gtk2/gdk/wayland/gdkwindow-wayland.c

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2010-12-18 20:38:49 +00:00
/*
* Copyright © 2010 Intel Corporation
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public License
* as published by the Free Software Foundation; either version 2 of
* the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
2012-02-27 13:01:10 +00:00
* License along with this library. If not, see <http://www.gnu.org/licenses/>.
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*/
#include "config.h"
#include <netinet/in.h>
#include <unistd.h>
#include "gdk.h"
#include "gdkwayland.h"
#include "gdkwindow.h"
#include "gdkwindowimpl.h"
#include "gdkdisplay-wayland.h"
#include "gdkglcontext-wayland.h"
#include "gdkframeclockprivate.h"
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#include "gdkprivate-wayland.h"
#include "gdkinternals.h"
#include "gdkdeviceprivate.h"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <errno.h>
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enum {
COMMITTED,
LAST_SIGNAL
};
static guint signals[LAST_SIGNAL];
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#define WINDOW_IS_TOPLEVEL_OR_FOREIGN(window) \
(GDK_WINDOW_TYPE (window) != GDK_WINDOW_CHILD && \
GDK_WINDOW_TYPE (window) != GDK_WINDOW_OFFSCREEN)
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#define WINDOW_IS_TOPLEVEL(window) \
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(GDK_WINDOW_TYPE (window) != GDK_WINDOW_CHILD && \
GDK_WINDOW_TYPE (window) != GDK_WINDOW_FOREIGN && \
GDK_WINDOW_TYPE (window) != GDK_WINDOW_OFFSCREEN)
typedef struct _GdkWaylandWindow GdkWaylandWindow;
typedef struct _GdkWaylandWindowClass GdkWaylandWindowClass;
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struct _GdkWaylandWindow
{
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GdkWindow parent;
};
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struct _GdkWaylandWindowClass
{
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GdkWindowClass parent_class;
};
G_DEFINE_TYPE (GdkWaylandWindow, gdk_wayland_window, GDK_TYPE_WINDOW)
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static void
gdk_wayland_window_class_init (GdkWaylandWindowClass *wayland_window_class)
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{
}
static void
gdk_wayland_window_init (GdkWaylandWindow *wayland_window)
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{
}
#define GDK_TYPE_WINDOW_IMPL_WAYLAND (_gdk_window_impl_wayland_get_type ())
#define GDK_WINDOW_IMPL_WAYLAND(object) (G_TYPE_CHECK_INSTANCE_CAST ((object), GDK_TYPE_WINDOW_IMPL_WAYLAND, GdkWindowImplWayland))
#define GDK_WINDOW_IMPL_WAYLAND_CLASS(klass) (G_TYPE_CHECK_CLASS_CAST ((klass), GDK_TYPE_WINDOW_IMPL_WAYLAND, GdkWindowImplWaylandClass))
#define GDK_IS_WINDOW_IMPL_WAYLAND(object) (G_TYPE_CHECK_INSTANCE_TYPE ((object), GDK_TYPE_WINDOW_IMPL_WAYLAND))
#define GDK_IS_WINDOW_IMPL_WAYLAND_CLASS(klass) (G_TYPE_CHECK_CLASS_TYPE ((klass), GDK_TYPE_WINDOW_IMPL_WAYLAND))
#define GDK_WINDOW_IMPL_WAYLAND_GET_CLASS(obj) (G_TYPE_INSTANCE_GET_CLASS ((obj), GDK_TYPE_WINDOW_IMPL_WAYLAND, GdkWindowImplWaylandClass))
typedef struct _GdkWindowImplWayland GdkWindowImplWayland;
typedef struct _GdkWindowImplWaylandClass GdkWindowImplWaylandClass;
struct _GdkWindowImplWayland
{
GdkWindowImpl parent_instance;
GdkWindow *wrapper;
struct {
/* The wl_outputs that this window currently touches */
GSList *outputs;
struct wl_surface *wl_surface;
struct xdg_surface *xdg_surface;
struct xdg_popup *xdg_popup;
struct gtk_surface1 *gtk_surface;
struct wl_subsurface *wl_subsurface;
struct wl_egl_window *egl_window;
struct wl_egl_window *dummy_egl_window;
} display_server;
