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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
v0.19.1 ... 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 This property must be present when the window leaves the Withdrawn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 state and may be changed only while the window is in the Withdrawn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
102 changed files with 5776 additions and 18926 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/
*~
#*#

69
.travis.yml
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@@ -1,61 +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
# Linux 64bit
- env: TARGET=x86_64-unknown-linux-gnu
os: linux
rust: nightly
- env: TARGET=x86_64-unknown-linux-gnu
os: linux
rust: stable
# macOS
- env: TARGET=x86_64-apple-darwin
os: osx
rust: nightly
- env: TARGET=x86_64-apple-darwin
os: osx
rust: stable
# iOS
- env: TARGET=x86_64-apple-ios
os: osx
rust: nightly
- env: TARGET=x86_64-apple-ios
os: osx
rust: stable
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
- cargo build --target $TARGET --features serde --verbose
- cargo build --target $TARGET --features icon_loading --verbose
# Running iOS apps on OSX requires the simulator so we skip that for now
- if [ "$TARGET" != "x86_64-apple-ios" ]; then cargo test --target $TARGET --verbose; fi
- if [ "$TARGET" != "x86_64-apple-ios" ]; then cargo test --target $TARGET --features serde --verbose; fi
- if [ "$TARGET" != "x86_64-apple-ios" ]; then cargo test --target $TARGET --features icon_loading --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:
- |

333
CHANGELOG.md
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@@ -1,333 +0,0 @@
# Unreleased
# Version 0.19.1 (2019-04-08)
- On Wayland, added a `get_wayland_display` function to `EventsLoopExt`.
- On Windows, fix `CursorMoved(0, 0)` getting dispatched on window focus.
- On macOS, fix command key event left and right reverse.
- On FreeBSD, NetBSD, and OpenBSD, fix build of X11 backend.
- On Windows, fix icon not showing up in corner of window.
- On X11, change DPI scaling factor behavior. First, winit tries to read it from "Xft.dpi" XResource, and uses DPI calculation from xrandr dimensions as fallback behavior.
# Version 0.19.0 (2019-03-06)
- On X11, we will use the faster `XRRGetScreenResourcesCurrent` function instead of `XRRGetScreenResources` when available.
- On macOS, fix keycodes being incorrect when using a non-US keyboard layout.
- On Wayland, fix `with_title()` not setting the windows title
- On Wayland, add `set_wayland_theme()` to control client decoration color theme
- Added serde serialization to `os::unix::XWindowType`.
- **Breaking:** `image` crate upgraded to 0.21. This is exposed as part of the `icon_loading` API.
- On X11, make event loop thread safe by replacing XNextEvent with select(2) and XCheckIfEvent
- On Windows, fix malformed function pointer typecast that could invoke undefined behavior.
- Refactored Windows state/flag-setting code.
- On Windows, hiding the cursor no longer hides the cursor for all Winit windows - just the one `hide_cursor` was called on.
- On Windows, cursor grabs used to get perpetually canceled when the grabbing window lost focus. Now, cursor grabs automatically get re-initialized when the window regains focus and the mouse moves over the client area.
- On Windows, only vertical mouse wheel events were handled. Now, horizontal mouse wheel events are also handled.
- On Windows, ignore the AltGr key when populating the `ModifersState` type.
- On Linux, the numpad's add, subtract and divide keys are now mapped to the `Add`, `Subtract` and `Divide` virtual key codes
- On macOS, the numpad's subtract key has been added to the `Subtract` mapping
- On Wayland, the numpad's home, end, page up and page down keys are now mapped to the `Home`, `End`, `PageUp` and `PageDown` virtual key codes
# Version 0.18.1 (2018-12-30)
- On macOS, fix `Yen` (JIS) so applications receive the event.
- On X11 with a tiling WM, fixed high CPU usage when moving windows across monitors.
- On X11, fixed panic caused by dropping the window before running the event loop.
- on macOS, added `WindowExt::set_simple_fullscreen` which does not require a separate space
- Introduce `WindowBuilderExt::with_app_id` to allow setting the application ID on Wayland.
- On Windows, catch panics in event loop child thread and forward them to the parent thread. This prevents an invocation of undefined behavior due to unwinding into foreign code.
- On Windows, fix issue where resizing or moving window combined with grabbing the cursor would freeze program.
- On Windows, fix issue where resizing or moving window would eat `Awakened` events.
- On Windows, exiting fullscreen after entering fullscreen with disabled decorations no longer shrinks window.
- On X11, fixed a segfault when using virtual monitors with XRandR.
- Derive `Ord` and `PartialOrd` for `VirtualKeyCode` enum.
- On Windows, fix issue where hovering or dropping a non file item would create a panic.
- On Wayland, fix resizing and DPI calculation when a `wl_output` is removed without sending a `leave` event to the `wl_surface`, such as disconnecting a monitor from a laptop.
- On Wayland, DPI calculation is handled by smithay-client-toolkit.
- On X11, `WindowBuilder::with_min_dimensions` and `WindowBuilder::with_max_dimensions` now correctly account for DPI.
- Added support for generating dummy `DeviceId`s and `WindowId`s to better support unit testing.
- On macOS, fixed unsoundness in drag-and-drop that could result in drops being rejected.
- On macOS, implemented `WindowEvent::Refresh`.
- On macOS, all `MouseCursor` variants are now implemented and the cursor will no longer reset after unfocusing.
- Removed minimum supported Rust version guarantee.
# Version 0.18.0 (2018-11-07)
- **Breaking:** `image` crate upgraded to 0.20. This is exposed as part of the `icon_loading` API.
- On Wayland, pointer events will now provide the current modifiers state.
- On Wayland, titles will now be displayed in the window header decoration.
- On Wayland, key repetition is now ended when keyboard loses focus.
- On Wayland, windows will now use more stylish and modern client side decorations.
- On Wayland, windows will use server-side decorations when available.
- **Breaking:** Added support for F16-F24 keys (variants were added to the `VirtualKeyCode` enum).
- Fixed graphical glitches when resizing on Wayland.
- On Windows, fix freezes when performing certain actions after a window resize has been triggered. Reintroduces some visual artifacts when resizing.
- Updated window manager hints under X11 to v1.5 of [Extended Window Manager Hints](https://specifications.freedesktop.org/wm-spec/wm-spec-1.5.html#idm140200472629520).
- Added `WindowBuilderExt::with_gtk_theme_variant` to X11-specific `WindowBuilder` functions.
- Fixed UTF8 handling bug in X11 `set_title` function.
- On Windows, `Window::set_cursor` now applies immediately instead of requiring specific events to occur first.
- On Windows, the `HoveredFile` and `HoveredFileCancelled` events are now implemented.
- On Windows, fix `Window::set_maximized`.
- On Windows 10, fix transparency (#260).
- On macOS, fix modifiers during key repeat.
- Implemented the `Debug` trait for `Window`, `EventsLoop`, `EventsLoopProxy` and `WindowBuilder`.
- On X11, now a `Resized` event will always be generated after a DPI change to ensure the window's logical size is consistent with the new DPI.
- Added further clarifications to the DPI docs.
- On Linux, if neither X11 nor Wayland manage to initialize, the corresponding panic now consists of a single line only.
- Add optional `serde` feature with implementations of `Serialize`/`Deserialize` for DPI types and various event types.
- Add `PartialEq`, `Eq`, and `Hash` implementations on public types that could have them but were missing them.
- On X11, drag-and-drop receiving an unsupported drop type can no longer cause the WM to freeze.
- Fix issue whereby the OpenGL context would not appear at startup on macOS Mojave (#1069).
- **Breaking:** Removed `From<NSApplicationActivationPolicy>` impl from `ActivationPolicy` on macOS.
- On macOS, the application can request the user's attention with `WindowExt::request_user_attention`.
# 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).

70
CONTRIBUTING.md
View File

@@ -1,70 +0,0 @@
# Winit Contributing Guidelines
## Scope
Winit aims to provide a generic platform abstracting the main graphic platforms (Windows, macOS, X11,
Wayland, Android, iOS and the web platform via Emscripten).
Most platforms expose capabilities that cannot be meaningfully transposed to the others. Winit does not
aim to support every single functionality of every platform, but rather to abstract the set of
capabilities that is common to all platforms. In this context, APIs exposed in winit can be split into
different "support levels":
- Tier 1: features which are in the main scope of winit. They are part of the common API of winit, and
are taken care of by the maintainers. Any part of these features that is not working correctly is
considered a bug in winit.
- Tier 2: some platform-specific features can be sufficiently fundamental to the platform that winit can
integrate support for them in the platform-specific part of the API. These features are not considered
directly handled by the maintainers of winit. If you have a strong incentive to have such a feature
integrated in winit, consider implementing it and proposing yourself to maintain it in the future.
- Tier 3: these features are not directly exposed by winit, but rather can be implemented using the
raw handles to the underlying platform that winit exposes. If your feature of interest is rather
niche, this is probably where it belongs.
The exact list of supported Tier 1 features is tracked in this issue:
[#252](https://github.com/tomaka/winit/issues/252).
## Reporting an issue
When reporting an issue, in order to help the maintainers understand what the problem is, please make
your description of the issue as detailed as possible:
- if it is a bug, please provide clear explanation of what happens, what should happen, and how to
reproduce the issue, ideally by providing a minimal program exhibiting the problem
- if it is a feature request, please provide a clear argumentation about why you believe this feature
should be supported by winit
## Making a pull request
When making a code contribution to winit, before opening your pull request, please make sure that:
- you tested your modifications on all the platforms impacted, or if not possible detail which platforms
were not tested, and what should be tested, so that a maintainer or another contributor can test them
- you updated any relevant documentation in winit
- you left comments in your code explaining any part that is not straightforward, so that the
maintainers and future contributors don't have to try to guess what your code is supposed to do
- your PR adds an entry to the changelog file if the introduced change is relevant to winit users
Once your PR is open, you can ask for review by a maintainer of your platform. Winit's merging policy
is that a PR must be approved by at least two maintainers of winit before being merged, including
at least a maintainer of the platform (a maintainer making a PR themselves counts as approving it).
## Maintainers & Testers
Winit is managed by several people, each with their specialities, and each maintaining a subset of the
backends of winit. As such, depending on your platform of interest, your contacts will be different.
This table summarizes who can be contacted in which case, with the following legend:
- `M`: is a main maintainer for this platform
- `R`: can review code for this platform
- `T`: has the ability of testing the platform
- ` `: knows nothing of this platform
| Platform | Windows | macOS | X11 | Wayland | Android | iOS | Emscripten |
| :--- | :---: | :---: | :---: | :---: | :---: | :---: | :---: |
| @francesca64 | R | M | M | | M | R | |
| @mitchmindtree | T | | T | T | | | |
| @Osspial | M | | T | T | T | | T |
| @vberger | | | T | M | | | |
| @mtak- | | T | | | T | M | |

69
Cargo.toml
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@@ -1,7 +1,7 @@
[package]
name = "winit"
version = "0.19.1"
authors = ["The winit contributors", "Pierre Krieger <pierre.krieger1708@gmail.com>"]
version = "0.6.4"
authors = ["The winit contributors, Pierre Krieger <pierre.krieger1708@gmail.com>"]
description = "Cross-platform window creation library."
keywords = ["windowing"]
license = "Apache-2.0"
@@ -10,61 +10,34 @@ repository = "https://github.com/tomaka/winit"
documentation = "https://docs.rs/winit"
categories = ["gui"]
[package.metadata.docs.rs]
features = ["icon_loading", "serde"]
[features]
icon_loading = ["image"]
[dependencies]
lazy_static = "1"
lazy_static = "0.2.2"
libc = "0.2"
log = "0.4"
image = { version = "0.21", optional = true }
serde = { version = "1", optional = true, features = ["serde_derive"] }
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 = "0.18.4"
core-foundation = "0.6"
core-graphics = "0.17.3"
objc = "0.2"
cgl = "0.2"
cocoa = "=0.5.2"
core-foundation = "0.2"
core-graphics = "0.4"
[target.'cfg(target_os = "windows")'.dependencies]
backtrace = "0.3"
bitflags = "1"
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(target_os = "windows")'.dependencies.winapi]
version = "0.3.6"
features = [
"combaseapi",
"dwmapi",
"errhandlingapi",
"hidusage",
"libloaderapi",
"objbase",
"ole2",
"processthreadsapi",
"shellapi",
"shellscalingapi",
"shobjidl_core",
"unknwnbase",
"winbase",
"windowsx",
"winerror",
"wingdi",
"winnt",
"winuser",
]
[target.'cfg(any(target_os = "linux", target_os = "dragonfly", target_os = "freebsd", target_os = "openbsd", target_os = "netbsd"))'.dependencies]
wayland-client = { version = "0.21", features = [ "dlopen", "egl", "cursor"] }
smithay-client-toolkit = "0.4.3"
x11-dl = "2.18.3"
parking_lot = "0.7"
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"

50
README.md
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@@ -1,29 +1,23 @@
# winit - Cross-platform window creation and management in Rust
[![](http://meritbadge.herokuapp.com/winit)](https://crates.io/crates/winit)
[![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 = "0.19.1"
winit = "0.5"
```
## [Documentation](https://docs.rs/winit)
## Contact Us
Join us in any of these:
[![Freenode](https://img.shields.io/badge/freenode.net-%23glutin-red.svg)](http://webchat.freenode.net?channels=%23glutin&uio=MTY9dHJ1ZSYyPXRydWUmND10cnVlJjExPTE4NSYxMj10cnVlJjE1PXRydWU7a)
[![Matrix](https://img.shields.io/badge/Matrix-%23Glutin%3Amatrix.org-blueviolet.svg)](https://matrix.to/#/#Glutin:matrix.org)
[![Gitter](https://badges.gitter.im/Join%20Chat.svg)](https://gitter.im/tomaka/glutin?utm_source=badge&utm_medium=badge&utm_campaign=pr-badge&utm_content=badge)
## 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
@@ -34,37 +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,
_ => ()
}
});
}
}
```
Winit is only officially supported on the latest stable version of the Rust compiler.
### Cargo Features
Winit provides the following features, which can be enabled in your `Cargo.toml` file:
* `icon_loading`: Enables loading window icons directly from files. Depends on the [`image` crate](https://crates.io/crates/image).
* `serde`: Enables serialization/deserialization of certain types with [Serde](https://crates.io/crates/serde).
### 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
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@@ -1,17 +1,12 @@
environment:
matrix:
- TARGET: x86_64-pc-windows-msvc
CHANNEL: nightly
- TARGET: x86_64-pc-windows-msvc
CHANNEL: stable
- 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
@@ -20,5 +15,3 @@ build: false
test_script:
- cargo test --verbose
- cargo test --features serde --verbose
- cargo test --features icon_loading --verbose

13
examples/cursor.rs
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@@ -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
});
}

