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//! Unstable protocols from wayland-protocols
//!
//! The protocols described in this module are experimental and
//! provide no guarantee of forward support. They may be abandoned
//! or never widely implemented.
//!
//! Backward compatible changes may be added together with the
//! corresponding interface version bump.
//!
//! Backward incompatible changes are done by bumping the version
//! number in the protocol and interface names and resetting the
//! interface version. Once the protocol is to be declared stable,
//! the 'z' prefix and the version number in the protocol and
//! interface names are removed and the interface version number is
//! reset.
#![cfg_attr(rustfmt, rustfmt_skip)]
pub mod fullscreen_shell {
//! Fullscreen shell protocol
wayland_protocol_versioned!(
"fullscreen-shell",
[v1],
[(wl_surface, wl_surface_interface), (wl_output, wl_output_interface)],
[]
);
}
pub mod idle_inhibit {
//! Screensaver inhibition protocol
wayland_protocol_versioned!("idle-inhibit", [v1], [(wl_surface, wl_surface_interface)], []);
}
pub mod input_method {
//! Input method protocol
wayland_protocol_versioned!(
"input-method",
[v1],
[
(wl_surface, wl_surface_interface),
(wl_output, wl_output_interface),
(wl_keyboard, wl_keyboard_interface)
],
[]
);
}
pub mod input_timestamps {
//! Input timestamps protocol
wayland_protocol_versioned!(
"input-timestamps",
[v1],
[
(wl_keyboard, wl_keyboard_interface),
(wl_pointer, wl_pointer_interface),
(wl_touch, wl_touch_interface)
],
[]
);
}
pub mod keyboard_shortcuts_inhibit {
//! Protocol for inhibiting the compositor keyboard shortcuts
//!
//! This protocol specifies a way for a client to request the compositor
//! to ignore its own keyboard shortcuts for a given seat, so that all
//! key events from that seat get forwarded to a surface.
wayland_protocol_versioned!(
"keyboard-shortcuts-inhibit",
[v1],
[(wl_seat, wl_seat_interface), (wl_surface, wl_surface_interface)],
[]
);
}
pub mod linux_dmabuf {
//! Linux DMA-BUF protocol
wayland_protocol_versioned!("linux-dmabuf", [v1], [(wl_buffer, wl_buffer_interface)], []);
}
pub mod linux_explicit_synchronization {
//! Linux explicit synchronization protocol
wayland_protocol_versioned!(
"linux-explicit-synchronization",
[v1],
[(wl_surface, wl_surface_interface)],
[]
);
}
pub mod pointer_constraints {
//! protocol for constraining pointer motions
//!
//! This protocol specifies a set of interfaces used for adding constraints to
//! the motion of a pointer. Possible constraints include confining pointer
//! motions to a given region, or locking it to its current position.
//!
//! In order to constrain the pointer, a client must first bind the global
//! interface "wp_pointer_constraints" which, if a compositor supports pointer
//! constraints, is exposed by the registry. Using the bound global object, the
//! client uses the request that corresponds to the type of constraint it wants
//! to make. See wp_pointer_constraints for more details.
wayland_protocol_versioned!(
"pointer-constraints",
[v1],
[
(wl_surface, wl_surface_interface),
(wl_pointer, wl_pointer_interface),
(wl_region, wl_region_interface)
],
[]
);
}
pub mod pointer_gestures {
//! Pointer gestures protocol
wayland_protocol_versioned!(
"pointer-gestures",
[v1],
[(wl_surface, wl_surface_interface), (wl_pointer, wl_pointer_interface)],
[]
);
}
pub mod primary_selection {
//! Primary selection protocol
wayland_protocol_versioned!("primary-selection", [v1], [(wl_seat, wl_seat_interface)], []);
}
pub mod relative_pointer {
//! protocol for relative pointer motion events
//!
//! This protocol specifies a set of interfaces used for making clients able to
//! receive relative pointer events not obstructed by barriers (such as the
//! monitor edge or other pointer barriers).
//!
//! To start receiving relative pointer events, a client must first bind the
//! global interface "wp_relative_pointer_manager" which, if a compositor
//! supports relative pointer motion events, is exposed by the registry. After
//! having created the relative pointer manager proxy object, the client uses
//! it to create the actual relative pointer object using the
//! "get_relative_pointer" request given a wl_pointer. The relative pointer
//! motion events will then, when applicable, be transmitted via the proxy of
//! the newly created relative pointer object. See the documentation of the
//! relative pointer interface for more details.
wayland_protocol_versioned!("relative-pointer", [v1], [(wl_pointer, wl_pointer_interface)], []);
}
pub mod tablet {
//! Wayland protocol for graphics tablets
//!
