_FROM_SYSTEM,
FORMAT_MESSAGE_IGNORE_INSERTS,
lstrlenW,
LocalFree,
};
use winapi::um::winnt::{
LPCWSTR,
MAKELANGID,
LANG_NEUTRAL,
SUBLANG_DEFAULT,
};
use winapi::um::winuser;
pub fn has_flag<T>(bitset: T, flag: T) -> bool
where T:
Copy + PartialEq + BitAnd<T, Output = T>
{
bitset & flag == flag
}
pub fn wchar_to_string(wchar: &[wchar_t]) -> String {
String::from_utf16_lossy(wchar).to_string()
}
pub fn wchar_ptr_to_string(wchar: *const wchar_t) -> String {
let len = unsafe { lstrlenW(wchar) } as usize;
let wchar_slice = unsafe { slice::from_raw_parts(wchar, len) };
wchar_to_string(wchar_slice)
}
pub unsafe fn status_map<T, F: FnMut(&mut T) -> BOOL>(mut fun: F) -> Option<T> {
let mut data: T = mem::uninitialized();
if fun(&mut data) != 0 {
Some(data)
} else {
None
}
}
pub fn get_cursor_pos() -> Option<POINT> {
unsafe { status_map(|cursor_pos| winuser::GetCursorPos(cursor_pos)) }
}
pub fn get_window_rect(hwnd: HWND) -> Option<RECT> {
unsafe { status_map(|rect| winuser::GetWindowRect(hwnd, rect)) }
}
// This won't be needed anymore if we just add a derive to winapi.
pub fn rect_eq(a: &RECT, b: &RECT) -> bool {
let left_eq = a.left == b.left;
let right_eq = a.right == b.right;
let top_eq = a.top == b.top;
let bottom_eq = a.bottom == b.bottom;
left_eq && right_eq && top_eq && bottom_eq
}
#[derive(Debug, Default, Clone, PartialEq, Eq)]
pub struct WinError(Option<String>);
impl WinError {
pub fn from_last_error() -> Self {
WinError(unsafe { get_last_error() })
}
}
pub unsafe fn get_last_error() -> Option<String> {
let err = GetLastError();
if err != 0 {
let buf_addr: LPCWSTR = {
let mut buf_addr: LPCWSTR = mem::uninitialized();
FormatMessageW(
FORMAT_MESSAGE_ALLOCATE_BUFFER
| FORMAT_MESSAGE_FROM_SYSTEM
| FORMAT_MESSAGE_IGNORE_INSERTS,
ptr::null(),
err,
MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT) as DWORD,
// This is a pointer to a pointer
&mut buf_addr as *mut LPCWSTR as *mut _,
0,
ptr::null_mut(),
);
buf_addr
};
if !buf_addr.is_null() {
let buf_len = lstrlenW(buf_addr) as usize;
let buf_slice = std::slice::from_raw_parts(buf_addr, buf_len);
let string = wchar_to_string(buf_slice);
LocalFree(buf_addr as *mut _);
return Some(string);
}
}
None
}