119
examples/fullscreen.rs
View File

@@ -1,46 +1,30 @@
extern crate winit;
use std::io::{self, Write};
use winit::{ControlFlow, Event, WindowEvent};
fn main() {
let mut events_loop = winit::EventsLoop::new();
#[cfg(target_os = "macos")]
let mut macos_use_simple_fullscreen = false;
// enumerating monitors
let monitor = {
// On macOS there are two fullscreen modes "native" and "simple"
#[cfg(target_os = "macos")]
{
print!("Please choose the fullscreen mode: (1) native, (2) simple: ");
io::stdout().flush().unwrap();
let mut num = String::new();
io::stdin().read_line(&mut num).unwrap();
let num = num.trim().parse().ok().expect("Please enter a number");
match num {
2 => macos_use_simple_fullscreen = true,
_ => {}
}
// Prompt for monitor when using native fullscreen
if !macos_use_simple_fullscreen {
Some(prompt_for_monitor(&events_loop))
} else {
None
}
for (num, monitor) in winit::get_available_monitors().enumerate() {
println!("Monitor #{}: {:?}", num, monitor.get_name());
}
#[cfg(not(target_os = "macos"))]
Some(prompt_for_monitor(&events_loop))
print!("Please write the number of the monitor to use: ");
io::stdout().flush().unwrap();
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 = winit::get_available_monitors().nth(num).expect("Please enter a valid ID");
println!("Using {:?}", monitor.get_name());
monitor
};
let mut is_fullscreen = monitor.is_some();
let mut is_maximized = false;
let mut decorations = true;
let events_loop = winit::EventsLoop::new();
let window = winit::WindowBuilder::new()
let _window = winit::WindowBuilder::new()
.with_title("Hello world!")
.with_fullscreen(monitor)
.build(&events_loop)
@@ -50,72 +34,13 @@ fn main() {
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) => {
#[cfg(target_os = "macos")]
{
if macos_use_simple_fullscreen {
use winit::os::macos::WindowExt;
if WindowExt::set_simple_fullscreen(&window, !is_fullscreen) {
is_fullscreen = !is_fullscreen;
}
return ControlFlow::Continue;
}
}
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
});
}
// Enumerate monitors and prompt user to choose one
fn prompt_for_monitor(events_loop: &winit::EventsLoop) -> winit::MonitorId {
for (num, monitor) in events_loop.get_available_monitors().enumerate() {
println!("Monitor #{}: {:?}", num, monitor.get_name());
}
print!("Please write the number of the monitor to use: ");
io::stdout().flush().unwrap();
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");
println!("Using {:?}", monitor.get_name());
monitor
}

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
View File

@@ -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(),
_ => ()
}
});
}

94
examples/window_icon.rs
View File

@@ -1,94 +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;
#[cfg(feature = "icon_loading")]
fn main() {
use winit::Icon;
// 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::GenericImageView;
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 _);
}
}
}
};
}

331
src/dpi.rs
View File

@@ -1,331 +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 [`HiDpiFactorChanged`](../enum.WindowEvent.html#variant.HiDpiFactorChanged) event of your
//! windows. This event is sent any time the DPI factor changes, either 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 [`HiDpiFactorChanged`](../enum.WindowEvent.html#variant.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 set per-screen by the server, and are always integers (most often 1 or 2).
//! - **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 always 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.
//!
//! `winit` will send [`Resized`](../enum.WindowEvent.html#variant.Resized) events whenever a window's logical size
//! changes, and [`HiDpiFactorChanged`](../enum.WindowEvent.html#variant.HiDpiFactorChanged) events
//! whenever the DPI factor changes. Receiving either of these events means that the physical size of your window has
//! changed, and you should recompute it using the latest values you received for each. If the logical size and the
//! DPI factor change simultaneously, `winit` will send both events together; thus, it's recommended to buffer
//! these events and process them at the end of the queue.
//!
//! If you never received any [`HiDpiFactorChanged`](../enum.WindowEvent.html#variant.HiDpiFactorChanged) events,
//! then your window's DPI factor is 1.
/// 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)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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 _)
}
}

213
src/events.rs
View File

@@ -1,59 +1,31 @@
use std::path::PathBuf;
use WindowId;
use {DeviceId, LogicalPosition, LogicalSize, WindowId};
/// Describes a generic event.
#[derive(Clone, Debug, PartialEq)]
#[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, PartialEq)]
#[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.
///
/// When the user drops multiple files at once, this event will be emitted for each file
/// separately.
DroppedFile(PathBuf),
/// A file is being hovered over the window.
///
/// When the user hovers multiple files at once, this event will be emitted for each file
/// separately.
HoveredFile(PathBuf),
/// A file was hovered, but has exited the window.
///
/// There will be a single `HoveredFileCancelled` event triggered even if multiple files were
/// hovered.
HoveredFileCancelled,
/// The window received a unicode character.
ReceivedCharacter(char),
@@ -63,127 +35,45 @@ 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, PartialEq)]
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, PartialEq, Eq, Hash)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum TouchPhase {
Started,
Moved,
@@ -191,6 +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.
@@ -206,35 +97,22 @@ 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, PartialEq)]
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)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum ElementState {
Pressed,
Released,
}
/// Describes a button of a mouse controller.
#[derive(Debug, Hash, PartialEq, Eq, Clone, Copy)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum MouseButton {
Left,
Right,
@@ -242,9 +120,7 @@ pub enum MouseButton {
Other(u8),
}
/// Describes a difference in the mouse scroll wheel state.
#[derive(Debug, Clone, Copy, PartialEq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum MouseScrollDelta {
/// Amount in lines or rows to scroll in the horizontal
/// and vertical directions.
@@ -258,13 +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, Ord, PartialOrd, PartialEq, Eq, Clone, Copy)]
#[repr(u32)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Hash, PartialEq, Eq, Clone, Copy)]
pub enum VirtualKeyCode {
/// The '1' key over the letters.
Key1,
@@ -332,15 +205,6 @@ pub enum VirtualKeyCode {
F13,
F14,
F15,
F16,
F17,
F18,
F19,
F20,
F21,
F22,
F23,
F24,
/// Print Screen/SysRq.
Snapshot,
@@ -373,8 +237,6 @@ pub enum VirtualKeyCode {
/// The "Compose" key on Linux.
Compose,
Caret,
Numlock,
Numpad0,
Numpad1,
@@ -409,6 +271,7 @@ pub enum VirtualKeyCode {
LAlt,
LBracket,
LControl,
LMenu,
LShift,
LWin,
Mail,
@@ -433,6 +296,7 @@ pub enum VirtualKeyCode {
RAlt,
RBracket,
RControl,
RMenu,
RShift,
RWin,
Semicolon,
@@ -455,17 +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)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[cfg_attr(feature = "serde", serde(default))]
#[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::{GenericImageView, 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 }
}
}

360
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,
//! _ => ()
//! }
//! });
//! ```
@@ -80,56 +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;
#[macro_use]
extern crate shared_library;
extern crate libc;
#[macro_use]
extern crate log;
#[cfg(feature = "icon_loading")]
extern crate image;
#[cfg(feature = "serde")]
#[macro_use]
extern crate serde;
#[cfg(target_os = "windows")]
extern crate winapi;
#[cfg(target_os = "windows")]
extern crate backtrace;
#[macro_use]
extern crate kernel32;
#[cfg(target_os = "windows")]
extern crate bitflags;
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;
@@ -139,28 +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,
}
impl std::fmt::Debug for Window {
fn fmt(&self, fmtr: &mut std::fmt::Formatter) -> std::fmt::Result {
fmtr.pad("Window { .. }")
}
window: platform::Window2,
}
/// Identifier of a window. Unique for each window.
@@ -172,171 +169,42 @@ impl std::fmt::Debug for Window {
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WindowId(platform::WindowId);
impl WindowId {
/// Returns a dummy `WindowId`, useful for unit testing. The only guarantee made about the return
/// value of this function is that it will always be equal to itself and to future values returned
/// by this function. No other guarantees are made. This may be equal to a real `WindowId`.
///
/// **Passing this into a winit function will result in undefined behavior.**
pub unsafe fn dummy() -> Self {
WindowId(platform::WindowId::dummy())
}
}
/// 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);
impl DeviceId {
/// Returns a dummy `DeviceId`, useful for unit testing. The only guarantee made about the return
/// value of this function is that it will always be equal to itself and to future values returned
/// by this function. No other guarantees are made. This may be equal to a real `DeviceId`.
///
/// **Passing this into a winit function will result in undefined behavior.**
pub unsafe fn dummy() -> Self {
DeviceId(platform::DeviceId::dummy())
}
}
/// 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
}
impl std::fmt::Debug for EventsLoop {
fn fmt(&self, fmtr: &mut std::fmt::Formatter) -> std::fmt::Result {
fmtr.pad("EventsLoop { .. }")
}
}
/// 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, Hash)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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 std::fmt::Debug for EventsLoopProxy {
fn fmt(&self, fmtr: &mut std::fmt::Formatter) -> std::fmt::Result {
fmtr.pad("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()
}
}
@@ -350,16 +218,8 @@ pub struct WindowBuilder {
platform_specific: platform::PlatformSpecificWindowBuilderAttributes,
}
impl std::fmt::Debug for WindowBuilder {
fn fmt(&self, fmtr: &mut std::fmt::Formatter) -> std::fmt::Result {
fmtr.debug_struct("WindowBuilder")
.field("window", &self.window)
.finish()
}
}
/// 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
@@ -387,9 +247,7 @@ impl std::error::Error for CreationError {
}
}
/// Describes the appearance of the mouse cursor.
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Copy, Clone, PartialEq)]
pub enum MouseCursor {
/// The platform-dependent default cursor.
Default,
@@ -415,6 +273,7 @@ pub enum MouseCursor {
/// Cursor showing that something cannot be done.
NotAllowed,
ContextMenu,
NoneCursor,
Cell,
VerticalText,
Alias,
@@ -444,51 +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`.
@@ -505,18 +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,
}
@@ -527,16 +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 _
}
}

130
src/os/macos.rs Normal file → Executable file
View File

@@ -1,7 +1,9 @@
#![cfg(target_os = "macos")]
use std::convert::From;
use std::os::raw::c_void;
use {LogicalSize, MonitorId, Window, WindowBuilder};
use cocoa::appkit::NSApplicationActivationPolicy;
use {Window, WindowBuilder};
/// Additional methods on `Window` that are specific to MacOS.
pub trait WindowExt {
@@ -14,23 +16,6 @@ pub trait WindowExt {
///
/// The pointer will become invalid when the `Window` is destroyed.
fn get_nsview(&self) -> *mut c_void;
/// Request user attention, causing the application's dock icon to bounce.
/// Note that this has no effect if the application is already focused.
///
/// The `is_critical` flag has the following effects:
/// - `false`: the dock icon will only bounce once.
/// - `true`: the dock icon will bounce until the application is focused.
fn request_user_attention(&self, is_critical: bool);
/// Toggles a fullscreen mode that doesn't require a new macOS space.
/// Returns a boolean indicating whether the transition was successful (this
/// won't work if the window was already in the native fullscreen).
///
/// This is how fullscreen used to work on macOS in versions before Lion.
/// And allows the user to have a fullscreen window without using another
/// space or taking control over the entire monitor.
fn set_simple_fullscreen(&self, fullscreen: bool) -> bool;
}
impl WindowExt for Window {
@@ -43,16 +28,6 @@ impl WindowExt for Window {
fn get_nsview(&self) -> *mut c_void {
self.window.get_nsview()
}
#[inline]
fn request_user_attention(&self, is_critical: bool) {
self.window.request_user_attention(is_critical)
}
#[inline]
fn set_simple_fullscreen(&self, fullscreen: bool) -> bool {
self.window.set_simple_fullscreen(fullscreen)
}
}
/// Corresponds to `NSApplicationActivationPolicy`.
@@ -72,100 +47,29 @@ impl Default for ActivationPolicy {
}
}
impl From<ActivationPolicy> for NSApplicationActivationPolicy {
fn from(activation_policy: ActivationPolicy) -> Self {
match activation_policy {
ActivationPolicy::Regular =>
NSApplicationActivationPolicy::NSApplicationActivationPolicyRegular,
ActivationPolicy::Accessory =>
NSApplicationActivationPolicy::NSApplicationActivationPolicyAccessory,
ActivationPolicy::Prohibited =>
NSApplicationActivationPolicy::NSApplicationActivationPolicyProhibited,
}
}
}
/// 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;

342
src/os/unix.rs
View File

@@ -1,233 +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 sctk::window::{ButtonState, Theme};
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;
/// Theme for wayland client side decorations
///
/// Colors must be in ARGB8888 format
pub struct WaylandTheme {
/// Primary color when the window is focused
pub primary_active: [u8; 4],
/// Primary color when the window is unfocused
pub primary_inactive: [u8; 4],
/// Secondary color when the window is focused
pub secondary_active: [u8; 4],
/// Secondary color when the window is unfocused
pub secondary_inactive: [u8; 4],
/// Close button color when hovered over
pub close_button_hovered: [u8; 4],
/// Close button color
pub close_button: [u8; 4],
/// Close button color when hovered over
pub maximize_button_hovered: [u8; 4],
/// Maximize button color
pub maximize_button: [u8; 4],
/// Minimize button color when hovered over
pub minimize_button_hovered: [u8; 4],
/// Minimize button color
pub minimize_button: [u8; 4],
}
struct WaylandThemeObject(WaylandTheme);
impl Theme for WaylandThemeObject {
fn get_primary_color(&self, active: bool) -> [u8; 4] {
if active {
self.0.primary_active
} else {
self.0.primary_inactive
}
}
// Used for division line
fn get_secondary_color(&self, active: bool) -> [u8; 4] {
if active {
self.0.secondary_active
} else {
self.0.secondary_inactive
}
}
fn get_close_button_color(&self, state: ButtonState) -> [u8; 4] {
match state {
ButtonState::Hovered => self.0.close_button_hovered,
_ => self.0.close_button,
}
}
fn get_maximize_button_color(&self, state: ButtonState) -> [u8; 4] {
match state {
ButtonState::Hovered => self.0.maximize_button_hovered,
_ => self.0.maximize_button,
}
}
fn get_minimize_button_color(&self, state: ButtonState) -> [u8; 4] {
match state {
ButtonState::Hovered => self.0.minimize_button_hovered,
_ => self.0.minimize_button,
}
}
}
/// 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>>;
/// Returns a pointer to the `wl_display` object of wayland that is used by this `EventsLoop`.
///
/// Returns `None` if the `EventsLoop` doesn't use wayland (if it uses xlib for example).
///
/// The pointer will become invalid when the glutin `EventsLoop` is destroyed.
fn get_wayland_display(&self) -> Option<*mut raw::c_void>;
}
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()
}
#[inline]
fn get_wayland_display(&self) -> Option<*mut raw::c_void> {
match self.events_loop {
LinuxEventsLoop::Wayland(ref e) => Some(e.get_display().c_ptr() as *mut _),
_ => None
}
// 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>;
/// Sets the color theme of the client side window decorations on wayland
fn set_wayland_theme(&self, theme: WaylandTheme);
/// Returns a reference to the `WlSurface` 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_surface(&self) -> Option<&WlSurface>;
/// Check if the window is ready for drawing
/// Returns a pointer to the `WlDisplay` 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_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
@@ -235,23 +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()),
@@ -259,8 +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
@@ -268,66 +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 set_wayland_theme(&self, theme: WaylandTheme) {
match self.window {
LinuxWindow::Wayland(ref w) => w.set_theme(WaylandThemeObject(theme)),
_ => {}
}
}
#[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 `_GTK_THEME_VARIANT` hint set to the specified value. Currently only relevant on X11.
fn with_gtk_theme_variant(self, variant: String) -> 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;
/// Build window with a given application ID. It should match the `.desktop` file distributed with
/// your program. Only relevant on Wayland.
///
/// For details about application ID conventions, see the
/// [Desktop Entry Spec](https://specifications.freedesktop.org/desktop-entry-spec/desktop-entry-spec-latest.html#desktop-file-id)
fn with_app_id(self, app_id: String) -> WindowBuilder;
}
impl WindowBuilderExt for WindowBuilder {
@@ -344,59 +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
}
#[inline]
fn with_gtk_theme_variant(mut self, variant: String) -> WindowBuilder {
self.platform_specific.gtk_theme_variant = Some(variant);
self
}
#[inline]
fn with_app_id(mut self, app_id: String) -> WindowBuilder {
self.platform_specific.app_id = Some(app_id);
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()
}
}

473
src/platform/android/mod.rs
View File

@@ -2,215 +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;
impl WindowId {
pub unsafe fn dummy() -> Self {
WindowId
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct DeviceId;
impl DeviceId {
pub unsafe fn dummy() -> Self {
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 {
@@ -220,25 +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!()
}
}
@@ -247,20 +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,
})
}
@@ -269,156 +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;
}