EGLSurface egl_surface;
EGLSurface dummy_egl_surface;
unsigned int mapped : 1;
unsigned int use_custom_surface : 1;
unsigned int pending_buffer_attached : 1;
unsigned int pending_commit : 1;
unsigned int awaiting_frame : 1;
unsigned int position_set : 1;
GdkWindowTypeHint hint;
GdkWindow *transient_for;
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
cairo_surface_t *staging_cairo_surface;
cairo_surface_t *committed_cairo_surface;
cairo_surface_t *backfill_cairo_surface;
int pending_buffer_offset_x;
int pending_buffer_offset_y;
gchar *title;
struct {
gboolean was_set;
gchar *application_id;
gchar *app_menu_path;
gchar *menubar_path;
gchar *window_object_path;
gchar *application_object_path;
gchar *unique_bus_name;
} application;
GdkGeometry geometry_hints;
GdkWindowHints geometry_mask;
GdkSeat *grab_input_seat;
gint64 pending_frame_counter;
guint32 scale;
int margin_left;
int margin_right;
int margin_top;
int margin_bottom;
int initial_fullscreen_monitor;
cairo_region_t *opaque_region;
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cairo_region_t *input_region;
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
cairo_region_t *staged_updates_region;
int saved_width;
int saved_height;
};
struct _GdkWindowImplWaylandClass
{
GdkWindowImplClass parent_class;
};
static void gdk_wayland_window_configure (GdkWindow *window,
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int width,
int height,
int scale);
static void maybe_set_gtk_surface_dbus_properties (GdkWindow *window);
static void maybe_set_gtk_surface_modal (GdkWindow *window);
static void gdk_window_request_transient_parent_commit (GdkWindow *window);
GType _gdk_window_impl_wayland_get_type (void);
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G_DEFINE_TYPE (GdkWindowImplWayland, _gdk_window_impl_wayland, GDK_TYPE_WINDOW_IMPL)
static void
_gdk_window_impl_wayland_init (GdkWindowImplWayland *impl)
{
impl->scale = 1;
impl->initial_fullscreen_monitor = -1;
impl->saved_width = -1;
impl->saved_height = -1;
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}
/* Keep a list of orphaned dialogs (i.e. without parent) */
static GList *orphan_dialogs;
static void
_gdk_wayland_screen_add_orphan_dialog (GdkWindow *window)
{
if (!g_list_find (orphan_dialogs, window))
orphan_dialogs = g_list_prepend (orphan_dialogs, window);
}
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
static void
drop_cairo_surfaces (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
g_clear_pointer (&impl->staging_cairo_surface, cairo_surface_destroy);
g_clear_pointer (&impl->backfill_cairo_surface, cairo_surface_destroy);
/* We nullify this so if a buffer release comes in later, we won't
* try to reuse that buffer since it's no longer suitable
*/
impl->committed_cairo_surface = NULL;
}
static void
_gdk_wayland_window_save_size (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (window->state & (GDK_WINDOW_STATE_FULLSCREEN | GDK_WINDOW_STATE_MAXIMIZED))
return;
impl->saved_width = window->width - impl->margin_left - impl->margin_right;
impl->saved_height = window->height - impl->margin_top - impl->margin_bottom;
}
static void
_gdk_wayland_window_clear_saved_size (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (window->state & (GDK_WINDOW_STATE_FULLSCREEN | GDK_WINDOW_STATE_MAXIMIZED))
return;
impl->saved_width = -1;
impl->saved_height = -1;
}
/*
* gdk_wayland_window_update_size:
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* @drawable: a #GdkDrawableImplWayland.
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*
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* Updates the state of the drawable (in particular the drawable's
* cairo surface) when its size has changed.