1171
src/platform/windows/window.rs
View File

File diff suppressed because it is too large Load Diff

413
src/window.rs
View File

@@ -1,19 +1,16 @@
use std::collections::vec_deque::IntoIter as VecDequeIter;
use {
CreationError,
EventsLoop,
Icon,
LogicalPosition,
LogicalSize,
MouseCursor,
PhysicalPosition,
PhysicalSize,
platform,
Window,
WindowBuilder,
WindowId,
};
use CreationError;
use CursorState;
use EventsLoop;
use MouseCursor;
use Window;
use WindowBuilder;
use WindowId;
use native_monitor::NativeMonitorId;
use libc;
use platform;
impl WindowBuilder {
/// Initializes a new `WindowBuilder` with default values.
@@ -26,39 +23,29 @@ impl WindowBuilder {
}
/// Requests the window to be of specific dimensions.
///
/// Width and height are in pixels.
#[inline]
pub fn with_dimensions(mut self, size: LogicalSize) -> WindowBuilder {
self.window.dimensions = Some(size);
pub fn with_dimensions(mut self, width: u32, height: u32) -> WindowBuilder {
self.window.dimensions = Some((width, height));
self
}
/// Sets a minimum dimension size for the window
///
/// Width and height are in pixels.
#[inline]
pub fn with_min_dimensions(mut self, min_size: LogicalSize) -> WindowBuilder {
self.window.min_dimensions = Some(min_size);
pub fn with_min_dimensions(mut self, width: u32, height: u32) -> WindowBuilder {
self.window.min_dimensions = Some((width, height));
self
}
/// Sets a maximum dimension size for the window
///
/// Width and height are in pixels.
#[inline]
pub fn with_max_dimensions(mut self, max_size: LogicalSize) -> WindowBuilder {
self.window.max_dimensions = Some(max_size);
self
}
/// Sets whether the window is resizable or not
///
/// Note that making the window unresizable doesn't exempt you from handling `Resized`, as that event can still be
/// triggered by DPI scaling, entering fullscreen mode, etc.
///
/// ## Platform-specific
///
/// This only has an effect on desktop platforms.
///
/// Due to a bug in XFCE, this has no effect on Xfwm.
#[inline]
pub fn with_resizable(mut self, resizable: bool) -> WindowBuilder {
self.window.resizable = resizable;
pub fn with_max_dimensions(mut self, width: u32, height: u32) -> WindowBuilder {
self.window.max_dimensions = Some((width, height));
self
}
@@ -69,18 +56,13 @@ impl WindowBuilder {
self
}
/// Sets the window fullscreen state. None means a normal window, Some(MonitorId)
/// means a fullscreen window on that specific monitor
/// Requests fullscreen mode.
///
/// If you don't specify dimensions for the window, it will match the monitor's.
#[inline]
pub fn with_fullscreen(mut self, monitor: Option<MonitorId>) -> WindowBuilder {
self.window.fullscreen = monitor;
self
}
/// Requests maximized mode.
#[inline]
pub fn with_maximized(mut self, maximized: bool) -> WindowBuilder {
self.window.maximized = maximized;
pub fn with_fullscreen(mut self, monitor: MonitorId) -> WindowBuilder {
let MonitorId(monitor) = monitor;
self.window.monitor = Some(monitor);
self
}
@@ -105,32 +87,7 @@ impl WindowBuilder {
self
}
/// Sets whether or not the window will always be on top of other windows.
#[inline]
pub fn with_always_on_top(mut self, always_on_top: bool) -> WindowBuilder {
self.window.always_on_top = always_on_top;
self
}
/// Sets the window icon. On Windows and X11, this is typically the small icon in the top-left
/// corner of the titlebar.
///
/// ## Platform-specific
///
/// This only has an effect on Windows and X11.
///
/// On Windows, this sets `ICON_SMALL`. The base size for a window icon is 16x16, but it's
/// recommended to account for screen scaling and pick a multiple of that, i.e. 32x32.
///
/// X11 has no universal guidelines for icon sizes, so you're at the whims of the WM. That
/// said, it's usually in the same ballpark as on Windows.
#[inline]
pub fn with_window_icon(mut self, window_icon: Option<Icon>) -> WindowBuilder {
self.window.window_icon = window_icon;
self
}
/// Enables multitouch.
/// Enables multitouch
#[inline]
pub fn with_multitouch(mut self) -> WindowBuilder {
self.window.multitouch = true;
@@ -141,29 +98,26 @@ impl WindowBuilder {
///
/// Error should be very rare and only occur in case of permission denied, incompatible system,
/// out of memory, etc.
#[inline]
pub fn build(mut self, events_loop: &EventsLoop) -> Result<Window, CreationError> {
self.window.dimensions = Some(self.window.dimensions.unwrap_or_else(|| {
if let Some(ref monitor) = self.window.fullscreen {
// resizing the window to the dimensions of the monitor when fullscreen
LogicalSize::from_physical(monitor.get_dimensions(), 1.0)
} else {
// default dimensions
(1024, 768).into()
}
}));
// resizing the window to the dimensions of the monitor when fullscreen
if self.window.dimensions.is_none() && self.window.monitor.is_some() {
self.window.dimensions = Some(self.window.monitor.as_ref().unwrap().get_dimensions())
}
// default dimensions
if self.window.dimensions.is_none() {
self.window.dimensions = Some((1024, 768));
}
// building
platform::Window::new(
&events_loop.events_loop,
self.window,
self.platform_specific,
).map(|window| Window { window })
let w = try!(platform::Window2::new(events_loop.events_loop.clone(), &self.window, &self.platform_specific));
Ok(Window { window: w })
}
}
impl Window {
/// Creates a new Window for platforms where this is appropriate.
/// Creates a new OpenGL context, and a Window for platforms where this is appropriate.
///
/// This function is equivalent to `WindowBuilder::new().build(events_loop)`.
///
@@ -217,210 +171,125 @@ impl Window {
///
/// Returns `None` if the window no longer exists.
#[inline]
pub fn get_position(&self) -> Option<LogicalPosition> {
pub fn get_position(&self) -> Option<(i32, i32)> {
self.window.get_position()
}
/// Returns the position of the top-left hand corner of the window's client area relative to the
