smithay/src/compositor/mod.rs

//! Utilities for handling surfaces, subsurfaces and regions
//!
//! This module provides automatic handling of sufaces, subsurfaces
//! and region wayland objects, by registering an implementation for
//! for the `wl_compositor` and `wl_subcompositor` globals.
//!
//! ## Why use this implementation
//!
//! This implementation does a simple job: it stores in a coherent way the state of
//! surface trees with subsurfaces, to provide you a direct access to the tree
//! structure and all surface metadata.
//!
//! As such, you can, given a root surface with a role requiring it to be displayed,
//! you can iterate over the whole tree of subsurfaces to recover all the metadata you
//! need to display the subsurface tree.
//!
//! This implementation will not do anything more than present you the metadata specified by the
//! client in a coherent and practical way. All the logic regarding to drawing itself, and
//! the positionning of windows (surface trees) one relative to another is out of its scope.
//!
//! ## How to use it
//!
//! ### Initialization
//!
//! To initialize this implementation, use the `compositor_init` method provided
//! by this module. It'll require you to first define as few things, as shown in
//! this example:
//!
//! ```
//! # extern crate wayland_server;
//! # #[macro_use] extern crate smithay;
//! use wayland_server::protocol::wl_compositor::WlCompositor;
//! use wayland_server::protocol::wl_subcompositor::WlSubcompositor;
//! use smithay::compositor::{compositor_init, SurfaceUserImplementation};
//!
//! // Define some user data to be associated with the surfaces.
//! // It must implement the Default trait, which will represent the state of a surface which
//! // has just been created.
//! #[derive(Default)]
//! struct MyData {
//!     // whatever you need here
//! }
//!
//! // Declare the roles enum
//! define_roles!(MyRoles);
//!
//! # fn main() {
//! # let (_display, mut event_loop) = wayland_server::create_display();
//! // define your implementation for surface
//! let my_implementation = SurfaceUserImplementation {
//!     commit: |evlh, idata, surface, token| { /* ... */ },
//!     frame: |evlh, idata, surface, callback, token| { /* ... */ }
//! };
//! // define your implementation data
//! let my_implementation_data = ();
//!
//! // Call the init function:
//! let (token, _, _) = compositor_init::<MyData, MyRoles, _, _>(
//!     &mut event_loop,
//!     my_implementation,       // instance of compositor::SurfaceUserImplementation
//!     my_implementation_data,  // whatever implementation data you need
//!     None                     // put a logger here
//! );
//!
//! // this `token` is what you'll use to access the surface associated data
//!
//! // You're now ready to go!
//! # }
//! ```
//!
//! ### Use the surface metadata
//!
//! As you can see in the previous example, in the end we are retrieving a token from
//! the init function. This token is necessary to retrieve the metadata associated with
//! a surface. It can be cloned, and is sendable accross threads (as long as your
//! `Mydata` and `MyRoles` are `Send` too). See `CompositorToken` for
//! the details of what it enables you.
//!
//! The surface metadata is held in the `SurfaceAttributes` struct. In contains double-buffered
//! state pending from the client as defined by the protocol for wl_surface, as well as your
//! user-defined type holding any data you need to have associated with a struct. See its
//! documentation for details.
//!
//! This `CompositorToken` also provides access to the metadata associated with the role of the
//! surfaces. See the documentation of the `roles` submodule for a detailed explanation.

mod handlers;
mod tree;
mod region;
pub mod roles;

pub use self::handlers::SurfaceIData;
use self::region::RegionData;
use self::roles::{Role, RoleType, WrongRole};
use self::tree::SurfaceData;
pub use self::tree::TraversalAction;
use wayland_server::{resource_is_registered, EventLoop, EventLoopHandle, Global};
use wayland_server::protocol::{wl_buffer, wl_callback, wl_compositor, wl_output, wl_region,
                               wl_subcompositor, wl_surface};

/// Description of which part of a surface
/// should be considered damaged and needs to be redrawn
pub enum Damage {
    /// The whole surface must be considered damaged (this is the default)
    Full,
    /// A rectangle containing the damaged zone, in surface coordinates
    Surface(Rectangle),
    /// A rectangle containing the damaged zone, in buffer coordinates
    ///
    /// Note: Buffer scaling must be taken into consideration
    Buffer(Rectangle),
}

#[derive(Copy, Clone, Default)]
struct Marker<U, R> {
    _u: ::std::marker::PhantomData<U>,
    _r: ::std::marker::PhantomData<R>,
}