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*/
static void
gdk_wayland_window_update_size (GdkWindow *window,
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int32_t width,
int32_t height,
int scale)
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{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkRectangle area;
cairo_region_t *region;
2010-12-18 20:38:49 +00:00
if ((window->width == width) &&
(window->height == height) &&
(impl->scale == scale))
return;
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
drop_cairo_surfaces (window);
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window->width = width;
window->height = height;
impl->scale = scale;
if (impl->display_server.egl_window)
{
wl_egl_window_resize (impl->display_server.egl_window,
width * scale,
height * scale,
0, 0);
wl_surface_set_buffer_scale (impl->display_server.wl_surface, scale);
}
area.x = 0;
area.y = 0;
area.width = window->width;
area.height = window->height;
region = cairo_region_create_rectangle (&area);
_gdk_window_invalidate_for_expose (window, region);
cairo_region_destroy (region);
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}
GdkWindow *
_gdk_wayland_screen_create_root_window (GdkScreen *screen,
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int width,
int height)
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{
GdkWaylandDisplay *wayland_display =
GDK_WAYLAND_DISPLAY (gdk_screen_get_display (screen));
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GdkWindow *window;
GdkWindowImplWayland *impl;
window = _gdk_display_create_window (GDK_DISPLAY (wayland_display));
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window->impl = g_object_new (GDK_TYPE_WINDOW_IMPL_WAYLAND, NULL);
window->impl_window = window;
window->visual = gdk_screen_get_system_visual (screen);
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
impl->wrapper = GDK_WINDOW (window);
if (wayland_display->compositor_version >= WL_SURFACE_HAS_BUFFER_SCALE &&
2015-02-28 03:28:28 +00:00
gdk_screen_get_n_monitors (screen) > 0)
impl->scale = gdk_screen_get_monitor_scale_factor (screen, 0);
/* logical 1x1 fake buffer */
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
impl->staging_cairo_surface = cairo_image_surface_create (CAIRO_FORMAT_ARGB32,
impl->scale,
impl->scale);
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
cairo_surface_set_device_scale (impl->staging_cairo_surface, impl->scale, impl->scale);
2010-12-18 20:38:49 +00:00
window->window_type = GDK_WINDOW_ROOT;
window->depth = 32;
window->x = 0;
window->y = 0;
window->abs_x = 0;
window->abs_y = 0;
window->width = width;
window->height = height;
window->viewable = TRUE;
/* see init_randr_support() in gdkscreen-wayland.c */
window->event_mask = GDK_STRUCTURE_MASK;
return window;
}
static const gchar *
get_default_title (void)
{
const char *title;
title = g_get_application_name ();
if (!title)
title = g_get_prgname ();
if (!title)
title = "";
return title;
}
static void
fill_presentation_time_from_frame_time (GdkFrameTimings *timings,
guint32 frame_time)
{
/* The timestamp in a wayland frame is a msec time value that in some
* way reflects the time at which the server started drawing the frame.
* This is not useful from our perspective.
*
* However, for the DRM backend of Weston, on reasonably recent
* Linux, we know that the time is the
2013-09-16 21:23:29 +00:00
* clock_gettime (CLOCK_MONOTONIC) value at the vblank, and that
* backend starts drawing immediately after receiving the vblank
* notification. If we detect this, and make the assumption that the
* compositor will finish drawing before the next vblank, we can
* then determine the presentation time as the frame time we
2013-09-16 21:23:29 +00:00
* received plus one refresh interval.
*
* If a backend is using clock_gettime(CLOCK_MONOTONIC), but not
* picking values right at the vblank, then the presentation times
* we compute won't be accurate, but not really worse than then
* the alternative of not providing presentation times at all.
*
* The complexity here is dealing with the fact that we receive
* only the low 32 bits of the CLOCK_MONOTONIC value in milliseconds.
*/
gint64 now_monotonic = g_get_monotonic_time ();
gint64 now_monotonic_msec = now_monotonic / 1000;
uint32_t now_monotonic_low = (uint32_t)now_monotonic_msec;
if (frame_time - now_monotonic_low < 1000 ||
frame_time - now_monotonic_low > (uint32_t)-1000)
{
/* Timestamp we received is within one second of the current time.
*/
gint64 last_frame_time = now_monotonic + (gint64)1000 * (gint32)(frame_time - now_monotonic_low);