//! This description provides a high-level overview of the interplay between
//! the interfaces defined this protocol. For details, see the protocol
//! specification.
//!
//! More than one tablet may exist, and device-specifics matter. Tablets are
//! not represented by a single virtual device like wl_pointer. A client
//! binds to the tablet manager object which is just a proxy object. From
//! that, the client requests wp_tablet_manager.get_tablet_seat(wl_seat)
//! and that returns the actual interface that has all the tablets. With
//! this indirection, we can avoid merging wp_tablet into the actual Wayland
//! protocol, a long-term benefit.
//!
//! The wp_tablet_seat sends a "tablet added" event for each tablet
//! connected. That event is followed by descriptive events about the
//! hardware; currently that includes events for name, vid/pid and
//! a wp_tablet.path event that describes a local path. This path can be
//! used to uniquely identify a tablet or get more information through
//! libwacom. Emulated or nested tablets can skip any of those, e.g. a
//! virtual tablet may not have a vid/pid. The sequence of descriptive
//! events is terminated by a wp_tablet.done event to signal that a client
//! may now finalize any initialization for that tablet.
//!
//! Events from tablets require a tool in proximity. Tools are also managed
//! by the tablet seat; a "tool added" event is sent whenever a tool is new
//! to the compositor. That event is followed by a number of descriptive
//! events about the hardware; currently that includes capabilities,
//! hardware id and serial number, and tool type. Similar to the tablet
//! interface, a wp_tablet_tool.done event is sent to terminate that initial
//! sequence.
//!
//! Any event from a tool happens on the wp_tablet_tool interface. When the
//! tool gets into proximity of the tablet, a proximity_in event is sent on
//! the wp_tablet_tool interface, listing the tablet and the surface. That
//! event is followed by a motion event with the coordinates. After that,
//! it's the usual motion, axis, button, etc. events. The protocol's
//! serialisation means events are grouped by wp_tablet_tool.frame events.
//!
//! Two special events (that don't exist in X) are down and up. They signal
//! "tip touching the surface". For tablets without real proximity
//! detection, the sequence is: proximity_in, motion, down, frame.
//!
//! When the tool leaves proximity, a proximity_out event is sent. If any
//! button is still down, a button release event is sent before this
//! proximity event. These button events are sent in the same frame as the
//! proximity event to signal to the client that the buttons were held when
//! the tool left proximity.
//!
//! If the tool moves out of the surface but stays in proximity (i.e.
//! between windows), compositor-specific grab policies apply. This usually
//! means that the proximity-out is delayed until all buttons are released.
//!
//! Moving a tool physically from one tablet to the other has no real effect
//! on the protocol, since we already have the tool object from the "tool
//! added" event. All the information is already there and the proximity
//! events on both tablets are all a client needs to reconstruct what
//! happened.
//!
//! Some extra axes are normalized, i.e. the client knows the range as
//! specified in the protocol (e.g. [0, 65535]), the granularity however is
//! unknown. The current normalized axes are pressure, distance, and slider.
//!
//! Other extra axes are in physical units as specified in the protocol.
//! The current extra axes with physical units are tilt, rotation and
//! wheel rotation.
//!
//! Since tablets work independently of the pointer controlled by the mouse,
//! the focus handling is independent too and controlled by proximity.
//! The wp_tablet_tool.set_cursor request sets a tool-specific cursor.
//! This cursor surface may be the same as the mouse cursor, and it may be
//! the same across tools but it is possible to be more fine-grained. For
//! example, a client may set different cursors for the pen and eraser.
//!
//! Tools are generally independent of tablets and it is
//! compositor-specific policy when a tool can be removed. Common approaches
//! will likely include some form of removing a tool when all tablets the
//! tool was used on are removed.
wayland_protocol_versioned!(
"tablet",
[v1, v2],
[(wl_seat, wl_seat_interface), (wl_surface, wl_surface_interface)],
[]
);
}
pub mod text_input {
//! Text input protocol
wayland_protocol_versioned!(
"text-input",
[v1, v3],
[(wl_seat, wl_seat_interface), (wl_surface, wl_surface_interface)],
[]
);
}
pub mod xdg_decoration {
//! This interface allows a compositor to announce support for server-side
//! decorations.