/// Data associated with a surface, aggreged by the handlers
///
/// Most of the fields of this struct represent a double-buffered state, which
/// should only be applied once a `commit` request is received from the surface.
///
/// You are responsible for setting those values as you see fit to avoid
/// processing them two times.
pub struct SurfaceAttributes<U> {
    /// Buffer defining the contents of the surface
    ///
    /// The tuple represent the coordinates of this buffer
    /// relative to the location of the current buffer.
    ///
    /// If set to `Some(None)`, it means the user specifically asked for the
    /// surface to be unmapped.
    ///
    /// You are free to set this field to `None` to avoid processing it several
    /// times. It'll be set to `Some(...)` if the user attaches a buffer (or NULL) to
    /// the surface.
    pub buffer: Option<Option<(wl_buffer::WlBuffer, (i32, i32))>>,
    /// Scale of the contents of the buffer, for higher-resolution contents.
    ///
    /// If it matches the one of the output displaying this surface, no change
    /// is necessary.
    pub buffer_scale: i32,
    /// Transform under which interpret the contents of the buffer
    ///
    /// If it matches the one of the output displaying this surface, no change
    /// is necessary.
    pub buffer_transform: wl_output::Transform,
    /// Region of the surface that is guaranteed to be opaque
    ///
    /// By default the whole surface is potentially transparent
    pub opaque_region: Option<RegionAttributes>,
    /// Region of the surface that is sensitive to user input
    ///
    /// By default the whole surface should be sensitive
    pub input_region: Option<RegionAttributes>,
    /// Damage rectangle
    ///
    /// Hint provided by the client to suggest that only this part
    /// of the surface was changed and needs to be redrawn
    pub damage: Damage,
    /// User-controlled data
    ///
    /// This is your field to host whatever you need.
    pub user_data: U,
}

impl<U: Default> Default for SurfaceAttributes<U> {
    fn default() -> SurfaceAttributes<U> {
        SurfaceAttributes {
            buffer: None,
            buffer_scale: 1,
            buffer_transform: wl_output::Transform::Normal,
            opaque_region: None,
            input_region: None,
            damage: Damage::Full,
            user_data: Default::default(),
        }
    }
}

/// Attributes defining the behaviour of a sub-surface relative to its parent
#[derive(Copy, Clone, Debug)]
pub struct SubsurfaceRole {
    /// Horizontal location of the top-left corner of this sub-surface relative to
    /// the top-left corner of its parent
    pub x: i32,
    /// Vertical location of the top-left corner of this sub-surface relative to
    /// the top-left corner of its parent
    pub y: i32,
    /// Sync status of this sub-surface
    ///
    /// If `true`, this surface should be repainted synchronously with its parent
    /// if `false`, it should be considered independant of its parent regarding
    /// repaint timings.
    pub sync: bool,
}

impl Default for SubsurfaceRole {
    fn default() -> SubsurfaceRole {
        SubsurfaceRole {
            x: 0,
            y: 0,
            sync: true,
        }
    }
}

/// Kind of a rectangle part of a region
#[derive(Copy, Clone, Debug)]
pub enum RectangleKind {
    /// This rectangle should be added to the region
    Add,
    /// The intersection of this rectangle with the region should
    /// be removed from the region
    Subtract,
}

/// A rectangle defined by its top-left corner and dimensions
#[derive(Copy, Clone, Debug)]
pub struct Rectangle {
    /// horizontal position of the top-leftcorner of the rectangle, in surface coordinates
    pub x: i32,
    /// vertical position of the top-leftcorner of the rectangle, in surface coordinates
    pub y: i32,
    /// width of the rectangle
    pub width: i32,
    /// height of the rectangle
    pub height: i32,
}

/// Description of the contents of a region
///
/// A region is defined as an union and difference of rectangle.
///
/// This struct contains an ordered Vec containing the rectangles defining
/// a region. They should be added or substracted in this order to compute the
/// actual contents of the region.
#[derive(Clone, Debug)]
pub struct RegionAttributes {
    /// List of rectangle part of this region
    pub rects: Vec<(RectangleKind, Rectangle)>,
}

impl Default for RegionAttributes {
    fn default() -> RegionAttributes {
        RegionAttributes { rects: Vec::new() }
    }
}