1135
src/platform/emscripten/mod.rs
View File

File diff suppressed because it is too large Load Diff

73
src/platform/ios/ffi.rs
View File

@@ -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))
}
}

913
src/platform/ios/mod.rs
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File diff suppressed because it is too large Load Diff

2
src/platform/linux/dlopen.rs
View File

@@ -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};

523
src/platform/linux/mod.rs
View File

@@ -1,93 +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 gtk_theme_variant: Option<String>,
pub app_id: Option<String>
}
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)
}
impl WindowId {
pub unsafe fn dummy() -> Self {
WindowId::X(x11::WindowId::dummy())
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum DeviceId {
X(x11::DeviceId),
Wayland(wayland::DeviceId),
}
impl DeviceId {
pub unsafe fn dummy() -> Self {
DeviceId::X(x11::DeviceId::dummy())
}
}
#[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 {
@@ -96,296 +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, pl_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(),
@@ -394,149 +288,58 @@ unsafe extern "C" fn x_error_callback(
minor_code: (*event).minor_code,
};
error!("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!(
"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)
}
}

990
src/platform/linux/wayland/event_loop.rs
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File diff suppressed because it is too large Load Diff

290
src/platform/linux/wayland/keyboard.rs
View File

@@ -1,196 +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::Proxy;
use sctk::reexports::client::protocol::wl_seat;
use sctk::reexports::client::protocol::wl_seat::RequestsTrait as SeatRequests;
use {VirtualKeyCode, ElementState, WindowEvent as Event};
use {ElementState, KeyboardInput, ModifiersState, VirtualKeyCode, WindowEvent};
use events::ModifiersState;
pub fn init_keyboard(
seat: &Proxy<wl_seat::WlSeat>,
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,
modifiers_tracker: Arc<Mutex<ModifiersState>>,
) -> 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 my_modifiers = modifiers_tracker.clone();
// }
let ret = map_keyboard_auto_with_repeat(
seat,
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 {
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_tracker.lock().unwrap().clone(),
},
},
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);
}
pub target: Option<WindowId>
}
impl KbdHandler {
pub fn new(sink: Arc<Mutex<EventsLoopSink>>) -> KbdHandler {
KbdHandler { sink: sink, target: None }
}
}
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);
}
}
KbEvent::RepeatInfo { .. } => { /* Handled by smithay client toolkit */ }
KbEvent::Modifiers { modifiers: event_modifiers } => {
*modifiers_tracker.lock().unwrap() = event_modifiers.into()
}
},
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: my_modifiers.lock().unwrap().clone(),
},
},
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();
}
},
);
match ret {
Ok(keyboard) => keyboard,
Err(_) => {
// 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)
// { variables to be captured by the closure
let mut target = None;
let my_sink = sink;
// }
seat.get_keyboard(|keyboard| {
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,
);
}
}
_ => (),
}, ())
}).unwrap()
}
}
}
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),
@@ -220,30 +111,21 @@ 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),
keysyms::XKB_KEY_F13 => Some(VirtualKeyCode::F13),
keysyms::XKB_KEY_F14 => Some(VirtualKeyCode::F14),
keysyms::XKB_KEY_F15 => Some(VirtualKeyCode::F15),
keysyms::XKB_KEY_F16 => Some(VirtualKeyCode::F16),
keysyms::XKB_KEY_F17 => Some(VirtualKeyCode::F17),
keysyms::XKB_KEY_F18 => Some(VirtualKeyCode::F18),
keysyms::XKB_KEY_F19 => Some(VirtualKeyCode::F19),
keysyms::XKB_KEY_F20 => Some(VirtualKeyCode::F20),
keysyms::XKB_KEY_F21 => Some(VirtualKeyCode::F21),
keysyms::XKB_KEY_F22 => Some(VirtualKeyCode::F22),
keysyms::XKB_KEY_F23 => Some(VirtualKeyCode::F23),
keysyms::XKB_KEY_F24 => Some(VirtualKeyCode::F24),
// flow control
keysyms::XKB_KEY_Print => Some(VirtualKeyCode::Snapshot),
keysyms::XKB_KEY_Scroll_Lock => Some(VirtualKeyCode::Scroll),
@@ -298,6 +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),
@@ -312,13 +195,6 @@ fn keysym_to_vkey(keysym: u32) -> Option<VirtualKeyCode> {
keysyms::XKB_KEY_KP_Separator => Some(VirtualKeyCode::NumpadComma),
keysyms::XKB_KEY_KP_Enter => Some(VirtualKeyCode::NumpadEnter),
keysyms::XKB_KEY_KP_Equal => Some(VirtualKeyCode::NumpadEquals),
keysyms::XKB_KEY_KP_Add => Some(VirtualKeyCode::Add),
keysyms::XKB_KEY_KP_Subtract => Some(VirtualKeyCode::Subtract),
keysyms::XKB_KEY_KP_Divide => Some(VirtualKeyCode::Divide),
keysyms::XKB_KEY_KP_Page_Up => Some(VirtualKeyCode::PageUp),
keysyms::XKB_KEY_KP_Page_Down => Some(VirtualKeyCode::PageDown),
keysyms::XKB_KEY_KP_Home => Some(VirtualKeyCode::Home),
keysyms::XKB_KEY_KP_End => Some(VirtualKeyCode::End),
// => Some(VirtualKeyCode::OEM102),
// => Some(VirtualKeyCode::Period),
// => Some(VirtualKeyCode::Playpause),
@@ -327,6 +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),
@@ -336,7 +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),
@@ -350,21 +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
}
}

42
src/platform/linux/wayland/mod.rs
View File

@@ -1,37 +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;
impl DeviceId {
pub unsafe fn dummy() -> Self {
DeviceId
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WindowId(usize);
impl WindowId {
pub unsafe fn dummy() -> Self {
WindowId(0)
}
}
#[inline]
fn make_wid(s: &Proxy<wl_surface::WlSurface>) -> WindowId {
WindowId(s.c_ptr() as usize)
}

189
src/platform/linux/wayland/pointer.rs
View File

@@ -1,189 +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::Proxy;
use sctk::reexports::client::protocol::wl_pointer::{self, Event as PtrEvent, WlPointer};
use sctk::reexports::client::protocol::wl_seat;
use sctk::reexports::client::protocol::wl_seat::RequestsTrait as SeatRequests;
pub fn implement_pointer(
seat: &Proxy<wl_seat::WlSeat>,
sink: Arc<Mutex<EventsLoopSink>>,
store: Arc<Mutex<WindowStore>>,
modifiers_tracker: Arc<Mutex<ModifiersState>>,
) -> Proxy<WlPointer> {
let mut mouse_focus = None;
let mut axis_buffer = None;
let mut axis_discrete_buffer = None;
let mut axis_state = TouchPhase::Ended;
seat.get_pointer(|pointer| {
pointer.implement(move |evt, pointer| {
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(),
modifiers: modifiers_tracker.lock().unwrap().clone(),
},
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(),
modifiers: modifiers_tracker.lock().unwrap().clone(),
},
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,
modifiers: modifiers_tracker.lock().unwrap().clone(),
},
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,
modifiers: modifiers_tracker.lock().unwrap().clone(),
},
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,
modifiers: modifiers_tracker.lock().unwrap().clone(),
},
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,
modifiers: modifiers_tracker.lock().unwrap().clone(),
},
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,
}
}
}
}, ())
}).unwrap()
}

97
src/platform/linux/wayland/touch.rs
View File

@@ -1,97 +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::Proxy;
use sctk::reexports::client::protocol::wl_touch::{Event as TouchEvent, WlTouch};
use sctk::reexports::client::protocol::wl_seat;
use sctk::reexports::client::protocol::wl_seat::RequestsTrait as SeatRequests;
struct TouchPoint {
wid: WindowId,
location: (f64, f64),
id: i32,
}
pub(crate) fn implement_touch(
seat: &Proxy<wl_seat::WlSeat>,
sink: Arc<Mutex<EventsLoopSink>>,
store: Arc<Mutex<WindowStore>>,
) -> Proxy<WlTouch> {
let mut pending_ids = Vec::new();
seat.get_touch(|touch| {
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,
);
},
}
}, ())
}).unwrap()
}

441
src/platform/linux/wayland/window.rs
View File

@@ -1,138 +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 platform::{MonitorId as PlatformMonitorId, PlatformSpecificWindowBuilderAttributes as PlAttributes};
use window::MonitorId as RootMonitorId;
use wayland_client::{EventQueue, EventQueueHandle, Proxy};
use wayland_client::protocol::{wl_display,wl_surface,wl_shell_surface};
use sctk::surface::{get_dpi_factor, get_outputs};
use sctk::window::{ConceptFrame, Event as WEvent, Window as SWindow, Theme};
use sctk::reexports::client::{Display, Proxy};
use sctk::reexports::client::protocol::{wl_seat, wl_surface};
use sctk::reexports::client::protocol::wl_surface::RequestsTrait as SurfaceRequests;
use sctk::output::OutputMgr;
use {CreationError, MouseCursor, CursorState, WindowAttributes};
use platform::MonitorId as PlatformMonitorId;
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<ConceptFrame>>>,
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, pl_attribs: PlAttributes) -> 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));
let window_store = evlp.store.clone();
let surface = evlp.env.create_surface(move |dpi, surface| {
window_store.lock().unwrap().dpi_change(&surface, dpi);
surface.set_buffer_scale(dpi);
});
let (surface, decorated) = ctxt.create_window::<DecoratedHandler>();
let window_store = evlp.store.clone();
let my_surface = surface.clone();
let mut frame = SWindow::<ConceptFrame>::init_from_env(
&evlp.env,
surface.clone(),
(width, height),
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;
}
}
// 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)
)
});
} else if attributes.decorations {
decorated.set_decorate(true);
}
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();
if let Some(app_id) = pl_attribs.app_id {
frame.set_app_id(app_id);
}
frame.set_title(attributes.title);
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(),
// Finally, set the decorations size
decorated.resize(width as i32, height as i32);
}
decorated_id
};
let me = Window {
ctxt: ctxt,
evq: evq,
cleanup_signal: cleanup_signal,
surface: surface,
frame: frame,
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]
@@ -141,7 +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]
@@ -155,91 +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 {
get_dpi_factor(&self.surface)
}
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_theme<T: Theme>(&self, theme: T) {
self.frame.lock().unwrap().set_theme(theme)
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]
@@ -248,143 +143,63 @@ impl Window {
}
#[inline]
pub fn hide_cursor(&self, _hide: bool) {
// TODO: This isn't possible on Wayland yet
}
#[inline]
pub fn grab_cursor(&self, _grab: bool) -> Result<(), String> {
Err("Cursor grabbing is not yet possible on Wayland.".to_owned())
}
#[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 get_display(&self) -> &Display {
&*self.display
}
pub fn get_surface(&self) -> &Proxy<wl_surface::WlSurface> {
&self.surface
}
pub fn get_current_monitor(&self) -> MonitorId {
let output = get_outputs(&self.surface).last().unwrap().clone();
MonitorId {
proxy: output,
mgr: self.outputs.clone(),
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(())
}
}
pub fn get_available_monitors(&self) -> VecDeque<MonitorId> {
get_available_monitors(&self.outputs)
#[inline]
pub fn hidpi_factor(&self) -> f32 {
// TODO
1.0
}
pub fn get_primary_monitor(&self) -> MonitorId {
get_primary_monitor(&self.outputs)
#[inline]
pub fn set_cursor_position(&self, _x: i32, _y: i32) -> Result<(), ()> {
// TODO: not yet possible on wayland
Err(())
}
pub fn get_display(&self) -> &wl_display::WlDisplay {
&self.ctxt.display
}
pub fn get_surface(&self) -> &wl_surface::WlSurface {
&self.surface
}
}
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<ConceptFrame>>>,
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<ConceptFrame>>),
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;
}
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)
}
}
}

52
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,
@@ -67,26 +67,26 @@ 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::Add,
//ffi::XK_KP_Add => events::VirtualKeyCode::NumpadAdd,
//ffi::XK_KP_Separator => events::VirtualKeyCode::Kp_separator,
ffi::XK_KP_Subtract => events::VirtualKeyCode::Subtract,
//ffi::XK_KP_Subtract => events::VirtualKeyCode::NumpadSubtract,
//ffi::XK_KP_Decimal => events::VirtualKeyCode::Kp_decimal,
ffi::XK_KP_Divide => events::VirtualKeyCode::Divide,
//ffi::XK_KP_Divide => events::VirtualKeyCode::NumpadDivide,
ffi::XK_KP_0 => events::VirtualKeyCode::Numpad0,
ffi::XK_KP_1 => events::VirtualKeyCode::Numpad1,
ffi::XK_KP_2 => events::VirtualKeyCode::Numpad2,
@@ -117,23 +117,23 @@ pub fn keysym_to_element(keysym: libc::c_uint) -> Option<VirtualKeyCode> {
//ffi::XK_L4 => events::VirtualKeyCode::L4,
ffi::XK_F15 => events::VirtualKeyCode::F15,
//ffi::XK_L5 => events::VirtualKeyCode::L5,
ffi::XK_F16 => events::VirtualKeyCode::F16,
//ffi::XK_F16 => events::VirtualKeyCode::F16,
//ffi::XK_L6 => events::VirtualKeyCode::L6,
ffi::XK_F17 => events::VirtualKeyCode::F17,
//ffi::XK_F17 => events::VirtualKeyCode::F17,
//ffi::XK_L7 => events::VirtualKeyCode::L7,
ffi::XK_F18 => events::VirtualKeyCode::F18,
//ffi::XK_F18 => events::VirtualKeyCode::F18,
//ffi::XK_L8 => events::VirtualKeyCode::L8,
ffi::XK_F19 => events::VirtualKeyCode::F19,
//ffi::XK_F19 => events::VirtualKeyCode::F19,
//ffi::XK_L9 => events::VirtualKeyCode::L9,
ffi::XK_F20 => events::VirtualKeyCode::F20,
//ffi::XK_F20 => events::VirtualKeyCode::F20,
//ffi::XK_L10 => events::VirtualKeyCode::L10,
ffi::XK_F21 => events::VirtualKeyCode::F21,
//ffi::XK_F21 => events::VirtualKeyCode::F21,
//ffi::XK_R1 => events::VirtualKeyCode::R1,
ffi::XK_F22 => events::VirtualKeyCode::F22,
//ffi::XK_F22 => events::VirtualKeyCode::F22,
//ffi::XK_R2 => events::VirtualKeyCode::R2,
ffi::XK_F23 => events::VirtualKeyCode::F23,
//ffi::XK_F23 => events::VirtualKeyCode::F23,
//ffi::XK_R3 => events::VirtualKeyCode::R3,
ffi::XK_F24 => events::VirtualKeyCode::F24,
//ffi::XK_F24 => events::VirtualKeyCode::F24,
//ffi::XK_R4 => events::VirtualKeyCode::R4,
//ffi::XK_F25 => events::VirtualKeyCode::F25,
//ffi::XK_R5 => events::VirtualKeyCode::R5,
@@ -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
View File

@@ -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
}

1559
src/platform/linux/x11/mod.rs
View File

File diff suppressed because it is too large Load Diff

284
src/platform/linux/x11/monitor.rs
View File

@@ -1,274 +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,
) -> Option<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);
Some(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);
let resources = if version_is_at_least(1, 3) {
(self.xrandr.XRRGetScreenResourcesCurrent)(self.display, root)
} else {
// WARNING: this function is supposedly very slow, on the order of hundreds of ms.
// Upon failure, `resources` will be null.
(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;
MonitorId::from_repr(
self,
resources,
monitor_index as u32,
monitor.into(),
is_primary,
).map(|monitor_id| available.push(monitor_id));
}
(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;
MonitorId::from_repr(
self,
resources,
crtc_id as u32,
crtc,
is_primary,
).map(|monitor_id| available.push(monitor_id));
}
(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,
}
}
}
}

