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const std = @import("std");
const c = @import("c.zig").c;
const Output = @import("output.zig").Output;
const Root = @import("root.zig").Root;
const Seat = @import("seat.zig").Seat;
const View = @import("view.zig").View;
pub const Server = struct {
const Self = @This();
allocator: *std.mem.Allocator,
root: Root,
seat: Seat,
wl_display: *c.wl_display,
wlr_backend: *c.wlr_backend,
wlr_renderer: *c.wlr_renderer,
listen_new_output: c.wl_listener,
wlr_xdg_shell: *c.wlr_xdg_shell,
listen_new_xdg_surface: c.wl_listener,
pub fn init(self: *Self, allocator: *std.mem.Allocator) !void {
self.allocator = allocator;
// The Wayland display is managed by libwayland. It handles accepting
// clients from the Unix socket, manging Wayland globals, and so on.
self.wl_display = c.wl_display_create() orelse
return error.CantCreateWlDisplay;
errdefer c.wl_display_destroy(self.wl_display);
// The wlr_backend abstracts the input/output hardware. Autocreate chooses
// the best option based on the environment, for example DRM when run from
// a tty or wayland if WAYLAND_DISPLAY is set.
//
// This frees itself.when the wl_display is destroyed.
self.wlr_backend = c.zag_wlr_backend_autocreate(self.wl_display) orelse
return error.CantCreateWlrBackend;
// If we don't provide a renderer, autocreate makes a GLES2 renderer for us.
// The renderer is responsible for defining the various pixel formats it
// supports for shared memory, this configures that for clients.
self.wlr_renderer = c.zag_wlr_backend_get_renderer(self.wlr_backend) orelse
return error.CantGetWlrRenderer;
// TODO: Handle failure after https://github.com/swaywm/wlroots/pull/2080
c.wlr_renderer_init_wl_display(self.wlr_renderer, self.wl_display); // orelse
// return error.CantInitWlDisplay;
// These both free themselves when the wl_display is destroyed
_ = c.wlr_compositor_create(self.wl_display, self.wlr_renderer) orelse
return error.CantCreateWlrCompositor;
_ = c.wlr_data_device_manager_create(self.wl_display) orelse
return error.CantCreateWlrDataDeviceManager;
self.wlr_xdg_shell = c.wlr_xdg_shell_create(self.wl_display) orelse
return error.CantCreateWlrXdgShell;
try self.root.init(self);
self.seat = try Seat.create(self);
try self.seat.init();
// Register our listeners for new outputs and xdg_surfaces.
self.listen_new_output.notify = handle_new_output;
c.wl_signal_add(&self.wlr_backend.events.new_output, &self.listen_new_output);
self.listen_new_xdg_surface.notify = handle_new_xdg_surface;
c.wl_signal_add(&self.wlr_xdg_shell.events.new_surface, &self.listen_new_xdg_surface);
}
/// Free allocated memory and clean up
pub fn destroy(self: *Self) void {
c.wl_display_destroy_clients(self.wl_display);
c.wl_display_destroy(self.wl_display);
self.root.destroy();
}
/// Create the socket, set WAYLAND_DISPLAY, and start the backend
pub fn start(self: Self) !void {
// Add a Unix socket to the Wayland display.
const socket = c.wl_display_add_socket_auto(self.wl_display) orelse
return error.CantAddSocket;
// Start the backend. This will enumerate outputs and inputs, become the DRM
// master, etc
if (!c.zag_wlr_backend_start(self.wlr_backend)) {
return error.CantStartBackend;
}
// Set the WAYLAND_DISPLAY environment variable to our socket and run the
// startup command if requested. */
if (c.setenv("WAYLAND_DISPLAY", socket, 1) == -1) {
return error.CantSetEnv;
}
}
/// Enter the wayland event loop and block until the compositor is exited
pub fn run(self: Self) void {
c.wl_display_run(self.wl_display);
}
pub fn handle_keybinding(self: *Self, sym: c.xkb_keysym_t) bool {
// Here we handle compositor keybindings. This is when the compositor is
// processing keys, rather than passing them on to the client for its own
// processing.
//
// This function assumes the proper modifier is held down.
switch (sym) {
c.XKB_KEY_Escape => c.wl_display_terminate(self.wl_display),
c.XKB_KEY_F1 => {
// Cycle to the next view
//if (c.wl_list_length(&server.views) > 1) {
// const current_view = @fieldParentPtr(View, "link", server.views.next);
// const next_view = @fieldParentPtr(View, "link", current_view.link.next);
// focus_view(next_view, next_view.xdg_surface.surface);
// // Move the previous view to the end of the list
// c.wl_list_remove(¤t_view.link);
// c.wl_list_insert(server.views.prev, ¤t_view.link);
//}
},
else => return false,
}
return true;
}
fn handle_new_output(listener: ?*c.wl_listener, data: ?*c_void) callconv(.C) void {
const server = @fieldParentPtr(Server, "listen_new_output", listener.?);
const wlr_output = @ptrCast(*c.wlr_output, @alignCast(@alignOf(*c.wlr_output), data));
server.root.addOutput(wlr_output);
}
fn handle_new_xdg_surface(listener: ?*c.wl_listener, data: ?*c_void) callconv(.C) void {
// This event is raised when wlr_xdg_shell receives a new xdg surface from a
// client, either a toplevel (application window) or popup.
const server = @fieldParentPtr(Server, "listen_new_xdg_surface", listener.?);
const wlr_xdg_surface = @ptrCast(*c.wlr_xdg_surface, @alignCast(@alignOf(*c.wlr_xdg_surface), data));
if (wlr_xdg_surface.role != c.enum_wlr_xdg_surface_role.WLR_XDG_SURFACE_ROLE_TOPLEVEL) {
// TODO: log
return;
}
// toplevel surfaces are tracked and managed by the root
server.root.addView(wlr_xdg_surface);
}
};
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