/// A Compositor global token
///
/// This token can be cloned at will, and is the entry-point to
/// access data associated with the wl_surface and wl_region managed
/// by the `CompositorGlobal` that provided it.
pub struct CompositorToken<U, R, ID> {
    _data: ::std::marker::PhantomData<*mut U>,
    _role: ::std::marker::PhantomData<*mut R>,
    _idata: ::std::marker::PhantomData<*mut ID>,
}

unsafe impl<U: Send, R: Send, ID> Send for CompositorToken<U, R, ID> {}
unsafe impl<U: Send, R: Send, ID> Sync for CompositorToken<U, R, ID> {}

// we implement them manually because #[derive(..)] would require
// U: Clone and R: Clone
impl<U, R, ID> Copy for CompositorToken<U, R, ID> {}
impl<U, R, ID> Clone for CompositorToken<U, R, ID> {
    fn clone(&self) -> CompositorToken<U, R, ID> {
        *self
    }
}

impl<U, R, ID> CompositorToken<U, R, ID> {
    pub(crate) fn make() -> CompositorToken<U, R, ID> {
        CompositorToken {
            _data: ::std::marker::PhantomData,
            _role: ::std::marker::PhantomData,
            _idata: ::std::marker::PhantomData,
        }
    }
}

impl<U: Send + 'static, R: Send + 'static, ID: 'static> CompositorToken<U, R, ID> {
    /// Access the data of a surface
    ///
    /// The closure will be called with the contents of the data associated with this surface.
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn with_surface_data<F, T>(&self, surface: &wl_surface::WlSurface, f: F) -> T
    where
        F: FnOnce(&mut SurfaceAttributes<U>) -> T,
    {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::with_data(surface, f) }
    }
}

impl<U, R, ID> CompositorToken<U, R, ID>
where
    U: 'static,
    R: RoleType + Role<SubsurfaceRole> + 'static,
    ID: 'static,
{
    /// Access the data of a surface tree
    ///
    /// The provided closure is called successively on the surface and all its child subsurfaces,
    /// in a depth-first order. This matches the order in which the surfaces are supposed to be
    /// drawn: top-most last.
    ///
    /// The arguments provided to the closure are, in this order:
    ///
    /// - The surface object itself
    /// - a mutable reference to its surface attribute data
    /// - a mutable reference to its role data,
    /// - a custom value that is passer in a fold-like maneer, but only from the output of a parent
    ///   to its children. See `TraversalAction` for details.
    ///
    /// If the surface not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn with_surface_tree<F, T>(&self, surface: &wl_surface::WlSurface, initial: T, f: F) -> Result<(), ()>
    where
        F: FnMut(&wl_surface::WlSurface, &mut SurfaceAttributes<U>, &mut R, &T)
              -> TraversalAction<T>,
    {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe {
            SurfaceData::<U, R>::map_tree(surface, initial, f);
        }
        Ok(())
    }

    /// Retrieve the parent of this surface
    ///
    /// Returns `None` is this surface is a root surface
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn get_parent(&self, surface: &wl_surface::WlSurface) -> Option<wl_surface::WlSurface> {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::get_parent(surface) }
    }

    /// Retrieve the children of this surface
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn get_children(&self, surface: &wl_surface::WlSurface) -> Vec<wl_surface::WlSurface> {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::get_children(surface) }
    }
}

impl<U: 'static, R: RoleType + 'static, ID: 'static> CompositorToken<U, R, ID> {
    /// Check wether this surface as a role or not
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn has_a_role(&self, surface: &wl_surface::WlSurface) -> bool {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::has_a_role(surface) }
    }

    /// Check wether this surface as a specific role
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn has_role<RoleData>(&self, surface: &wl_surface::WlSurface) -> bool
    where
        R: Role<RoleData>,
    {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::has_role::<RoleData>(surface) }
    }


    /// Register that this surface has given role with default data
    ///
    /// Fails if the surface already has a role.
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn give_role<RoleData>(&self, surface: &wl_surface::WlSurface) -> Result<(), ()>
    where
        R: Role<RoleData>,
        RoleData: Default,
    {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::give_role::<RoleData>(surface) }
    }

    /// Register that this surface has given role with given data
    ///
    /// Fails if the surface already has a role and returns the data.
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn give_role_with<RoleData>(&self, surface: &wl_surface::WlSurface, data: RoleData)
                                    -> Result<(), RoleData>
    where
        R: Role<RoleData>,
    {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::give_role_with::<RoleData>(surface, data) }
    }

    /// Access the role data of a surface
    ///
    /// Fails and don't call the closure if the surface doesn't have this role
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn with_role_data<RoleData, F, T>(&self, surface: &wl_surface::WlSurface, f: F)
                                          -> Result<T, WrongRole>
    where
        R: Role<RoleData>,
        F: FnOnce(&mut RoleData) -> T,
    {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::with_role_data::<RoleData, _, _>(surface, f) }
    }