236
src/platform/linux/x11/util/hint.rs
View File

@@ -1,236 +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/wm-spec-1.5.html).
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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,
/// A dropdown menu that usually appears when the user clicks on an item in a menu bar.
/// This property is typically used on override-redirect windows.
DropdownMenu,
/// A popup menu that usually appears when the user right clicks on an object.
/// This property is typically used on override-redirect windows.
PopupMenu,
/// A tooltip window. Usually used to show additional information when hovering over an object with the cursor.
/// This property is typically used on override-redirect windows.
Tooltip,
/// The window is a notification.
/// This property is typically used on override-redirect windows.
Notification,
/// This should be used on the windows that are popped up by combo boxes.
/// This property is typically used on override-redirect windows.
Combo,
/// This indicates the the window is being dragged.
/// This property is typically used on override-redirect windows.
Dnd,
/// 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",
&DropdownMenu => b"_NET_WM_WINDOW_TYPE_DROPDOWN_MENU\0",
&PopupMenu => b"_NET_WM_WINDOW_TYPE_POPUP_MENU\0",
&Tooltip => b"_NET_WM_WINDOW_TYPE_TOOLTIP\0",
&Notification => b"_NET_WM_WINDOW_TYPE_NOTIFICATION\0",
&Combo => b"_NET_WM_WINDOW_TYPE_COMBO\0",
&Dnd => b"_NET_WM_WINDOW_TYPE_DND\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()
}
}

134
src/platform/linux/x11/util/randr.rs
View File

@@ -1,134 +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 {
// Retrieve DPI from Xft.dpi property
pub unsafe fn get_xft_dpi(&self) -> Option<f64> {
(self.xlib.XrmInitialize)();
let resource_manager_str = (self.xlib.XResourceManagerString)(self.display);
if resource_manager_str == ptr::null_mut() {
return None;
}
if let Ok(res) = ::std::ffi::CStr::from_ptr(resource_manager_str).to_str() {
let name : &str = "Xft.dpi:\t";
for pair in res.split("\n") {
if pair.starts_with(&name) {
let res = &pair[name.len()..];
return f64::from_str(&res).ok();
}
}
}
None
}
pub unsafe fn get_output_info(
&self,
resources: *mut ffi::XRRScreenResources,
repr: &MonitorRepr,
) -> Option<(String, f64)> {
let output_info = (self.xrandr.XRRGetOutputInfo)(
self.display,
resources,
repr.get_output(),
);
if output_info.is_null() {
// When calling `XRRGetOutputInfo` on a virtual monitor (versus a physical display)
// it's possible for it to return null.
// https://bugs.debian.org/cgi-bin/bugreport.cgi?bug=816596
let _ = self.check_errors(); // discard `BadRROutput` error
return None;
}
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 = if let Some(dpi) = self.get_xft_dpi() {
dpi / 96.
} else {
calc_dpi_factor(
repr.get_dimensions(),
((*output_info).mm_width as u64, (*output_info).mm_height as u64),
)
};
(self.xrandr.XRRFreeOutputInfo)(output_info);
Some((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())
}
}

1957
src/platform/linux/x11/window.rs
View File

File diff suppressed because it is too large Load Diff

50
src/platform/linux/x11/xdisplay.rs
View File

@@ -1,25 +1,20 @@
use std::ptr;
use std::fmt;
use std::error::Error;
use std::os::raw::c_int;
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,
pub display: *mut ffi::Display,
pub x11_fd: c_int,
pub latest_error: Mutex<Option<XError>>,
}
@@ -31,12 +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) };
@@ -50,20 +44,13 @@ impl XConnection {
display
};
// Get X11 socket file descriptor
let fd = unsafe {
(xlib.XConnectionNumber)(display)
};
Ok(XConnection {
xlib,
xrandr,
xrandr_1_5,
xcursor,
xinput2,
xlib_xcb,
display,
x11_fd: fd,
xlib: xlib,
xf86vmode: xf86vmode,
xcursor: xcursor,
xinput2: xinput2,
xlib_xcb: xlib_xcb,
display: display,
latest_error: Mutex::new(None),
})
}
@@ -71,7 +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 {
@@ -82,13 +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;
}
}

672
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,
},
@@ -514,97 +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 char_to_keycode(c: char) -> Option<events::VirtualKeyCode> {
// We only translate keys that are affected by keyboard layout.
//
// Note that since keys are translated in a somewhat "dumb" way (reading character)
// there is a concern that some combination, i.e. Cmd+char, causes the wrong
// letter to be received, and so we receive the wrong key.
//
// Implementation reference: https://github.com/WebKit/webkit/blob/82bae82cf0f329dbe21059ef0986c4e92fea4ba6/Source/WebCore/platform/cocoa/KeyEventCocoa.mm#L626
Some(match c {
'a' | 'A' => events::VirtualKeyCode::A,
'b' | 'B' => events::VirtualKeyCode::B,
'c' | 'C' => events::VirtualKeyCode::C,
'd' | 'D' => events::VirtualKeyCode::D,
'e' | 'E' => events::VirtualKeyCode::E,
'f' | 'F' => events::VirtualKeyCode::F,
'g' | 'G' => events::VirtualKeyCode::G,
'h' | 'H' => events::VirtualKeyCode::H,
'i' | 'I' => events::VirtualKeyCode::I,
'j' | 'J' => events::VirtualKeyCode::J,
'k' | 'K' => events::VirtualKeyCode::K,
'l' | 'L' => events::VirtualKeyCode::L,
'm' | 'M' => events::VirtualKeyCode::M,
'n' | 'N' => events::VirtualKeyCode::N,
'o' | 'O' => events::VirtualKeyCode::O,
'p' | 'P' => events::VirtualKeyCode::P,
'q' | 'Q' => events::VirtualKeyCode::Q,
'r' | 'R' => events::VirtualKeyCode::R,
's' | 'S' => events::VirtualKeyCode::S,
't' | 'T' => events::VirtualKeyCode::T,
'u' | 'U' => events::VirtualKeyCode::U,
'v' | 'V' => events::VirtualKeyCode::V,
'w' | 'W' => events::VirtualKeyCode::W,
'x' | 'X' => events::VirtualKeyCode::X,
'y' | 'Y' => events::VirtualKeyCode::Y,
'z' | 'Z' => events::VirtualKeyCode::Z,
'1' | '!' => events::VirtualKeyCode::Key1,
'2' | '@' => events::VirtualKeyCode::Key2,
'3' | '#' => events::VirtualKeyCode::Key3,
'4' | '$' => events::VirtualKeyCode::Key4,
'5' | '%' => events::VirtualKeyCode::Key5,
'6' | '^' => events::VirtualKeyCode::Key6,
'7' | '&' => events::VirtualKeyCode::Key7,
'8' | '*' => events::VirtualKeyCode::Key8,
'9' | '(' => events::VirtualKeyCode::Key9,
'0' | ')' => events::VirtualKeyCode::Key0,
'=' | '+' => events::VirtualKeyCode::Equals,
'-' | '_' => events::VirtualKeyCode::Minus,
']' | '}' => events::VirtualKeyCode::RBracket,
'[' | '{' => events::VirtualKeyCode::LBracket,
'\''| '"' => events::VirtualKeyCode::Apostrophe,
';' | ':' => events::VirtualKeyCode::Semicolon,
'\\'| '|' => events::VirtualKeyCode::Backslash,
',' | '<' => events::VirtualKeyCode::Comma,
'/' | '?' => events::VirtualKeyCode::Slash,
'.' | '>' => events::VirtualKeyCode::Period,
'`' | '~' => events::VirtualKeyCode::Grave,
_ => return None,
})
}
pub fn scancode_to_keycode(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,
@@ -664,13 +546,13 @@ pub fn scancode_to_keycode(code: c_ushort) -> Option<events::VirtualKeyCode> {
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 => events::VirtualKeyCode::F17,
//0x40 => F17 Key,
0x41 => events::VirtualKeyCode::Decimal,
//0x42 -> unkown,
0x43 => events::VirtualKeyCode::Multiply,
@@ -683,11 +565,10 @@ pub fn scancode_to_keycode(code: c_ushort) -> Option<events::VirtualKeyCode> {
0x4a => events::VirtualKeyCode::VolumeDown,
0x4b => events::VirtualKeyCode::Divide,
0x4c => events::VirtualKeyCode::NumpadEnter,
0x4e => events::VirtualKeyCode::Subtract,
//0x4d => unkown,
0x4e => events::VirtualKeyCode::Subtract,
0x4f => events::VirtualKeyCode::F18,
0x50 => events::VirtualKeyCode::F19,
//0x4f => F18 key,
//0x50 => F19 Key,
0x51 => events::VirtualKeyCode::NumpadEquals,
0x52 => events::VirtualKeyCode::Numpad0,
0x53 => events::VirtualKeyCode::Numpad1,
@@ -697,11 +578,11 @@ pub fn scancode_to_keycode(code: c_ushort) -> Option<events::VirtualKeyCode> {
0x57 => events::VirtualKeyCode::Numpad5,
0x58 => events::VirtualKeyCode::Numpad6,
0x59 => events::VirtualKeyCode::Numpad7,
0x5a => events::VirtualKeyCode::F20,
//0x5a => F20 Key,
0x5b => events::VirtualKeyCode::Numpad8,
0x5c => events::VirtualKeyCode::Numpad9,
0x5d => events::VirtualKeyCode::Yen,
//0x5e => JIS Ro,
//0x5d => unkown,
//0x5e => unkown,
//0x5f => unkown,
0x60 => events::VirtualKeyCode::F5,
0x61 => events::VirtualKeyCode::F6,
@@ -709,11 +590,11 @@ pub fn scancode_to_keycode(code: c_ushort) -> Option<events::VirtualKeyCode> {
0x63 => events::VirtualKeyCode::F3,
0x64 => events::VirtualKeyCode::F8,
0x65 => events::VirtualKeyCode::F9,
//0x66 => JIS Eisuu (macOS),
//0x66 => unkown,
0x67 => events::VirtualKeyCode::F11,
//0x68 => JIS Kana (macOS),
//0x68 => unkown,
0x69 => events::VirtualKeyCode::F13,
0x6a => events::VirtualKeyCode::F16,
//0x6a => F16 Key,
0x6b => events::VirtualKeyCode::F14,
//0x6c => unkown,
0x6d => events::VirtualKeyCode::F10,
@@ -736,77 +617,18 @@ pub fn scancode_to_keycode(code: c_ushort) -> Option<events::VirtualKeyCode> {
0x7e => events::VirtualKeyCode::Up,
//0x7f => unkown,
0xa => events::VirtualKeyCode::Caret,
_ => return None,
})
}
pub fn check_function_keys(
s: &String
) -> Option<events::VirtualKeyCode> {
if let Some(ch) = s.encode_utf16().next() {
return Some(match ch {
0xf718 => events::VirtualKeyCode::F21,
0xf719 => events::VirtualKeyCode::F22,
0xf71a => events::VirtualKeyCode::F23,
0xf71b => events::VirtualKeyCode::F24,
_ => return None,
})
}
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),
}
}
pub fn get_scancode(event: cocoa::base::id) -> c_ushort {
// In AppKit, `keyCode` refers to the position (scancode) of a key rather than its character,
// and there is no easy way to navtively retrieve the layout-dependent character.
// In winit, we use keycode to refer to the key's character, and so this function aligns
// AppKit's terminology with ours.
unsafe {
msg_send![event, keyCode]
}
}
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 scancode = get_scancode(ns_event);
let virtual_keycode = scancode_to_keycode(scancode);
Some(WindowEvent::KeyboardInput {
device_id: DEVICE_ID,
input: KeyboardInput {
state,
scancode: scancode as u32,
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 _,
}

47
src/platform/macos/mod.rs
View File

@@ -1,51 +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;
impl DeviceId {
pub unsafe fn dummy() -> Self {
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
}
}

149
src/platform/macos/util/cursor.rs
View File

@@ -1,149 +0,0 @@
use cocoa::{
appkit::NSImage, base::{id, nil, YES},
foundation::{NSDictionary, NSPoint, NSString},
};
use objc::runtime::Sel;
use super::IntoOption;
use MouseCursor;
pub enum Cursor {
Native(&'static str),
Undocumented(&'static str),
WebKit(&'static str),
}
impl From<MouseCursor> for Cursor {
fn from(cursor: MouseCursor) -> Self {
match cursor {
MouseCursor::Arrow | MouseCursor::Default => Cursor::Native("arrowCursor"),
MouseCursor::Hand => Cursor::Native("pointingHandCursor"),
MouseCursor::Grabbing | MouseCursor::Grab => Cursor::Native("closedHandCursor"),
MouseCursor::Text => Cursor::Native("IBeamCursor"),
MouseCursor::VerticalText => Cursor::Native("IBeamCursorForVerticalLayout"),
MouseCursor::Copy => Cursor::Native("dragCopyCursor"),
MouseCursor::Alias => Cursor::Native("dragLinkCursor"),
MouseCursor::NotAllowed | MouseCursor::NoDrop => Cursor::Native("operationNotAllowedCursor"),
MouseCursor::ContextMenu => Cursor::Native("contextualMenuCursor"),
MouseCursor::Crosshair => Cursor::Native("crosshairCursor"),
MouseCursor::EResize => Cursor::Native("resizeRightCursor"),
MouseCursor::NResize => Cursor::Native("resizeUpCursor"),
MouseCursor::WResize => Cursor::Native("resizeLeftCursor"),
MouseCursor::SResize => Cursor::Native("resizeDownCursor"),
MouseCursor::EwResize | MouseCursor::ColResize => Cursor::Native("resizeLeftRightCursor"),
MouseCursor::NsResize | MouseCursor::RowResize => Cursor::Native("resizeUpDownCursor"),
// Undocumented cursors: https://stackoverflow.com/a/46635398/5435443
MouseCursor::Help => Cursor::Undocumented("_helpCursor"),
MouseCursor::ZoomIn => Cursor::Undocumented("_zoomInCursor"),
MouseCursor::ZoomOut => Cursor::Undocumented("_zoomOutCursor"),
MouseCursor::NeResize => Cursor::Undocumented("_windowResizeNorthEastCursor"),
MouseCursor::NwResize => Cursor::Undocumented("_windowResizeNorthWestCursor"),
MouseCursor::SeResize => Cursor::Undocumented("_windowResizeSouthEastCursor"),
MouseCursor::SwResize => Cursor::Undocumented("_windowResizeSouthWestCursor"),
MouseCursor::NeswResize => Cursor::Undocumented("_windowResizeNorthEastSouthWestCursor"),
MouseCursor::NwseResize => Cursor::Undocumented("_windowResizeNorthWestSouthEastCursor"),
// While these are available, the former just loads a white arrow,
// and the latter loads an ugly deflated beachball!
// MouseCursor::Move => Cursor::Undocumented("_moveCursor"),
// MouseCursor::Wait => Cursor::Undocumented("_waitCursor"),
// An even more undocumented cursor...
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=522349
// This is the wrong semantics for `Wait`, but it's the same as
// what's used in Safari and Chrome.
MouseCursor::Wait | MouseCursor::Progress => Cursor::Undocumented("busyButClickableCursor"),
// For the rest, we can just snatch the cursors from WebKit...
// They fit the style of the native cursors, and will seem
// completely standard to macOS users.
// https://stackoverflow.com/a/21786835/5435443
MouseCursor::Move | MouseCursor::AllScroll => Cursor::WebKit("move"),
MouseCursor::Cell => Cursor::WebKit("cell"),
}
}
}
impl Default for Cursor {
fn default() -> Self {
Cursor::Native("arrowCursor")
}
}
impl Cursor {
pub unsafe fn load(&self) -> id {
match self {
Cursor::Native(cursor_name) => {
let sel = Sel::register(cursor_name);
msg_send![class!(NSCursor), performSelector:sel]
},
Cursor::Undocumented(cursor_name) => {
let class = class!(NSCursor);
let sel = Sel::register(cursor_name);
let sel = if msg_send![class, respondsToSelector:sel] {
sel
} else {
warn!("Cursor `{}` appears to be invalid", cursor_name);
sel!(arrowCursor)
};
msg_send![class, performSelector:sel]
},
Cursor::WebKit(cursor_name) => load_webkit_cursor(cursor_name)
.unwrap_or_else(|message| {
warn!("{}", message);
Self::default().load()
}),
}
}
}
// Note that loading `busybutclickable` with this code won't animate the frames;
// instead you'll just get them all in a column.
unsafe fn load_webkit_cursor(cursor_name_str: &str) -> Result<id, String> {
static CURSOR_ROOT: &'static str = "/System/Library/Frameworks/ApplicationServices.framework/Versions/A/Frameworks/HIServices.framework/Versions/A/Resources/cursors";
let cursor_root = NSString::alloc(nil).init_str(CURSOR_ROOT);
let cursor_name = NSString::alloc(nil).init_str(cursor_name_str);
let cursor_pdf = NSString::alloc(nil).init_str("cursor.pdf");
let cursor_plist = NSString::alloc(nil).init_str("info.plist");
let key_x = NSString::alloc(nil).init_str("hotx");
let key_y = NSString::alloc(nil).init_str("hoty");
let cursor_path: id = msg_send![cursor_root,
stringByAppendingPathComponent:cursor_name
];
let pdf_path: id = msg_send![cursor_path,
stringByAppendingPathComponent:cursor_pdf
];
let info_path: id = msg_send![cursor_path,
stringByAppendingPathComponent:cursor_plist
];
let image = NSImage::alloc(nil)
.initByReferencingFile_(pdf_path)
// This will probably never be `None`, since images are loaded lazily...
.into_option()
// because of that, we need to check for validity.
.filter(|image| image.isValid() == YES)
.ok_or_else(||
format!("Failed to read image for `{}` cursor", cursor_name_str)
)?;
let info = NSDictionary::dictionaryWithContentsOfFile_(nil, info_path)
.into_option()
.ok_or_else(||
format!("Failed to read info for `{}` cursor", cursor_name_str)
)?;
let x = info.valueForKey_(key_x);
let y = info.valueForKey_(key_y);
let point = NSPoint::new(
msg_send![x, doubleValue],
msg_send![y, doubleValue],
);
let cursor: id = msg_send![class!(NSCursor), alloc];
let cursor: id = msg_send![cursor, initWithImage:image hotSpot:point];
cursor
.into_option()
.ok_or_else(||
format!("Failed to initialize `{}` cursor", cursor_name_str)
)
}