if ((gint32)now_monotonic_low < 0 && (gint32)frame_time > 0)
last_frame_time += (gint64)1000 * G_GINT64_CONSTANT(0x100000000);
else if ((gint32)now_monotonic_low > 0 && (gint32)frame_time < 0)
last_frame_time -= (gint64)1000 * G_GINT64_CONSTANT(0x100000000);
timings->presentation_time = last_frame_time + timings->refresh_interval;
}
}
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
static void
read_back_cairo_surface (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
cairo_t *cr;
cairo_region_t *paint_region = NULL;
if (!impl->backfill_cairo_surface)
goto out;
paint_region = cairo_region_copy (window->clip_region);
cairo_region_subtract (paint_region, impl->staged_updates_region);
if (cairo_region_is_empty (paint_region))
goto out;
cr = cairo_create (impl->staging_cairo_surface);
cairo_set_source_surface (cr, impl->backfill_cairo_surface, 0, 0);
gdk_cairo_region (cr, paint_region);
cairo_clip (cr);
cairo_set_operator (cr, CAIRO_OPERATOR_SOURCE);
cairo_paint (cr);
cairo_destroy (cr);
cairo_surface_flush (impl->staging_cairo_surface);
out:
g_clear_pointer (&paint_region, cairo_region_destroy);
g_clear_pointer (&impl->staged_updates_region, cairo_region_destroy);
g_clear_pointer (&impl->backfill_cairo_surface, cairo_surface_destroy);
}
static void
frame_callback (void *data,
struct wl_callback *callback,
uint32_t time)
{
GdkWindow *window = data;
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWaylandDisplay *wayland_display = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
GdkFrameClock *clock = gdk_window_get_frame_clock (window);
GdkFrameTimings *timings;
2015-02-28 05:15:13 +00:00
GDK_NOTE (EVENTS,
g_message ("frame %p", window));
wl_callback_destroy (callback);
if (GDK_WINDOW_DESTROYED (window))
return;
if (!impl->awaiting_frame)
return;
impl->awaiting_frame = FALSE;
_gdk_frame_clock_thaw (clock);
timings = gdk_frame_clock_get_timings (clock, impl->pending_frame_counter);
impl->pending_frame_counter = 0;
if (timings == NULL)
return;
timings->refresh_interval = 16667; /* default to 1/60th of a second */
if (impl->display_server.outputs)
{
/* We pick a random output out of the outputs that the window touches
* The rate here is in milli-hertz */
int refresh_rate = _gdk_wayland_screen_get_output_refresh_rate (wayland_display->screen,
impl->display_server.outputs->data);
if (refresh_rate != 0)
timings->refresh_interval = G_GINT64_CONSTANT(1000000000) / refresh_rate;
}
fill_presentation_time_from_frame_time (timings, time);
timings->complete = TRUE;
#ifdef G_ENABLE_DEBUG
if ((_gdk_debug_flags & GDK_DEBUG_FRAMES) != 0)
_gdk_frame_clock_debug_print_timings (clock, timings);
#endif
}
static const struct wl_callback_listener frame_listener = {
frame_callback
};
static void
on_frame_clock_before_paint (GdkFrameClock *clock,
GdkWindow *window)
{
GdkFrameTimings *timings = gdk_frame_clock_get_current_timings (clock);
gint64 presentation_time;
gint64 refresh_interval;
gdk_frame_clock_get_refresh_info (clock,
timings->frame_time,
&refresh_interval, &presentation_time);
if (presentation_time != 0)
{
/* Assume the algorithm used by the DRM backend of Weston - it
* starts drawing at the next vblank after receiving the commit
* for this frame, and presentation occurs at the vblank
* after that.
*/
timings->predicted_presentation_time = presentation_time + refresh_interval;
}
else
{
/* As above, but we don't actually know the phase of the vblank,
* so just assume that we're half way through a refresh cycle.
*/
timings->predicted_presentation_time = timings->frame_time + refresh_interval / 2 + refresh_interval;
}
}
static void
on_frame_clock_after_paint (GdkFrameClock *clock,
GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
struct wl_callback *callback;
if (!impl->pending_commit)
return;
callback = wl_surface_frame (impl->display_server.wl_surface);
wl_callback_add_listener (callback, &frame_listener, window);
_gdk_frame_clock_freeze (clock);
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
/* Before we commit a new buffer, make sure we've backfilled
* undrawn parts from any old committed buffer
*/
if (impl->pending_buffer_attached)
read_back_cairo_surface (window);
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
/* From this commit forward, we can't write to the buffer,
* it's "live". In the future, if we need to stage more changes
* we have to allocate a new staging buffer and draw to it instead.
*
* Our one saving grace is if the compositor releases the buffer
* before we need to stage any changes, then we can take it back and
* use it again.