    /// Register that this surface does not have a role any longer and retrieve the data
    ///
    /// Fails if the surface didn't already have this role.
    ///
    /// If the surface is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn remove_role<RoleData>(&self, surface: &wl_surface::WlSurface) -> Result<RoleData, WrongRole>
    where
        R: Role<RoleData>,
    {
        assert!(
            resource_is_registered(
                surface,
                &self::handlers::surface_implementation::<U, R, ID>()
            ),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { SurfaceData::<U, R>::remove_role::<RoleData>(surface) }
    }

    /// Retrieve the metadata associated with a wl_region
    ///
    /// If the region is not managed by the CompositorGlobal that provided this token, this
    /// will panic (having more than one compositor is not supported).
    pub fn get_region_attributes(&self, region: &wl_region::WlRegion) -> RegionAttributes {
        assert!(
            resource_is_registered(region, &self::handlers::region_implementation()),
            "Accessing the data of foreign surfaces is not supported."
        );
        unsafe { RegionData::get_attributes(region) }
    }
}

/// Create new wl_compositor and wl_subcompositor globals.
///
/// The globals are directly registered into the eventloop, and this function
/// returns a `CompositorToken` which you'll need access the data associated to
/// the `wl_surface`s.
///
/// It also returns the two global handles, in case you whish to remove these
/// globals from the event loop in the future.
pub fn compositor_init<U, R, ID, L>(
    evl: &mut EventLoop, implem: SurfaceUserImplementation<U, R, ID>, idata: ID, logger: L)
    -> (
        CompositorToken<U, R, ID>,
        Global<wl_compositor::WlCompositor, self::handlers::SurfaceIData<U, R, ID>>,
        Global<wl_subcompositor::WlSubcompositor, ()>,
    )
where
    L: Into<Option<::slog::Logger>>,
    U: Default + 'static,
    R: Default + RoleType + Role<SubsurfaceRole> + 'static,
    ID: 'static,
{
    let log = ::slog_or_stdlog(logger);
    let idata = self::handlers::SurfaceIData::make(
        log.new(o!("smithay_module" => "compositor_handler")),
        implem,
        idata,
    );
    let compositor_global_token =
        evl.register_global::<wl_compositor::WlCompositor, _>(4, self::handlers::compositor_bind, idata);
    let subcompositor_global_token = evl.register_global::<wl_subcompositor::WlSubcompositor, _>(
        1,
        self::handlers::subcompositor_bind::<U, R>,
        (),
    );

    (
        CompositorToken::make(),
        compositor_global_token,
        subcompositor_global_token,
    )
}

/// Sub-implementation for surface event handling
///
/// The global provided by Smithay cannot process these events for you, so they
/// are forwarded directly to this implementation that you must provide
/// at creation of the compositor global.
pub struct SurfaceUserImplementation<U, R, ID> {
    /// The double-buffered state has been validated by the client
    ///
    /// At this point, the pending state that has been accumulated in the `SurfaceAttributes` associated
    /// to this surface should be integrated into the current state of the surface.
    ///
    /// See [`wayland_server::protocol::wl_surface::Implementation::commit`](https://docs.rs/wayland-server/0.10.1/wayland_server/protocol/wl_surface/struct.Implementation.html#structfield.commit)
    /// for more details
    pub commit: fn(
     evlh: &mut EventLoopHandle,
     idata: &mut ID,
     surface: &wl_surface::WlSurface,
     token: CompositorToken<U, R, ID>,
    ),
    /// The client asks to be notified when would be a good time to update the contents of this surface
    ///
    /// You must keep the provided `WlCallback` and trigger it at the appropriate time by calling
    /// its `done()` method.
    ///
    /// See [`wayland_server::protocol::wl_surface::Implementation::frame`](https://docs.rs/wayland-server/0.10.1/wayland_server/protocol/wl_surface/struct.Implementation.html#structfield.frame)
    /// for more details
    pub frame: fn(
     evlh: &mut EventLoopHandle,
     idata: &mut ID,
     surface: &wl_surface::WlSurface,
     callback: wl_callback::WlCallback,
     token: CompositorToken<U, R, ID>,
    ),
}

impl<U, R, ID> Copy for SurfaceUserImplementation<U, R, ID> {}
impl<U, R, ID> Clone for SurfaceUserImplementation<U, R, ID> {
    fn clone(&self) -> SurfaceUserImplementation<U, R, ID> {
        *self
    }
}