//! A window decoration is a set of window controls as deemed appropriate by
//! the party managing them, such as user interface components used to move,
//! resize and change a window's state.
//! A client can use this protocol to request being decorated by a supporting
//! compositor.
//! If compositor and client do not negotiate the use of a server-side
//! decoration using this protocol, clients continue to self-decorate as they
//! see fit.
wayland_protocol_versioned!(
"xdg-decoration",
[v1],
[],
[(xdg_shell, xdg_toplevel, xdg_toplevel_interface)]
);
}
pub mod xdg_foreign {
//! Protocol for exporting xdg surface handles
//!
//! This protocol specifies a way for making it possible to reference a surface
//! of a different client. With such a reference, a client can, by using the
//! interfaces provided by this protocol, manipulate the relationship between
//! its own surfaces and the surface of some other client. For example, stack
//! some of its own surface above the other clients surface.
//!
//! In order for a client A to get a reference of a surface of client B, client
//! B must first export its surface using xdg_exporter.export. Upon doing this,
//! client B will receive a handle (a unique string) that it may share with
//! client A in some way (for example D-Bus). After client A has received the
//! handle from client B, it may use xdg_importer.import to create a reference
//! to the surface client B just exported. See the corresponding requests for
//! details.
//!
//! A possible use case for this is out-of-process dialogs. For example when a
//! sandboxed client without file system access needs the user to select a file
//! on the file system, given sandbox environment support, it can export its
//! surface, passing the exported surface handle to an unsandboxed process that
//! can show a file browser dialog and stack it above the sandboxed client's
//! surface.
wayland_protocol_versioned!("xdg-foreign", [v1, v2], [(wl_surface, wl_surface_interface)], []);
}
pub mod xdg_output {
//! Protocol to describe output regions
//!
//! This protocol aims at describing outputs in a way which is more in line
//! with the concept of an output on desktop oriented systems.
//!
//! Some information are more specific to the concept of an output for
//! a desktop oriented system and may not make sense in other applications,
//! such as IVI systems for example.
//!
//! Typically, the global compositor space on a desktop system is made of
//! a contiguous or overlapping set of rectangular regions.
//!
//! Some of the information provided in this protocol might be identical
//! to their counterparts already available from wl_output, in which case
//! the information provided by this protocol should be preferred to their
//! equivalent in wl_output. The goal is to move the desktop specific
//! concepts (such as output location within the global compositor space,
//! the connector name and types, etc.) out of the core wl_output protocol.
wayland_protocol_versioned!("xdg-output", [v1], [(wl_output, wl_output_interface)], []);
}
pub mod xdg_shell {
//! XDG Shell protocol
//!
//! These are the old, unstable versions of the now stable XDG Shell protocol.
//!
//! They remain here for compatibility reasons, allowing you to support older
//! clients/server not yet implementing the new protocol.
wayland_protocol_versioned!(
"xdg-shell",
[v5, v6],
[
(wl_surface, wl_surface_interface),
(wl_output, wl_output_interface),
(wl_seat, wl_seat_interface)
],
[]
);
}
pub mod xwayland_keyboard_grab {
//! Protocol for grabbing the keyboard from Xwayland
//!
//! This protocol is application-specific to meet the needs of the X11
//! protocol through Xwayland. It provides a way for Xwayland to request
//! all keyboard events to be forwarded to a surface even when the
//! surface does not have keyboard focus.
//!
//! In the X11 protocol, a client may request an "active grab" on the
//! keyboard. On success, all key events are reported only to the
//! grabbing X11 client. For details, see XGrabKeyboard(3).
//!
//! The core Wayland protocol does not have a notion of an active
//! keyboard grab. When running in Xwayland, X11 applications may
//! acquire an active grab inside Xwayland but that cannot be translated
//! to the Wayland compositor who may set the input focus to some other
//! surface. In doing so, it breaks the X11 client assumption that all
//! key events are reported to the grabbing client.
//!
//! This protocol specifies a way for Xwayland to request all keyboard
//! be directed to the given surface. The protocol does not guarantee
//! that the compositor will honor this request and it does not
//! prescribe user interfaces on how to handle the respond. For example,
//! a compositor may inform the user that all key events are now
//! forwarded to the given client surface, or it may ask the user for
//! permission to do so.
//!
//! Compositors are required to restrict access to this application
//! specific protocol to Xwayland alone.
wayland_protocol_versioned!(
"xwayland-keyboard-grab",
[v1],
[(wl_seat, wl_seat_interface), (wl_surface, wl_surface_interface)],
[]
);
}