14
src/platform/macos/util/into_option.rs
View File

@@ -1,14 +0,0 @@
use cocoa::base::{id, nil};
pub trait IntoOption: Sized {
fn into_option(self) -> Option<Self>;
}
impl IntoOption for id {
fn into_option(self) -> Option<Self> {
match self != nil {
true => Some(self),
false => None,
}
}
}

63
src/platform/macos/util/mod.rs
View File

@@ -1,63 +0,0 @@
mod cursor;
mod into_option;
pub use self::{cursor::Cursor, into_option::IntoOption};
use cocoa::appkit::NSWindowStyleMask;
use cocoa::base::{id, nil};
use cocoa::foundation::{NSRect, NSUInteger};
use core_graphics::display::CGDisplay;
use objc::runtime::{Class, Object};
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 toggle_style_mask(window: id, view: id, mask: NSWindowStyleMask, on: bool) {
use cocoa::appkit::NSWindow;
let current_style_mask = window.styleMask();
if on {
window.setStyleMask_(current_style_mask | mask);
} else {
window.setStyleMask_(current_style_mask & (!mask));
}
// If we don't do this, key handling will break. Therefore, never call `setStyleMask` directly!
window.makeFirstResponder_(view);
}
pub unsafe fn superclass<'a>(this: &'a Object) -> &'a Class {
let superclass: id = msg_send![this, superclass];
&*(superclass as *const _)
}
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];
}

663
src/platform/macos/view.rs
View File

@@ -1,663 +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::{Arc, Mutex, 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, scancode_to_keycode, char_to_keycode, check_function_keys, get_scancode};
use platform::platform::util;
use platform::platform::ffi::*;
use platform::platform::window::{get_window_id, IdRef};
use events;
struct ViewState {
window: id,
shared: Weak<Shared>,
cursor: Arc<Mutex<util::Cursor>>,
ime_spot: Option<(f64, f64)>,
raw_characters: Option<String>,
is_key_down: bool,
}
pub fn new_view(window: id, shared: Weak<Shared>) -> (IdRef, Weak<Mutex<util::Cursor>>) {
let cursor = Default::default();
let cursor_access = Arc::downgrade(&cursor);
let state = ViewState {
window,
shared,
cursor,
ime_spot: None,
raw_characters: None,
is_key_down: false,
};
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]), cursor_access)
}
}
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!(drawRect:),
draw_rect as extern fn(&Object, Sel, NSRect),
);
decl.add_method(
sel!(resetCursorRects),
reset_cursor_rects as extern fn(&Object, Sel),
);
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 draw_rect(this: &Object, _sel: Sel, rect: NSRect) {
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
if let Some(shared) = state.shared.upgrade() {
let window_event = Event::WindowEvent {
window_id: WindowId(get_window_id(state.window)),
event: WindowEvent::Refresh,
};
shared.pending_events
.lock()
.unwrap()
.push_back(window_event);
}
let superclass = util::superclass(this);
let () = msg_send![super(this, superclass), drawRect:rect];
}
}
extern fn reset_cursor_rects(this: &Object, _sel: Sel) {
unsafe {
let state_ptr: *mut c_void = *this.get_ivar("winitState");
let state = &mut *(state_ptr as *mut ViewState);
let bounds: NSRect = msg_send![this, bounds];
let cursor = state.cursor.lock().unwrap().load();
let _: () = msg_send![this,
addCursorRect:bounds
cursor:cursor
];
}
}
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.is_key_down = true;
// 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);
}
}
fn get_characters(event: id, ignore_modifiers: bool) -> String {
unsafe {
let characters: id = if ignore_modifiers {
msg_send![event, charactersIgnoringModifiers]
} else {
msg_send![event, characters]
};
assert_ne!(characters, nil);
let slice = slice::from_raw_parts(
characters.UTF8String() as *const c_uchar,
characters.len(),
);
let string = str::from_utf8_unchecked(slice);
string.to_owned()
}
}
// Retrieves a layout-independent keycode given an event.
fn retrieve_keycode(event: id) -> Option<events::VirtualKeyCode> {
#[inline]
fn get_code(ev: id, raw: bool) -> Option<events::VirtualKeyCode> {
let characters = get_characters(ev, raw);
characters.chars().next().map_or(None, |c| char_to_keycode(c))
}
// Cmd switches Roman letters for Dvorak-QWERTY layout, so we try modified characters first.
// If we don't get a match, then we fall back to unmodified characters.
let code = get_code(event, false)
.or_else(|| {
get_code(event, true)
});
// We've checked all layout related keys, so fall through to scancode.
// Reaching this code means that the key is layout-independent (e.g. Backspace, Return).
//
// We're additionally checking here for F21-F24 keys, since their keycode
// can vary, but we know that they are encoded
// in characters property.
code.or_else(|| {
let scancode = get_scancode(event);
scancode_to_keycode(scancode)
.or_else(|| {
check_function_keys(&get_characters(event, true))
})
})
}
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 characters = get_characters(event, false);
state.raw_characters = Some(characters.clone());
let scancode = get_scancode(event) as u32;
let virtual_keycode = retrieve_keycode(event);
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),
},
},
};
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.is_key_down{
for character in characters.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.is_key_down = false;
let scancode = get_scancode(event) as u32;
let virtual_keycode = retrieve_keycode(event);
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
}

1330
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) })
}

226
src/platform/windows/drop_handler.rs
View File

@@ -1,226 +0,0 @@
use std::ffi::OsString;
use std::os::windows::ffi::OsStringExt;
use std::path::PathBuf;
use std::sync::atomic::{AtomicUsize, Ordering};
use std::{mem, ptr};
use winapi::ctypes::c_void;
use winapi::shared::guiddef::REFIID;
use winapi::shared::minwindef::{DWORD, MAX_PATH, UINT, ULONG};
use winapi::shared::windef::{HWND, POINTL};
use winapi::shared::winerror::S_OK;
use winapi::um::objidl::IDataObject;
use winapi::um::oleidl::{DROPEFFECT_COPY, DROPEFFECT_NONE, IDropTarget, IDropTargetVtbl};
use winapi::um::winnt::HRESULT;
use winapi::um::{shellapi, unknwnbase};
use platform::platform::events_loop::send_event;
use platform::platform::WindowId;
use {Event, WindowId as SuperWindowId};
#[repr(C)]
pub struct FileDropHandlerData {
pub interface: IDropTarget,
refcount: AtomicUsize,
window: HWND,
cursor_effect: DWORD,
hovered_is_valid: bool, // If the currently hovered item is not valid there must not be any `HoveredFileCancelled` emitted
}
pub struct FileDropHandler {
pub data: *mut FileDropHandlerData,
}
#[allow(non_snake_case)]
impl FileDropHandler {
pub fn new(window: HWND) -> FileDropHandler {
let data = Box::new(FileDropHandlerData {
interface: IDropTarget {
lpVtbl: &DROP_TARGET_VTBL as *const IDropTargetVtbl,
},
refcount: AtomicUsize::new(1),
window,
cursor_effect: DROPEFFECT_NONE,
hovered_is_valid: false,
});
FileDropHandler {
data: Box::into_raw(data),
}
}
// Implement IUnknown
pub unsafe extern "system" fn QueryInterface(
_this: *mut unknwnbase::IUnknown,
_riid: REFIID,
_ppvObject: *mut *mut c_void,
) -> HRESULT {
// This function doesn't appear to be required for an `IDropTarget`.
// An implementation would be nice however.
unimplemented!();
}
pub unsafe extern "system" fn AddRef(this: *mut unknwnbase::IUnknown) -> ULONG {
let drop_handler_data = Self::from_interface(this);
let count = drop_handler_data.refcount.fetch_add(1, Ordering::Release) + 1;
count as ULONG
}
pub unsafe extern "system" fn Release(this: *mut unknwnbase::IUnknown) -> ULONG {
let drop_handler = Self::from_interface(this);
let count = drop_handler.refcount.fetch_sub(1, Ordering::Release) - 1;
if count == 0 {
// Destroy the underlying data
Box::from_raw(drop_handler as *mut FileDropHandlerData);
}
count as ULONG
}
pub unsafe extern "system" fn DragEnter(
this: *mut IDropTarget,
pDataObj: *const IDataObject,
_grfKeyState: DWORD,
_pt: *const POINTL,
pdwEffect: *mut DWORD,
) -> HRESULT {
use events::WindowEvent::HoveredFile;
let drop_handler = Self::from_interface(this);
let hdrop = Self::iterate_filenames(pDataObj, |filename| {
send_event(Event::WindowEvent {
window_id: SuperWindowId(WindowId(drop_handler.window)),
event: HoveredFile(filename),
});
});
drop_handler.hovered_is_valid = hdrop.is_some();
drop_handler.cursor_effect = if drop_handler.hovered_is_valid {
DROPEFFECT_COPY
} else {
DROPEFFECT_NONE
};
*pdwEffect = drop_handler.cursor_effect;
S_OK
}
pub unsafe extern "system" fn DragOver(
this: *mut IDropTarget,
_grfKeyState: DWORD,
_pt: *const POINTL,
pdwEffect: *mut DWORD,
) -> HRESULT {
let drop_handler = Self::from_interface(this);
*pdwEffect = drop_handler.cursor_effect;
S_OK
}
pub unsafe extern "system" fn DragLeave(this: *mut IDropTarget) -> HRESULT {
use events::WindowEvent::HoveredFileCancelled;
let drop_handler = Self::from_interface(this);
if drop_handler.hovered_is_valid {
send_event(Event::WindowEvent {
window_id: SuperWindowId(WindowId(drop_handler.window)),
event: HoveredFileCancelled,
});
}
S_OK
}
pub unsafe extern "system" fn Drop(
this: *mut IDropTarget,
pDataObj: *const IDataObject,
_grfKeyState: DWORD,
_pt: *const POINTL,
_pdwEffect: *mut DWORD,
) -> HRESULT {
use events::WindowEvent::DroppedFile;
let drop_handler = Self::from_interface(this);
let hdrop = Self::iterate_filenames(pDataObj, |filename| {
send_event(Event::WindowEvent {
window_id: SuperWindowId(WindowId(drop_handler.window)),
event: DroppedFile(filename),
});
});
if let Some(hdrop) = hdrop {
shellapi::DragFinish(hdrop);
}
S_OK
}
unsafe fn from_interface<'a, InterfaceT>(this: *mut InterfaceT) -> &'a mut FileDropHandlerData {
&mut *(this as *mut _)
}
unsafe fn iterate_filenames<F>(data_obj: *const IDataObject, callback: F) -> Option<shellapi::HDROP>
where
F: Fn(PathBuf),
{
use winapi::ctypes::wchar_t;
use winapi::shared::winerror::{SUCCEEDED, DV_E_FORMATETC};
use winapi::shared::wtypes::{CLIPFORMAT, DVASPECT_CONTENT};
use winapi::um::objidl::{FORMATETC, TYMED_HGLOBAL};
use winapi::um::shellapi::DragQueryFileW;
use winapi::um::winuser::CF_HDROP;
let mut drop_format = FORMATETC {
cfFormat: CF_HDROP as CLIPFORMAT,
ptd: ptr::null(),
dwAspect: DVASPECT_CONTENT,
lindex: -1,
tymed: TYMED_HGLOBAL,
};
let mut medium = mem::uninitialized();
let get_data_result = (*data_obj).GetData(&mut drop_format, &mut medium);
if SUCCEEDED(get_data_result) {
let hglobal = (*medium.u).hGlobal();
let hdrop = (*hglobal) as shellapi::HDROP;
// The second parameter (0xFFFFFFFF) instructs the function to return the item count
let item_count = DragQueryFileW(hdrop, 0xFFFFFFFF, ptr::null_mut(), 0);
let mut pathbuf: [wchar_t; MAX_PATH] = mem::uninitialized();
for i in 0..item_count {
let character_count =
DragQueryFileW(hdrop, i, pathbuf.as_mut_ptr(), MAX_PATH as UINT) as usize;
if character_count > 0 {
callback(OsString::from_wide(&pathbuf[0..character_count]).into());
}
}
return Some(hdrop);
} else if get_data_result == DV_E_FORMATETC {
// If the dropped item is not a file this error will occur.
// In this case it is OK to return without taking further action.
debug!("Error occured while processing dropped/hovered item: item is not a file.");
return None;
} else {
debug!("Unexpected error occured while processing dropped/hovered item.");
return None;
}
}
}
impl Drop for FileDropHandler {
fn drop(&mut self) {
unsafe {
FileDropHandler::Release(self.data as *mut unknwnbase::IUnknown);
}
}
}
static DROP_TARGET_VTBL: IDropTargetVtbl = IDropTargetVtbl {
parent: unknwnbase::IUnknownVtbl {
QueryInterface: FileDropHandler::QueryInterface,
AddRef: FileDropHandler::AddRef,
Release: FileDropHandler::Release,
},
DragEnter: FileDropHandler::DragEnter,
DragOver: FileDropHandler::DragOver,
DragLeave: FileDropHandler::DragLeave,
Drop: FileDropHandler::Drop,
};