/// top-left hand corner of the desktop.
///
/// The same conditions that apply to `get_position` apply to this method.
#[inline]
pub fn get_inner_position(&self) -> Option<LogicalPosition> {
self.window.get_inner_position()
}
/// Modifies the position of the window.
///
/// See `get_position` for more information about the coordinates.
/// See `get_position` for more informations about the coordinates.
///
/// This is a no-op if the window has already been closed.
#[inline]
pub fn set_position(&self, position: LogicalPosition) {
self.window.set_position(position)
pub fn set_position(&self, x: i32, y: i32) {
self.window.set_position(x, y)
}
/// Returns the logical size of the window's client area.
/// Returns the size in points of the client area of the window.
///
/// The client area is the content of the window, excluding the title bar and borders.
/// To get the dimensions of the frame buffer when calling `glViewport`, multiply with hidpi factor.
///
/// Converting the returned `LogicalSize` to `PhysicalSize` produces the size your framebuffer should be.
/// Returns `None` if the window no longer exists.
///
/// DEPRECATED
#[inline]
pub fn get_inner_size(&self) -> Option<(u32, u32)> {
self.window.get_inner_size()
}
/// Returns the size in points of the client area of the window.
///
/// The client area is the content of the window, excluding the title bar and borders.
/// To get the dimensions of the frame buffer when calling `glViewport`, multiply with hidpi factor.
///
/// Returns `None` if the window no longer exists.
#[inline]
pub fn get_inner_size(&self) -> Option<LogicalSize> {
pub fn get_inner_size_points(&self) -> Option<(u32, u32)> {
self.window.get_inner_size()
}
/// Returns the logical size of the entire window.
/// Returns the size in pixels of the client area of the window.
///
/// These dimensions include the title bar and borders. If you don't want that (and you usually don't),
/// use `get_inner_size` instead.
/// The client area is the content of the window, excluding the title bar and borders.
/// These are the dimensions of the frame buffer, and the dimensions that you should use
/// when you call `glViewport`.
///
/// Returns `None` if the window no longer exists.
#[inline]
pub fn get_outer_size(&self) -> Option<LogicalSize> {
pub fn get_inner_size_pixels(&self) -> Option<(u32, u32)> {
self.window.get_inner_size().map(|(x, y)| {
let hidpi = self.hidpi_factor();
((x as f32 * hidpi) as u32, (y as f32 * hidpi) as u32)
})
}
/// Returns the size in pixels of the window.
///
/// These dimensions include title bar and borders. If you don't want these, you should use
/// use `get_inner_size` instead.
///
/// Returns `None` if the window no longer exists.
#[inline]
pub fn get_outer_size(&self) -> Option<(u32, u32)> {
self.window.get_outer_size()
}
/// Modifies the inner size of the window.
///
/// See `get_inner_size` for more information about the values.
/// See `get_inner_size` for more informations about the values.
///
/// This is a no-op if the window has already been closed.
#[inline]
pub fn set_inner_size(&self, size: LogicalSize) {
self.window.set_inner_size(size)
pub fn set_inner_size(&self, x: u32, y: u32) {
self.window.set_inner_size(x, y)
}
/// Sets a minimum dimension size for the window.
/// DEPRECATED. Gets the native platform specific display for this window.
/// This is typically only required when integrating with
/// other libraries that need this information.
#[deprecated]
#[inline]
pub fn set_min_dimensions(&self, dimensions: Option<LogicalSize>) {
self.window.set_min_dimensions(dimensions)
pub unsafe fn platform_display(&self) -> *mut libc::c_void {
self.window.platform_display()
}
/// Sets a maximum dimension size for the window.
/// DEPRECATED. Gets the native platform specific window handle. This is
/// typically only required when integrating with other libraries
/// that need this information.
#[deprecated]
#[inline]
pub fn set_max_dimensions(&self, dimensions: Option<LogicalSize>) {
self.window.set_max_dimensions(dimensions)
}
/// Sets whether the window is resizable or not.
///
/// Note that making the window unresizable doesn't exempt you from handling `Resized`, as that event can still be
/// triggered by DPI scaling, entering fullscreen mode, etc.
///
/// ## Platform-specific
///
/// This only has an effect on desktop platforms.
///
/// Due to a bug in XFCE, this has no effect on Xfwm.
#[inline]
pub fn set_resizable(&self, resizable: bool) {
self.window.set_resizable(resizable)
}
/// Returns the DPI factor that can be used to map logical pixels to physical pixels, and vice versa.
///
/// See the [`dpi`](dpi/index.html) module for more information.
///
/// Note that this value can change depending on user action (for example if the window is
/// moved to another screen); as such, tracking `WindowEvent::HiDpiFactorChanged` events is
/// the most robust way to track the DPI you need to use to draw.
///
/// ## Platform-specific
///
/// - **X11:** Can be overridden using the `WINIT_HIDPI_FACTOR` environment variable.
/// - **Android:** Always returns 1.0.
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
self.window.get_hidpi_factor()
pub unsafe fn platform_window(&self) -> *mut libc::c_void {
self.window.platform_window()
}
/// Modifies the mouse cursor of the window.
/// Has no effect on Android.
#[inline]
pub fn set_cursor(&self, cursor: MouseCursor) {
self.window.set_cursor(cursor);
}
/// Returns the ratio between the backing framebuffer resolution and the
/// window size in screen pixels. This is typically one for a normal display
/// and two for a retina display.
#[inline]
pub fn hidpi_factor(&self) -> f32 {
self.window.hidpi_factor()
}
/// Changes the position of the cursor in window coordinates.
#[inline]
pub fn set_cursor_position(&self, position: LogicalPosition) -> Result<(), String> {