435
src/platform/windows/event.rs
View File

@@ -1,136 +1,86 @@
use std::{char, ptr};
use std::os::raw::c_int;
use std::sync::atomic::{AtomicBool, AtomicPtr, Ordering};
use events::VirtualKeyCode;
use events::ModifiersState;
use winapi::shared::minwindef::{WPARAM, LPARAM, UINT, HKL, HKL__};
use winapi::um::winuser;
use winapi;
use user32;
use ScanCode;
fn key_pressed(vkey: c_int) -> bool {
unsafe {
(winuser::GetKeyState(vkey) & (1 << 15)) == (1 << 15)
}
}
const MAPVK_VSC_TO_VK_EX: u32 = 3;
pub fn get_key_mods() -> ModifiersState {
let mut mods = ModifiersState::default();
let filter_out_altgr = layout_uses_altgr() && key_pressed(winuser::VK_RMENU);
mods.shift = key_pressed(winuser::VK_SHIFT);
mods.ctrl = key_pressed(winuser::VK_CONTROL) && !filter_out_altgr;
mods.alt = key_pressed(winuser::VK_MENU) && !filter_out_altgr;
mods.logo = key_pressed(winuser::VK_LWIN) || key_pressed(winuser::VK_RWIN);
unsafe {
if user32::GetKeyState(winapi::VK_SHIFT) & (1 << 15) == (1 << 15) {
mods.shift = true;
}
if user32::GetKeyState(winapi::VK_CONTROL) & (1 << 15) == (1 << 15) {
mods.ctrl = true;
}
if user32::GetKeyState(winapi::VK_MENU) & (1 << 15) == (1 << 15) {
mods.alt = true;
}
if (user32::GetKeyState(winapi::VK_LWIN) | user32::GetKeyState(winapi::VK_RWIN)) & (1 << 15) == (1 << 15) {
mods.logo = true;
}
}
mods
}
unsafe fn get_char(keyboard_state: &[u8; 256], v_key: u32, hkl: HKL) -> Option<char> {
let mut unicode_bytes = [0u16; 5];
let len = winuser::ToUnicodeEx(v_key, 0, keyboard_state.as_ptr(), unicode_bytes.as_mut_ptr(), unicode_bytes.len() as _, 0, hkl);
if len >= 1 {
char::decode_utf16(unicode_bytes.into_iter().cloned()).next().and_then(|c| c.ok())
} else {
None
}
}
/// Figures out if the keyboard layout has an AltGr key instead of an Alt key.
///
/// Unfortunately, the Windows API doesn't give a way for us to conveniently figure that out. So,
/// we use a technique blatantly stolen from [the Firefox source code][source]: iterate over every
/// possible virtual key and compare the `char` output when AltGr is pressed vs when it isn't. If
/// pressing AltGr outputs characters that are different from the standard characters, the layout
/// uses AltGr. Otherwise, it doesn't.
///
/// [source]: https://github.com/mozilla/gecko-dev/blob/265e6721798a455604328ed5262f430cfcc37c2f/widget/windows/KeyboardLayout.cpp#L4356-L4416
fn layout_uses_altgr() -> bool {
unsafe {
static ACTIVE_LAYOUT: AtomicPtr<HKL__> = AtomicPtr::new(ptr::null_mut());
static USES_ALTGR: AtomicBool = AtomicBool::new(false);
let hkl = winuser::GetKeyboardLayout(0);
let old_hkl = ACTIVE_LAYOUT.swap(hkl, Ordering::SeqCst);
if hkl == old_hkl {
return USES_ALTGR.load(Ordering::SeqCst);
}
let mut keyboard_state_altgr = [0u8; 256];
// AltGr is an alias for Ctrl+Alt for... some reason. Whatever it is, those are the keypresses
// we have to emulate to do an AltGr test.
keyboard_state_altgr[winuser::VK_MENU as usize] = 0x80;
keyboard_state_altgr[winuser::VK_CONTROL as usize] = 0x80;
let keyboard_state_empty = [0u8; 256];
for v_key in 0..=255 {
let key_noaltgr = get_char(&keyboard_state_empty, v_key, hkl);
let key_altgr = get_char(&keyboard_state_altgr, v_key, hkl);
if let (Some(noaltgr), Some(altgr)) = (key_noaltgr, key_altgr) {
if noaltgr != altgr {
USES_ALTGR.store(true, Ordering::SeqCst);
return true;
}
}
}
USES_ALTGR.store(false, Ordering::SeqCst);
false
}
}
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),
@@ -167,155 +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
}
})
}

1264
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
View File

@@ -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(())
}

409
src/platform/windows/mod.rs
View File

@@ -1,74 +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, Copy)]
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 unsafe fn dummy() -> Self {
DeviceId(0)
}
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) };
}
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
/// 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 {}
impl WindowId {
pub unsafe fn dummy() -> Self {
use std::ptr::null_mut;
WindowId(null_mut())
impl WindowProxy {
#[inline]
pub fn wakeup_event_loop(&self) {
unsafe {
user32::PostMessageA(self.hwnd, *WAKEUP_MSG_ID, 0, 0);
}
}
}
mod dpi;
mod drop_handler;
mod event;
mod events_loop;
mod icon;
mod monitor;
mod raw_input;
mod util;
mod window;
mod window_state;
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()
}
}
pub(crate) 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,
),
]
}

183
src/platform/windows/util.rs
View File

@@ -1,183 +0,0 @@
use std::{self, mem, ptr, slice, io};
use std::ops::BitAnd;
use std::sync::atomic::{AtomicBool, Ordering};
use MouseCursor;
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
}
}
fn win_to_err<F: FnOnce() -> BOOL>(f: F) -> Result<(), io::Error> {
if f() != 0 {
Ok(())
} else {
Err(io::Error::last_os_error())
}
}
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)) }
}
pub fn get_client_rect(hwnd: HWND) -> Result<RECT, io::Error> {
unsafe {
let mut rect = mem::uninitialized();
let mut top_left = mem::zeroed();
win_to_err(|| winuser::ClientToScreen(hwnd, &mut top_left))?;
win_to_err(|| winuser::GetClientRect(hwnd, &mut rect))?;
rect.left += top_left.x;
rect.top += top_left.y;
rect.right += top_left.x;
rect.bottom += top_left.y;
Ok(rect)
}
}
pub fn adjust_window_rect(hwnd: HWND, rect: RECT) -> Option<RECT> {
unsafe {
let style = winuser::GetWindowLongW(hwnd, winuser::GWL_STYLE);
let style_ex = winuser::GetWindowLongW(hwnd, winuser::GWL_EXSTYLE);
adjust_window_rect_with_styles(hwnd, style as _, style_ex as _, rect)
}
}
pub fn adjust_window_rect_with_styles(hwnd: HWND, style: DWORD, style_ex: DWORD, rect: RECT) -> Option<RECT> {
unsafe { status_map(|r| {
*r = rect;
let b_menu = !winuser::GetMenu(hwnd).is_null() as BOOL;
winuser::AdjustWindowRectEx(r, style as _ , b_menu, style_ex as _)
}) }
}
pub fn set_cursor_hidden(hidden: bool) {
static HIDDEN: AtomicBool = AtomicBool::new(false);
let changed = HIDDEN.swap(hidden, Ordering::SeqCst) ^ hidden;
if changed {
unsafe{ winuser::ShowCursor(!hidden as BOOL) };
}
}
pub fn set_cursor_clip(rect: Option<RECT>) -> Result<(), io::Error> {
unsafe {
let rect_ptr = rect.as_ref().map(|r| r as *const RECT).unwrap_or(ptr::null());
win_to_err(|| winuser::ClipCursor(rect_ptr))
}
}
pub fn is_focused(window: HWND) -> bool {
window == unsafe{ winuser::GetActiveWindow() }
}
#[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
}
impl MouseCursor {
pub(crate) fn to_windows_cursor(self) -> *const wchar_t {
match self {
MouseCursor::Arrow | MouseCursor::Default => winuser::IDC_ARROW,
MouseCursor::Hand => winuser::IDC_HAND,
MouseCursor::Crosshair => winuser::IDC_CROSS,
MouseCursor::Text | MouseCursor::VerticalText => winuser::IDC_IBEAM,
MouseCursor::NotAllowed | MouseCursor::NoDrop => winuser::IDC_NO,
MouseCursor::Grab | MouseCursor::Grabbing |
MouseCursor::Move | MouseCursor::AllScroll => winuser::IDC_SIZEALL,
MouseCursor::EResize | MouseCursor::WResize |
MouseCursor::EwResize | MouseCursor::ColResize => winuser::IDC_SIZEWE,
MouseCursor::NResize | MouseCursor::SResize |
MouseCursor::NsResize | MouseCursor::RowResize => winuser::IDC_SIZENS,
MouseCursor::NeResize | MouseCursor::SwResize |
MouseCursor::NeswResize => winuser::IDC_SIZENESW,
MouseCursor::NwResize | MouseCursor::SeResize |
MouseCursor::NwseResize => winuser::IDC_SIZENWSE,
MouseCursor::Wait => winuser::IDC_WAIT,
MouseCursor::Progress => winuser::IDC_APPSTARTING,
MouseCursor::Help => winuser::IDC_HELP,
_ => winuser::IDC_ARROW, // use arrow for the missing cases.
}
}
}