self.window.set_cursor_position(position)
pub fn set_cursor_position(&self, x: i32, y: i32) -> Result<(), ()> {
self.window.set_cursor_position(x, y)
}
/// Grabs the cursor, preventing it from leaving the window.
/// Sets how glutin handles the cursor. See the documentation of `CursorState` for details.
///
/// ## Platform-specific
///
/// On macOS, this presently merely locks the cursor in a fixed location, which looks visually awkward.
///
/// This has no effect on Android or iOS.
/// Has no effect on Android.
#[inline]
pub fn grab_cursor(&self, grab: bool) -> Result<(), String> {
self.window.grab_cursor(grab)
}
/// Hides the cursor, making it invisible but still usable.
///
/// ## Platform-specific
///
/// On Windows and X11, the cursor is only hidden within the confines of the window.
///
/// On macOS, the cursor is hidden as long as the window has input focus, even if the cursor is outside of the
/// window.
///
/// This has no effect on Android or iOS.
#[inline]
pub fn hide_cursor(&self, hide: bool) {
self.window.hide_cursor(hide)
}
/// Sets the window to maximized or back
#[inline]
pub fn set_maximized(&self, maximized: bool) {
self.window.set_maximized(maximized)
}
/// Sets the window to fullscreen or back
#[inline]
pub fn set_fullscreen(&self, monitor: Option<MonitorId>) {
self.window.set_fullscreen(monitor)
}
/// Turn window decorations on or off.
#[inline]
pub fn set_decorations(&self, decorations: bool) {
self.window.set_decorations(decorations)
}
/// Change whether or not the window will always be on top of other windows.
#[inline]
pub fn set_always_on_top(&self, always_on_top: bool) {
self.window.set_always_on_top(always_on_top)
}
/// Sets the window icon. On Windows and X11, this is typically the small icon in the top-left
/// corner of the titlebar.
///
/// For more usage notes, see `WindowBuilder::with_window_icon`.
///
/// ## Platform-specific
///
/// This only has an effect on Windows and X11.
#[inline]
pub fn set_window_icon(&self, window_icon: Option<Icon>) {
self.window.set_window_icon(window_icon)
}
/// Sets location of IME candidate box in client area coordinates relative to the top left.
#[inline]
pub fn set_ime_spot(&self, position: LogicalPosition) {
self.window.set_ime_spot(position)
}
/// Returns the monitor on which the window currently resides
#[inline]
pub fn get_current_monitor(&self) -> MonitorId {
self.window.get_current_monitor()
}
/// Returns the list of all the monitors available on the system.
///
/// This is the same as `EventsLoop::get_available_monitors`, and is provided for convenience.
#[inline]
pub fn get_available_monitors(&self) -> AvailableMonitorsIter {
let data = self.window.get_available_monitors();
AvailableMonitorsIter { data: data.into_iter() }
}
/// Returns the primary monitor of the system.
///
/// This is the same as `EventsLoop::get_primary_monitor`, and is provided for convenience.
#[inline]
pub fn get_primary_monitor(&self) -> MonitorId {
MonitorId { inner: self.window.get_primary_monitor() }
pub fn set_cursor_state(&self, state: CursorState) -> Result<(), String> {
self.window.set_cursor_state(state)
}
#[inline]
@@ -430,11 +299,10 @@ impl Window {
}
/// An iterator for the list of available monitors.
// Implementation note: we retrieve the list once, then serve each element by one by one.
// Implementation note: we retreive the list once, then serve each element by one by one.
// This may change in the future.
#[derive(Debug)]
pub struct AvailableMonitorsIter {
pub(crate) data: VecDequeIter<platform::MonitorId>,
data: VecDequeIter<platform::MonitorId>,
}
impl Iterator for AvailableMonitorsIter {
@@ -442,7 +310,7 @@ impl Iterator for AvailableMonitorsIter {
#[inline]
fn next(&mut self) -> Option<MonitorId> {
self.data.next().map(|id| MonitorId { inner: id })
self.data.next().map(|id| MonitorId(id))
}
#[inline]
@@ -451,44 +319,41 @@ impl Iterator for AvailableMonitorsIter {
}
}
/// Identifier for a monitor.
#[derive(Debug, Clone)]
pub struct MonitorId {
pub(crate) inner: platform::MonitorId
/// Returns the list of all available monitors.
#[inline]
pub fn get_available_monitors() -> AvailableMonitorsIter {
let data = platform::get_available_monitors();
AvailableMonitorsIter{ data: data.into_iter() }
}
/// Returns the primary monitor of the system.
#[inline]
pub fn get_primary_monitor() -> MonitorId {
MonitorId(platform::get_primary_monitor())
}
/// Identifier for a monitor.
pub struct MonitorId(platform::MonitorId);
impl MonitorId {
/// Returns a human-readable name of the monitor.
///
/// Returns `None` if the monitor doesn't exist anymore.
#[inline]
pub fn get_name(&self) -> Option<String> {
self.inner.get_name()
let &MonitorId(ref id) = self;
id.get_name()
}
/// Returns the monitor's resolution.
/// Returns the native platform identifier for this monitor.
#[inline]
pub fn get_dimensions(&self) -> PhysicalSize {
self.inner.get_dimensions()
pub fn get_native_identifier(&self) -> NativeMonitorId {
let &MonitorId(ref id) = self;
id.get_native_identifier()
}
/// Returns the top-left corner position of the monitor relative to the larger full
/// screen area.
/// Returns the number of pixels currently displayed on the monitor.
#[inline]
pub fn get_position(&self) -> PhysicalPosition {
self.inner.get_position()
}
/// Returns the DPI factor that can be used to map logical pixels to physical pixels, and vice versa.
///
/// See the [`dpi`](dpi/index.html) module for more information.
///
/// ## Platform-specific
///
/// - **X11:** Can be overridden using the `WINIT_HIDPI_FACTOR` environment variable.
/// - **Android:** Always returns 1.0.
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
self.inner.get_hidpi_factor()
pub fn get_dimensions(&self) -> (u32, u32) {
let &MonitorId(ref id) = self;
id.get_dimensions()
}
}