854
src/platform/windows/window.rs
View File

@@ -1,854 +0,0 @@
#![cfg(target_os = "windows")]
use std::{io, mem, ptr};
use std::cell::Cell;
use std::ffi::OsStr;
use std::os::windows::ffi::OsStrExt;
use std::sync::{Arc, Mutex};
use std::sync::mpsc::channel;
use winapi::ctypes::c_int;
use winapi::shared::minwindef::{DWORD, LPARAM, UINT, WORD, WPARAM};
use winapi::shared::windef::{HWND, POINT, RECT};
use winapi::um::{combaseapi, dwmapi, libloaderapi, winuser};
use winapi::um::objbase::COINIT_MULTITHREADED;
use winapi::um::shobjidl_core::{CLSID_TaskbarList, ITaskbarList2};
use winapi::um::wingdi::{CreateRectRgn, DeleteObject};
use winapi::um::winnt::{LONG, LPCWSTR};
use {
CreationError,
Icon,
LogicalPosition,
LogicalSize,
MonitorId as RootMonitorId,
MouseCursor,
PhysicalSize,
WindowAttributes,
};
use platform::platform::{PlatformSpecificWindowBuilderAttributes, WindowId};
use platform::platform::dpi::{dpi_to_scale_factor, get_hwnd_dpi};
use platform::platform::events_loop::{self, EventsLoop, DESTROY_MSG_ID, INITIAL_DPI_MSG_ID};
use platform::platform::icon::{self, IconType, WinIcon};
use platform::platform::monitor::get_available_monitors;
use platform::platform::raw_input::register_all_mice_and_keyboards_for_raw_input;
use platform::platform::util;
use platform::platform::window_state::{CursorFlags, SavedWindow, WindowFlags, WindowState};
/// The Win32 implementation of the main `Window` object.
pub struct Window {
/// Main handle for the window.
window: WindowWrapper,
/// The current window state.
window_state: Arc<Mutex<WindowState>>,
// The events loop proxy.
events_loop_proxy: events_loop::EventsLoopProxy,
}
impl Window {
pub fn new(
events_loop: &EventsLoop,
w_attr: WindowAttributes,
pl_attr: PlatformSpecificWindowBuilderAttributes,
) -> Result<Window, CreationError> {
let (tx, rx) = channel();
let proxy = events_loop.create_proxy();
events_loop.execute_in_thread(move |inserter| {
// We dispatch an `init` function because of code style.
// First person to remove the need for cloning here gets a cookie!
let win = unsafe { init(w_attr.clone(), pl_attr.clone(), inserter, proxy.clone()) };
let _ = tx.send(win);
});
rx.recv().unwrap()
}
pub fn set_title(&self, text: &str) {
let text = OsStr::new(text)
.encode_wide()
.chain(Some(0).into_iter())
.collect::<Vec<_>>();
unsafe {
winuser::SetWindowTextW(self.window.0, text.as_ptr() as LPCWSTR);
}
}
#[inline]
pub fn show(&self) {
unsafe {
winuser::ShowWindow(self.window.0, winuser::SW_SHOW);
}
}
#[inline]
pub fn hide(&self) {
unsafe {
winuser::ShowWindow(self.window.0, winuser::SW_HIDE);
}
}
pub(crate) fn get_position_physical(&self) -> Option<(i32, i32)> {
util::get_window_rect(self.window.0)
.map(|rect| (rect.left as i32, rect.top as i32))
}
#[inline]
pub fn get_position(&self) -> Option<LogicalPosition> {
self.get_position_physical()
.map(|physical_position| {
let dpi_factor = self.get_hidpi_factor();
LogicalPosition::from_physical(physical_position, dpi_factor)
})
}
pub(crate) fn get_inner_position_physical(&self) -> Option<(i32, i32)> {
let mut position: POINT = unsafe { mem::zeroed() };
if unsafe { winuser::ClientToScreen(self.window.0, &mut position) } == 0 {
return None;
}
Some((position.x, position.y))
}
#[inline]
pub fn get_inner_position(&self) -> Option<LogicalPosition> {
self.get_inner_position_physical()
.map(|physical_position| {
let dpi_factor = self.get_hidpi_factor();
LogicalPosition::from_physical(physical_position, dpi_factor)
})
}
pub(crate) fn set_position_physical(&self, x: i32, y: i32) {
unsafe {
winuser::SetWindowPos(
self.window.0,
ptr::null_mut(),
x as c_int,
y as c_int,
0,
0,
winuser::SWP_ASYNCWINDOWPOS | winuser::SWP_NOZORDER | winuser::SWP_NOSIZE,
);
winuser::UpdateWindow(self.window.0);
}
}
#[inline]
pub fn set_position(&self, logical_position: LogicalPosition) {
let dpi_factor = self.get_hidpi_factor();
let (x, y) = logical_position.to_physical(dpi_factor).into();
self.set_position_physical(x, y);
}
pub(crate) fn get_inner_size_physical(&self) -> Option<(u32, u32)> {
let mut rect: RECT = unsafe { mem::uninitialized() };
if unsafe { winuser::GetClientRect(self.window.0, &mut rect) } == 0 {
return None;
}
Some((
(rect.right - rect.left) as u32,
(rect.bottom - rect.top) as u32,
))
}
#[inline]
pub fn get_inner_size(&self) -> Option<LogicalSize> {
self.get_inner_size_physical()
.map(|physical_size| {
let dpi_factor = self.get_hidpi_factor();
LogicalSize::from_physical(physical_size, dpi_factor)
})
}
pub(crate) fn get_outer_size_physical(&self) -> Option<(u32, u32)> {
util::get_window_rect(self.window.0)
.map(|rect| (
(rect.right - rect.left) as u32,
(rect.bottom - rect.top) as u32,
))
}
#[inline]
pub fn get_outer_size(&self) -> Option<LogicalSize> {
self.get_outer_size_physical()
.map(|physical_size| {
let dpi_factor = self.get_hidpi_factor();
LogicalSize::from_physical(physical_size, dpi_factor)
})
}
pub(crate) fn set_inner_size_physical(&self, x: u32, y: u32) {
unsafe {
let rect = util::adjust_window_rect(
self.window.0,
RECT {
top: 0,
left: 0,
bottom: y as LONG,
right: x as LONG,
}
).expect("adjust_window_rect failed");
let outer_x = (rect.right - rect.left).abs() as c_int;
let outer_y = (rect.top - rect.bottom).abs() as c_int;
winuser::SetWindowPos(
self.window.0,
ptr::null_mut(),
0,
0,
outer_x,
outer_y,
winuser::SWP_ASYNCWINDOWPOS
| winuser::SWP_NOZORDER
| winuser::SWP_NOREPOSITION
| winuser::SWP_NOMOVE,
);
winuser::UpdateWindow(self.window.0);
}
}
#[inline]
pub fn set_inner_size(&self, logical_size: LogicalSize) {
let dpi_factor = self.get_hidpi_factor();
let (width, height) = logical_size.to_physical(dpi_factor).into();
self.set_inner_size_physical(width, height);
}
pub(crate) fn set_min_dimensions_physical(&self, dimensions: Option<(u32, u32)>) {
self.window_state.lock().unwrap().min_size = dimensions.map(Into::into);
// Make windows re-check the window size bounds.
self.get_inner_size_physical()
.map(|(width, height)| self.set_inner_size_physical(width, height));
}
#[inline]
pub fn set_min_dimensions(&self, logical_size: Option<LogicalSize>) {
let physical_size = logical_size.map(|logical_size| {
let dpi_factor = self.get_hidpi_factor();
logical_size.to_physical(dpi_factor).into()
});
self.set_min_dimensions_physical(physical_size);
}
pub fn set_max_dimensions_physical(&self, dimensions: Option<(u32, u32)>) {
self.window_state.lock().unwrap().max_size = dimensions.map(Into::into);
// Make windows re-check the window size bounds.
self.get_inner_size_physical()
.map(|(width, height)| self.set_inner_size_physical(width, height));
}
#[inline]
pub fn set_max_dimensions(&self, logical_size: Option<LogicalSize>) {
let physical_size = logical_size.map(|logical_size| {
let dpi_factor = self.get_hidpi_factor();
logical_size.to_physical(dpi_factor).into()
});
self.set_max_dimensions_physical(physical_size);
}
#[inline]
pub fn set_resizable(&self, resizable: bool) {
let window = self.window.clone();
let window_state = Arc::clone(&self.window_state);
self.events_loop_proxy.execute_in_thread(move |_| {
WindowState::set_window_flags(
window_state.lock().unwrap(),
window.0,
None,
|f| f.set(WindowFlags::RESIZABLE, resizable),
);
});
}
/// Returns the `hwnd` of this window.
#[inline]
pub fn hwnd(&self) -> HWND {
self.window.0
}
#[inline]
pub fn set_cursor(&self, cursor: MouseCursor) {
self.window_state.lock().unwrap().mouse.cursor = cursor;
self.events_loop_proxy.execute_in_thread(move |_| unsafe {
let cursor = winuser::LoadCursorW(
ptr::null_mut(),
cursor.to_windows_cursor(),
);
winuser::SetCursor(cursor);
});
}
#[inline]
pub fn grab_cursor(&self, grab: bool) -> Result<(), String> {
let window = self.window.clone();
let window_state = Arc::clone(&self.window_state);
let (tx, rx) = channel();
self.events_loop_proxy.execute_in_thread(move |_| {
let result = window_state.lock().unwrap().mouse
.set_cursor_flags(window.0, |f| f.set(CursorFlags::GRABBED, grab))
.map_err(|e| e.to_string());
let _ = tx.send(result);
});
rx.recv().unwrap()
}
#[inline]
pub fn hide_cursor(&self, hide: bool) {
let window = self.window.clone();
let window_state = Arc::clone(&self.window_state);
let (tx, rx) = channel();
self.events_loop_proxy.execute_in_thread(move |_| {
let result = window_state.lock().unwrap().mouse
.set_cursor_flags(window.0, |f| f.set(CursorFlags::HIDDEN, hide))
.map_err(|e| e.to_string());
let _ = tx.send(result);
});
rx.recv().unwrap().ok();
}
#[inline]
pub fn get_hidpi_factor(&self) -> f64 {
self.window_state.lock().unwrap().dpi_factor
}
fn set_cursor_position_physical(&self, x: i32, y: i32) -> Result<(), String> {
let mut point = POINT { x, y };
unsafe {
if winuser::ClientToScreen(self.window.0, &mut point) == 0 {
return Err("`ClientToScreen` failed".to_owned());
}
if winuser::SetCursorPos(point.x, point.y) == 0 {
return Err("`SetCursorPos` failed".to_owned());
}
}
Ok(())
}
#[inline]
pub fn set_cursor_position(&self, logical_position: LogicalPosition) -> Result<(), String> {
let dpi_factor = self.get_hidpi_factor();
let (x, y) = logical_position.to_physical(dpi_factor).into();
self.set_cursor_position_physical(x, y)
}
#[inline]
pub fn id(&self) -> WindowId {
WindowId(self.window.0)
}
#[inline]
pub fn set_maximized(&self, maximized: bool) {
let window = self.window.clone();
let window_state = Arc::clone(&self.window_state);
self.events_loop_proxy.execute_in_thread(move |_| {
WindowState::set_window_flags(
window_state.lock().unwrap(),
window.0,
None,
|f| f.set(WindowFlags::MAXIMIZED, maximized),
);
});
}
#[inline]
pub fn set_fullscreen(&self, monitor: Option<RootMonitorId>) {
unsafe {
let window = self.window.clone();
let window_state = Arc::clone(&self.window_state);
match &monitor {
&Some(RootMonitorId { ref inner }) => {
let (x, y): (i32, i32) = inner.get_position().into();
let (width, height): (u32, u32) = inner.get_dimensions().into();
let mut monitor = monitor.clone();
self.events_loop_proxy.execute_in_thread(move |_| {
let mut window_state_lock = window_state.lock().unwrap();
let client_rect = util::get_client_rect(window.0).expect("get client rect failed!");
window_state_lock.saved_window = Some(SavedWindow {
client_rect,
dpi_factor: window_state_lock.dpi_factor
});
window_state_lock.fullscreen = monitor.take();
WindowState::refresh_window_state(
window_state_lock,
window.0,
Some(RECT {
left: x,
top: y,
right: x + width as c_int,
bottom: y + height as c_int,
})
);
mark_fullscreen(window.0, true);
});
}
&None => {
self.events_loop_proxy.execute_in_thread(move |_| {
let mut window_state_lock = window_state.lock().unwrap();
window_state_lock.fullscreen = None;
if let Some(SavedWindow{client_rect, dpi_factor}) = window_state_lock.saved_window {
window_state_lock.dpi_factor = dpi_factor;
window_state_lock.saved_window = None;
WindowState::refresh_window_state(
window_state_lock,
window.0,
Some(client_rect)
);
}
mark_fullscreen(window.0, false);
});
}
}
}
}
#[inline]
pub fn set_decorations(&self, decorations: bool) {
let window = self.window.clone();
let window_state = Arc::clone(&self.window_state);
self.events_loop_proxy.execute_in_thread(move |_| {
let client_rect = util::get_client_rect(window.0).expect("get client rect failed!");
WindowState::set_window_flags(
window_state.lock().unwrap(),
window.0,
Some(client_rect),
|f| f.set(WindowFlags::DECORATIONS, decorations),
);
});
}
#[inline]
pub fn set_always_on_top(&self, always_on_top: bool) {
let window = self.window.clone();
let window_state = Arc::clone(&self.window_state);
self.events_loop_proxy.execute_in_thread(move |_| {
WindowState::set_window_flags(
window_state.lock().unwrap(),
window.0,
None,
|f| f.set(WindowFlags::ALWAYS_ON_TOP, always_on_top),
);
});
}
#[inline]
pub fn get_current_monitor(&self) -> RootMonitorId {
RootMonitorId {
inner: EventsLoop::get_current_monitor(self.window.0),
}
}
#[inline]
pub fn set_window_icon(&self, mut window_icon: Option<Icon>) {
let window_icon = window_icon
.take()
.map(|icon| WinIcon::from_icon(icon).expect("Failed to create `ICON_SMALL`"));
if let Some(ref window_icon) = window_icon {
window_icon.set_for_window(self.window.0, IconType::Small);
} else {
icon::unset_for_window(self.window.0, IconType::Small);
}
self.window_state.lock().unwrap().window_icon = window_icon;
}
#[inline]
pub fn set_taskbar_icon(&self, mut taskbar_icon: Option<Icon>) {
let taskbar_icon = taskbar_icon
.take()
.map(|icon| WinIcon::from_icon(icon).expect("Failed to create `ICON_BIG`"));
if let Some(ref taskbar_icon) = taskbar_icon {
taskbar_icon.set_for_window(self.window.0, IconType::Big);
} else {
icon::unset_for_window(self.window.0, IconType::Big);
}
self.window_state.lock().unwrap().taskbar_icon = taskbar_icon;
}
#[inline]
pub fn set_ime_spot(&self, _logical_spot: LogicalPosition) {
unimplemented!();
}
}
impl Drop for Window {
#[inline]
fn drop(&mut self) {
unsafe {
// The window must be destroyed from the same thread that created it, so we send a
// custom message to be handled by our callback to do the actual work.
winuser::PostMessageW(self.window.0, *DESTROY_MSG_ID, 0, 0);
}
}
}
/// A simple non-owning wrapper around a window.
#[doc(hidden)]
#[derive(Clone)]
pub struct WindowWrapper(HWND);
// Send and Sync are not implemented for HWND and HDC, we have to wrap it and implement them manually.
// For more info see:
// https://github.com/retep998/winapi-rs/issues/360
// https://github.com/retep998/winapi-rs/issues/396
unsafe impl Sync for WindowWrapper {}
unsafe impl Send for WindowWrapper {}
pub unsafe fn adjust_size(
physical_size: PhysicalSize,
style: DWORD,
ex_style: DWORD,
) -> (LONG, LONG) {
let (width, height): (u32, u32) = physical_size.into();
let mut rect = RECT {
left: 0,
right: width as LONG,
top: 0,
bottom: height as LONG,
};
winuser::AdjustWindowRectEx(&mut rect, style, 0, ex_style);
(rect.right - rect.left, rect.bottom - rect.top)
}
unsafe fn init(
mut attributes: WindowAttributes,
mut pl_attribs: PlatformSpecificWindowBuilderAttributes,
inserter: events_loop::Inserter,
events_loop_proxy: events_loop::EventsLoopProxy,
) -> Result<Window, CreationError> {
let title = OsStr::new(&attributes.title)
.encode_wide()
.chain(Some(0).into_iter())
.collect::<Vec<_>>();
let window_icon = {
let icon = attributes.window_icon
.take()
.map(WinIcon::from_icon);
if icon.is_some() {
Some(icon.unwrap().map_err(|err| {
CreationError::OsError(format!("Failed to create `ICON_SMALL`: {:?}", err))
})?)
} else {
None
}
};
let taskbar_icon = {
let icon = pl_attribs.taskbar_icon
.take()
.map(WinIcon::from_icon);
if icon.is_some() {
Some(icon.unwrap().map_err(|err| {
CreationError::OsError(format!("Failed to create `ICON_BIG`: {:?}", err))
})?)
} else {
None
}
};
// registering the window class
let class_name = register_window_class(&window_icon, &taskbar_icon);
let guessed_dpi_factor = {
let monitors = get_available_monitors();
let dpi_factor = if !monitors.is_empty() {
let mut dpi_factor = Some(monitors[0].get_hidpi_factor());
for monitor in &monitors {
if Some(monitor.get_hidpi_factor()) != dpi_factor {
dpi_factor = None;
}
}
dpi_factor
} else {
return Err(CreationError::OsError(format!("No monitors were detected.")));
};
dpi_factor.unwrap_or_else(|| {
util::get_cursor_pos()
.and_then(|cursor_pos| {
let mut dpi_factor = None;
for monitor in &monitors {
if monitor.contains_point(&cursor_pos) {
dpi_factor = Some(monitor.get_hidpi_factor());
break;
}
}
dpi_factor
})
.unwrap_or(1.0)
})
};
info!("Guessed window DPI factor: {}", guessed_dpi_factor);
let dimensions = attributes.dimensions.unwrap_or_else(|| (1024, 768).into());
let mut window_flags = WindowFlags::empty();
window_flags.set(WindowFlags::DECORATIONS, attributes.decorations);
window_flags.set(WindowFlags::ALWAYS_ON_TOP, attributes.always_on_top);
window_flags.set(WindowFlags::NO_BACK_BUFFER, pl_attribs.no_redirection_bitmap);
window_flags.set(WindowFlags::TRANSPARENT, attributes.transparent);
// WindowFlags::VISIBLE and MAXIMIZED are set down below after the window has been configured.
window_flags.set(WindowFlags::RESIZABLE, attributes.resizable);
window_flags.set(WindowFlags::CHILD, pl_attribs.parent.is_some());
window_flags.set(WindowFlags::ON_TASKBAR, true);
// creating the real window this time, by using the functions in `extra_functions`
let real_window = {
let (style, ex_style) = window_flags.to_window_styles();
let handle = winuser::CreateWindowExW(
ex_style,
class_name.as_ptr(),
title.as_ptr() as LPCWSTR,
style,
winuser::CW_USEDEFAULT, winuser::CW_USEDEFAULT,
winuser::CW_USEDEFAULT, winuser::CW_USEDEFAULT,
pl_attribs.parent.unwrap_or(ptr::null_mut()),
ptr::null_mut(),
libloaderapi::GetModuleHandleW(ptr::null()),
ptr::null_mut(),
);
if handle.is_null() {
return Err(CreationError::OsError(format!("CreateWindowEx function failed: {}",
format!("{}", io::Error::last_os_error()))));
}
WindowWrapper(handle)
};
// Set up raw input
register_all_mice_and_keyboards_for_raw_input(real_window.0);
// Register for touch events if applicable
{
let digitizer = winuser::GetSystemMetrics( winuser::SM_DIGITIZER ) as u32;
if digitizer & winuser::NID_READY != 0 {
winuser::RegisterTouchWindow( real_window.0, winuser::TWF_WANTPALM );
}
}
let dpi = get_hwnd_dpi(real_window.0);
let dpi_factor = dpi_to_scale_factor(dpi);
if dpi_factor != guessed_dpi_factor {
let (width, height): (u32, u32) = dimensions.into();
let mut packed_dimensions = 0;
// MAKELPARAM isn't provided by winapi yet.
let ptr = &mut packed_dimensions as *mut LPARAM as *mut WORD;
*ptr.offset(0) = width as WORD;
*ptr.offset(1) = height as WORD;
winuser::PostMessageW(
real_window.0,
*INITIAL_DPI_MSG_ID,
dpi as WPARAM,
packed_dimensions,
);
}
// making the window transparent
if attributes.transparent && !pl_attribs.no_redirection_bitmap {
let region = CreateRectRgn(0, 0, -1, -1); // makes the window transparent
let bb = dwmapi::DWM_BLURBEHIND {
dwFlags: dwmapi::DWM_BB_ENABLE | dwmapi::DWM_BB_BLURREGION,
fEnable: 1,
hRgnBlur: region,
fTransitionOnMaximized: 0,
};
dwmapi::DwmEnableBlurBehindWindow(real_window.0, &bb);
DeleteObject(region as _);
if attributes.decorations {
// HACK: When opaque (opacity 255), there is a trail whenever
// the transparent window is moved. By reducing it to 254,
// the window is rendered properly.
let opacity = 254;
// The color key can be any value except for black (0x0).
let color_key = 0x0030c100;
winuser::SetLayeredWindowAttributes(real_window.0, color_key, opacity, winuser::LWA_ALPHA);
}
}
window_flags.set(WindowFlags::VISIBLE, attributes.visible);
window_flags.set(WindowFlags::MAXIMIZED, attributes.maximized);
let window_state = {
let mut window_state = WindowState::new(
&attributes,
window_icon,
taskbar_icon,
dpi_factor,
);
let window_state = Arc::new(Mutex::new(window_state));
WindowState::set_window_flags(
window_state.lock().unwrap(),
real_window.0,
None,
|f| *f = window_flags,
);
window_state
};
let win = Window {
window: real_window,
window_state,
events_loop_proxy,
};
if let Some(_) = attributes.fullscreen {
win.set_fullscreen(attributes.fullscreen);
force_window_active(win.window.0);
}
if let Some(dimensions) = attributes.dimensions {
win.set_inner_size(dimensions);
}
inserter.insert(win.window.0, win.window_state.clone());
Ok(win)
}
unsafe fn register_window_class(
window_icon: &Option<WinIcon>,
taskbar_icon: &Option<WinIcon>,
) -> Vec<u16> {
let class_name: Vec<_> = OsStr::new("Window Class")
.encode_wide()
.chain(Some(0).into_iter())
.collect();
let h_icon = taskbar_icon
.as_ref()
.map(|icon| icon.handle)
.unwrap_or(ptr::null_mut());
let h_icon_small = window_icon
.as_ref()
.map(|icon| icon.handle)
.unwrap_or(ptr::null_mut());
let class = winuser::WNDCLASSEXW {
cbSize: mem::size_of::<winuser::WNDCLASSEXW>() as UINT,
style: winuser::CS_HREDRAW | winuser::CS_VREDRAW | winuser::CS_OWNDC,
lpfnWndProc: Some(events_loop::callback),
cbClsExtra: 0,
cbWndExtra: 0,
hInstance: libloaderapi::GetModuleHandleW(ptr::null()),
hIcon: h_icon,
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: h_icon_small,
};
// 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.
winuser::RegisterClassExW(&class);
class_name
}
struct ComInitialized(*mut ());
impl Drop for ComInitialized {
fn drop(&mut self) {
unsafe { combaseapi::CoUninitialize() };
}
}
thread_local!{
static COM_INITIALIZED: ComInitialized = {
unsafe {
combaseapi::CoInitializeEx(ptr::null_mut(), COINIT_MULTITHREADED);
ComInitialized(ptr::null_mut())
}
};
static TASKBAR_LIST: Cell<*mut ITaskbarList2> = Cell::new(ptr::null_mut());
}
pub fn com_initialized() {
COM_INITIALIZED.with(|_| {});
}
// Reference Implementation:
// https://github.com/chromium/chromium/blob/f18e79d901f56154f80eea1e2218544285e62623/ui/views/win/fullscreen_handler.cc
//
// As per MSDN marking the window as fullscreen should ensure that the
// taskbar is moved to the bottom of the Z-order when the fullscreen window
// is activated. If the window is not fullscreen, the Shell falls back to
// heuristics to determine how the window should be treated, which means
// that it could still consider the window as fullscreen. :(
unsafe fn mark_fullscreen(handle: HWND, fullscreen: bool) {
com_initialized();
TASKBAR_LIST.with(|task_bar_list_ptr| {
let mut task_bar_list = task_bar_list_ptr.get();
if task_bar_list == ptr::null_mut() {
use winapi::shared::winerror::S_OK;
use winapi::Interface;
let hr = combaseapi::CoCreateInstance(
&CLSID_TaskbarList,
ptr::null_mut(),
combaseapi::CLSCTX_ALL,
&ITaskbarList2::uuidof(),
&mut task_bar_list as *mut _ as *mut _,
);
if hr != S_OK || (*task_bar_list).HrInit() != S_OK {
// In some old windows, the taskbar object could not be created, we just ignore it
return;
}
task_bar_list_ptr.set(task_bar_list)
}
task_bar_list = task_bar_list_ptr.get();
(*task_bar_list).MarkFullscreenWindow(handle, if fullscreen { 1 } else { 0 });
})
}
unsafe fn force_window_active(handle: HWND) {
// In some situation, calling SetForegroundWindow could not bring up the window,
// This is a little hack which can "steal" the foreground window permission
// We only call this function in the window creation, so it should be fine.
// See : https://stackoverflow.com/questions/10740346/setforegroundwindow-only-working-while-visual-studio-is-open
let alt_sc = winuser::MapVirtualKeyW(winuser::VK_MENU as _, winuser::MAPVK_VK_TO_VSC);
let mut inputs: [winuser::INPUT; 2] = mem::zeroed();
inputs[0].type_ = winuser::INPUT_KEYBOARD;
inputs[0].u.ki_mut().wVk = winuser::VK_LMENU as _;
inputs[0].u.ki_mut().wScan = alt_sc as _;
inputs[0].u.ki_mut().dwFlags = winuser::KEYEVENTF_EXTENDEDKEY;
inputs[1].type_ = winuser::INPUT_KEYBOARD;
inputs[1].u.ki_mut().wVk = winuser::VK_LMENU as _;
inputs[1].u.ki_mut().wScan = alt_sc as _;
inputs[1].u.ki_mut().dwFlags = winuser::KEYEVENTF_EXTENDEDKEY | winuser::KEYEVENTF_KEYUP;
// Simulate a key press and release
winuser::SendInput(
inputs.len() as _,
inputs.as_mut_ptr(),
mem::size_of::<winuser::INPUT>() as _,
);
winuser::SetForegroundWindow(handle);
}