10
tests/events_loop.rs Normal file
View File

@@ -0,0 +1,10 @@
extern crate winit;
// A part of the API requirement for `EventsLoop` is that it is `Send` + `Sync`.
//
// This short test will only compile if the `EventsLoop` is `Send` + `Sync`.
#[test]
fn send_sync() {
fn check_send_sync<T: Send + Sync>() {}
check_send_sync::<winit::EventsLoop>();
}

23
tests/send_objects.rs
View File

@@ -1,23 +0,0 @@
extern crate winit;
fn needs_send<T:Send>() {}
#[test]
fn events_loop_proxy_send() {
// ensures that `winit::EventsLoopProxy` implements `Send`
needs_send::<winit::EventsLoopProxy>();
}
#[test]
fn window_send() {
// ensures that `winit::Window` implements `Send`
needs_send::<winit::Window>();
}
#[test]
fn ids_send() {
// ensures that the various `..Id` types implement `Send`
needs_send::<winit::WindowId>();
needs_send::<winit::DeviceId>();
needs_send::<winit::MonitorId>();
}

9
tests/sync_object.rs
View File

@@ -1,9 +0,0 @@
extern crate winit;
fn needs_sync<T:Sync>() {}
#[test]
fn window_sync() {
// ensures that `winit::Window` implements `Sync`
needs_sync::<winit::Window>();
}

9
tests/window_proxy_send.rs Normal file
View File

@@ -0,0 +1,9 @@
extern crate winit;
#[cfg(feature = "window")]
#[test]
fn window_proxy_send() {
// ensures that `winit::WindowProxy` implements `Send`
fn needs_send<T:Send>() {}
needs_send::<winit::WindowProxy>();
}