329
src/platform/windows/window_state.rs
View File

@@ -1,329 +0,0 @@
use {MouseCursor, WindowAttributes};
use std::{io, ptr};
use std::sync::MutexGuard;
use dpi::LogicalSize;
use platform::platform::{util, events_loop};
use platform::platform::icon::WinIcon;
use winapi::shared::windef::{RECT, HWND};
use winapi::shared::minwindef::DWORD;
use winapi::um::winuser;
/// Contains information about states and the window that the callback is going to use.
#[derive(Clone)]
pub struct WindowState {
pub mouse: MouseProperties,
/// Used by `WM_GETMINMAXINFO`.
pub min_size: Option<LogicalSize>,
pub max_size: Option<LogicalSize>,
pub window_icon: Option<WinIcon>,
pub taskbar_icon: Option<WinIcon>,
pub saved_window: Option<SavedWindow>,
pub dpi_factor: f64,
pub fullscreen: Option<::MonitorId>,
window_flags: WindowFlags,
}
#[derive(Clone)]
pub struct SavedWindow {
pub client_rect: RECT,
pub dpi_factor: f64,
}
#[derive(Clone)]
pub struct MouseProperties {
pub cursor: MouseCursor,
cursor_flags: CursorFlags,
}
bitflags! {
pub struct CursorFlags: u8 {
const GRABBED = 1 << 0;
const HIDDEN = 1 << 1;
const IN_WINDOW = 1 << 2;
}
}
bitflags! {
pub struct WindowFlags: u32 {
const RESIZABLE = 1 << 0;
const DECORATIONS = 1 << 1;
const VISIBLE = 1 << 2;
const ON_TASKBAR = 1 << 3;
const ALWAYS_ON_TOP = 1 << 4;
const NO_BACK_BUFFER = 1 << 5;
const TRANSPARENT = 1 << 6;
const CHILD = 1 << 7;
const MAXIMIZED = 1 << 8;
/// Marker flag for fullscreen. Should always match `WindowState::fullscreen`, but is
/// included here to make masking easier.
const MARKER_FULLSCREEN = 1 << 9;
/// The `WM_SIZE` event contains some parameters that can effect the state of `WindowFlags`.
/// In most cases, it's okay to let those parameters change the state. However, when we're
/// running the `WindowFlags::apply_diff` function, we *don't* want those parameters to
/// effect our stored state, because the purpose of `apply_diff` is to update the actual
/// window's state to match our stored state. This controls whether to accept those changes.
const MARKER_RETAIN_STATE_ON_SIZE = 1 << 10;
const FULLSCREEN_AND_MASK = !(
WindowFlags::DECORATIONS.bits |
WindowFlags::RESIZABLE.bits |
WindowFlags::MAXIMIZED.bits
);
const NO_DECORATIONS_AND_MASK = !WindowFlags::RESIZABLE.bits;
const INVISIBLE_AND_MASK = !WindowFlags::MAXIMIZED.bits;
}
}
impl WindowState {
pub fn new(
attributes: &WindowAttributes,
window_icon: Option<WinIcon>,
taskbar_icon: Option<WinIcon>,
dpi_factor: f64
) -> WindowState {
WindowState {
mouse: MouseProperties {
cursor: MouseCursor::default(),
cursor_flags: CursorFlags::empty(),
},
min_size: attributes.min_dimensions,
max_size: attributes.max_dimensions,
window_icon,
taskbar_icon,
saved_window: None,
dpi_factor,
fullscreen: None,
window_flags: WindowFlags::empty()
}
}
pub fn window_flags(&self) -> WindowFlags {
self.window_flags
}
pub fn set_window_flags<F>(mut this: MutexGuard<Self>, window: HWND, set_client_rect: Option<RECT>, f: F)
where F: FnOnce(&mut WindowFlags)
{
let old_flags = this.window_flags;
f(&mut this.window_flags);
let is_fullscreen = this.fullscreen.is_some();
this.window_flags.set(WindowFlags::MARKER_FULLSCREEN, is_fullscreen);
let new_flags = this.window_flags;
drop(this);
old_flags.apply_diff(window, new_flags, set_client_rect);
}
pub fn refresh_window_state(this: MutexGuard<Self>, window: HWND, set_client_rect: Option<RECT>) {
Self::set_window_flags(this, window, set_client_rect, |_| ());
}
pub fn set_window_flags_in_place<F>(&mut self, f: F)
where F: FnOnce(&mut WindowFlags)
{
f(&mut self.window_flags);
}
}
impl MouseProperties {
pub fn cursor_flags(&self) -> CursorFlags {
self.cursor_flags
}
pub fn set_cursor_flags<F>(&mut self, window: HWND, f: F) -> Result<(), io::Error>
where F: FnOnce(&mut CursorFlags)
{
let old_flags = self.cursor_flags;
f(&mut self.cursor_flags);
match self.cursor_flags.refresh_os_cursor(window) {
Ok(()) => (),
Err(e) => {
self.cursor_flags = old_flags;
return Err(e);
}
}
Ok(())
}
}
impl WindowFlags {
fn mask(mut self) -> WindowFlags {
if self.contains(WindowFlags::MARKER_FULLSCREEN) {
self &= WindowFlags::FULLSCREEN_AND_MASK;
}
if !self.contains(WindowFlags::VISIBLE) {
self &= WindowFlags::INVISIBLE_AND_MASK;
}
if !self.contains(WindowFlags::DECORATIONS) {
self &= WindowFlags::NO_DECORATIONS_AND_MASK;
}
self
}
pub fn to_window_styles(self) -> (DWORD, DWORD) {
use winapi::um::winuser::*;
let (mut style, mut style_ex) = (0, 0);
if self.contains(WindowFlags::RESIZABLE) {
style |= WS_SIZEBOX | WS_MAXIMIZEBOX;
}
if self.contains(WindowFlags::DECORATIONS) {
style |= WS_CAPTION | WS_MINIMIZEBOX | WS_BORDER;
style_ex = WS_EX_WINDOWEDGE;
}
if self.contains(WindowFlags::VISIBLE) {
style |= WS_VISIBLE;
}
if self.contains(WindowFlags::ON_TASKBAR) {
style_ex |= WS_EX_APPWINDOW;
}
if self.contains(WindowFlags::ALWAYS_ON_TOP) {
style_ex |= WS_EX_TOPMOST;
}
if self.contains(WindowFlags::NO_BACK_BUFFER) {
style_ex |= WS_EX_NOREDIRECTIONBITMAP;
}
if self.contains(WindowFlags::TRANSPARENT) {
// Is this necessary? The docs say that WS_EX_LAYERED requires a windows class without
// CS_OWNDC, and Winit windows have that flag set.
style_ex |= WS_EX_LAYERED;
}
if self.contains(WindowFlags::CHILD) {
style |= WS_CHILD; // This is incompatible with WS_POPUP if that gets added eventually.
}
if self.contains(WindowFlags::MAXIMIZED) {
style |= WS_MAXIMIZE;
}
style |= WS_CLIPSIBLINGS | WS_CLIPCHILDREN | WS_SYSMENU;
style_ex |= WS_EX_ACCEPTFILES;
(style, style_ex)
}
/// Adjust the window client rectangle to the return value, if present.
fn apply_diff(mut self, window: HWND, mut new: WindowFlags, set_client_rect: Option<RECT>) {
self = self.mask();
new = new.mask();
let diff = self ^ new;
if diff == WindowFlags::empty() {
return;
}
if diff.contains(WindowFlags::VISIBLE) {
unsafe {
winuser::ShowWindow(
window,
match new.contains(WindowFlags::VISIBLE) {
true => winuser::SW_SHOW,
false => winuser::SW_HIDE
}
);
}
}
if diff.contains(WindowFlags::ALWAYS_ON_TOP) {
unsafe {
winuser::SetWindowPos(
window,
match new.contains(WindowFlags::ALWAYS_ON_TOP) {
true => winuser::HWND_TOPMOST,
false => winuser::HWND_NOTOPMOST,
},
0, 0, 0, 0,
winuser::SWP_ASYNCWINDOWPOS | winuser::SWP_NOMOVE | winuser::SWP_NOSIZE,
);
winuser::UpdateWindow(window);
}
}
if diff.contains(WindowFlags::MAXIMIZED) || new.contains(WindowFlags::MAXIMIZED) {
unsafe {
winuser::ShowWindow(
window,
match new.contains(WindowFlags::MAXIMIZED) {
true => winuser::SW_MAXIMIZE,
false => winuser::SW_RESTORE
}
);
}
}
if diff != WindowFlags::empty() {
let (style, style_ex) = new.to_window_styles();
unsafe {
winuser::SendMessageW(window, *events_loop::SET_RETAIN_STATE_ON_SIZE_MSG_ID, 1, 0);
winuser::SetWindowLongW(window, winuser::GWL_STYLE, style as _);
winuser::SetWindowLongW(window, winuser::GWL_EXSTYLE, style_ex as _);
match set_client_rect.and_then(|r| util::adjust_window_rect_with_styles(window, style, style_ex, r)) {
Some(client_rect) => {
let (x, y, w, h) = (
client_rect.left,
client_rect.top,
client_rect.right - client_rect.left,
client_rect.bottom - client_rect.top,
);
winuser::SetWindowPos(
window,
ptr::null_mut(),
x, y, w, h,
winuser::SWP_NOZORDER
| winuser::SWP_FRAMECHANGED,
);
},
None => {
// Refresh the window frame.
winuser::SetWindowPos(
window,
ptr::null_mut(),
0, 0, 0, 0,
winuser::SWP_NOZORDER
| winuser::SWP_NOMOVE
| winuser::SWP_NOSIZE
| winuser::SWP_FRAMECHANGED,
);
}
}
winuser::SendMessageW(window, *events_loop::SET_RETAIN_STATE_ON_SIZE_MSG_ID, 0, 0);
}
}
}
}
impl CursorFlags {
fn refresh_os_cursor(self, window: HWND) -> Result<(), io::Error> {
let client_rect = util::get_client_rect(window)?;
if util::is_focused(window) {
if self.contains(CursorFlags::GRABBED) {
util::set_cursor_clip(Some(client_rect))?;
} else {
util::set_cursor_clip(None)?;
}
}
let cursor_in_client = self.contains(CursorFlags::IN_WINDOW);
if cursor_in_client {
util::set_cursor_hidden(self.contains(CursorFlags::HIDDEN));
} else {
util::set_cursor_hidden(false);
}
Ok(())
}
}

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:** This respects Xft.dpi XResource, and 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
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@@ -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
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@@ -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>();
}

39
tests/serde_objects.rs
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@@ -1,39 +0,0 @@
#![cfg(feature = "serde")]
extern crate serde;
extern crate winit;
use winit::{ControlFlow, MouseCursor};
use winit::{
KeyboardInput, TouchPhase, ElementState, MouseButton, MouseScrollDelta, VirtualKeyCode,
ModifiersState
};
use winit::dpi::{LogicalPosition, PhysicalPosition, LogicalSize, PhysicalSize};
use serde::{Serialize, Deserialize};
fn needs_serde<S: Serialize + Deserialize<'static>>() {}
#[test]
fn root_serde() {
needs_serde::<ControlFlow>();
needs_serde::<MouseCursor>();
}
#[test]
fn events_serde() {
needs_serde::<KeyboardInput>();
needs_serde::<TouchPhase>();
needs_serde::<ElementState>();
needs_serde::<MouseButton>();
needs_serde::<MouseScrollDelta>();
needs_serde::<VirtualKeyCode>();
needs_serde::<ModifiersState>();
}
#[test]
fn dpi_serde() {
needs_serde::<LogicalPosition>();
needs_serde::<PhysicalPosition>();
needs_serde::<LogicalSize>();
needs_serde::<PhysicalSize>();
}

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