*/
wl_surface_commit (impl->display_server.wl_surface);
if (impl->pending_buffer_attached)
impl->committed_cairo_surface = g_steal_pointer (&impl->staging_cairo_surface);
impl->pending_buffer_attached = FALSE;
impl->pending_commit = FALSE;
impl->pending_frame_counter = gdk_frame_clock_get_frame_counter (clock);
impl->awaiting_frame = TRUE;
g_signal_emit (impl, signals[COMMITTED], 0);
}
static void
window_update_scale (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWaylandDisplay *wayland_display = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
guint32 scale;
GSList *l;
if (wayland_display->compositor_version < WL_SURFACE_HAS_BUFFER_SCALE)
{
/* We can't set the scale on this surface */
return;
}
scale = 1;
for (l = impl->display_server.outputs; l != NULL; l = l->next)
{
guint32 output_scale =
2015-02-28 03:28:28 +00:00
_gdk_wayland_screen_get_output_scale (wayland_display->screen, l->data);
scale = MAX (scale, output_scale);
}
/* Notify app that scale changed */
2015-02-28 03:28:28 +00:00
gdk_wayland_window_configure (window, window->width, window->height, scale);
}
static void
on_monitors_changed (GdkScreen *screen,
2013-09-16 21:23:29 +00:00
GdkWindow *window)
{
window_update_scale (window);
}
2013-09-16 21:23:29 +00:00
static void gdk_wayland_window_create_surface (GdkWindow *window);
2010-12-18 20:38:49 +00:00
void
_gdk_wayland_display_create_window_impl (GdkDisplay *display,
2013-09-16 21:23:29 +00:00
GdkWindow *window,
GdkWindow *real_parent,
GdkScreen *screen,
GdkEventMask event_mask,
GdkWindowAttr *attributes,
gint attributes_mask)
2010-12-18 20:38:49 +00:00
{
GdkWaylandDisplay *wayland_display = GDK_WAYLAND_DISPLAY (display);
2010-12-18 20:38:49 +00:00
GdkWindowImplWayland *impl;
GdkFrameClock *frame_clock;
2010-12-18 20:38:49 +00:00
const char *title;
impl = g_object_new (GDK_TYPE_WINDOW_IMPL_WAYLAND, NULL);
window->impl = GDK_WINDOW_IMPL (impl);
impl->wrapper = GDK_WINDOW (window);
2015-02-28 03:28:28 +00:00
if (window->width > 65535)
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{
2015-02-28 03:28:28 +00:00
g_warning ("Native Windows wider than 65535 pixels are not supported");
window->width = 65535;
}
if (window->height > 65535)
{
g_warning ("Native Windows taller than 65535 pixels are not supported");
window->height = 65535;
2010-12-18 20:38:49 +00:00
}
2010-12-18 20:38:49 +00:00
g_object_ref (window);
/* More likely to be right than just assuming 1 */
if (wayland_display->compositor_version >= WL_SURFACE_HAS_BUFFER_SCALE &&
gdk_screen_get_n_monitors (screen) > 0)
impl->scale = gdk_screen_get_monitor_scale_factor (screen, 0);
impl->title = NULL;
2010-12-18 20:38:49 +00:00
switch (GDK_WINDOW_TYPE (window))
{
case GDK_WINDOW_TOPLEVEL:
case GDK_WINDOW_TEMP:
if (attributes_mask & GDK_WA_TITLE)
2013-09-16 21:23:29 +00:00
title = attributes->title;
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else
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title = get_default_title ();
2010-12-18 20:38:49 +00:00
gdk_window_set_title (window, title);
break;
case GDK_WINDOW_CHILD:
default:
break;
}
gdk_wayland_window_create_surface (window);
2010-12-18 20:38:49 +00:00
if (attributes_mask & GDK_WA_TYPE_HINT)
gdk_window_set_type_hint (window, attributes->type_hint);
frame_clock = gdk_window_get_frame_clock (window);
g_signal_connect (frame_clock, "before-paint",
G_CALLBACK (on_frame_clock_before_paint), window);
g_signal_connect (frame_clock, "after-paint",
G_CALLBACK (on_frame_clock_after_paint), window);
g_signal_connect (screen, "monitors-changed",
G_CALLBACK (on_monitors_changed), window);
2010-12-18 20:38:49 +00:00
}
2011-01-08 01:49:40 +00:00
static void
gdk_wayland_window_attach_image (GdkWindow *window)
{
GdkWaylandDisplay *display;
2011-01-08 01:49:40 +00:00
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
2010-12-18 20:38:49 +00:00
2011-01-08 01:49:40 +00:00
if (GDK_WINDOW_DESTROYED (window))
return;
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
g_assert (_gdk_wayland_is_shm_surface (impl->staging_cairo_surface));
/* Attach this new buffer to the surface */
wl_surface_attach (impl->display_server.wl_surface,
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
_gdk_wayland_shm_surface_get_wl_buffer (impl->staging_cairo_surface),
impl->pending_buffer_offset_x,
impl->pending_buffer_offset_y);
impl->pending_buffer_offset_x = 0;
impl->pending_buffer_offset_y = 0;
/* Only set the buffer scale if supported by the compositor */
display = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
if (display->compositor_version >= WL_SURFACE_HAS_BUFFER_SCALE)
wl_surface_set_buffer_scale (impl->display_server.wl_surface, impl->scale);
impl->pending_buffer_attached = TRUE;
impl->pending_commit = TRUE;
2010-12-18 20:38:49 +00:00
}
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
static const cairo_user_data_key_t gdk_wayland_window_cairo_key;
static void
buffer_release_callback (void *_data,
struct wl_buffer *wl_buffer)
{
cairo_surface_t *cairo_surface = _data;
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
GdkWindowImplWayland *impl = cairo_surface_get_user_data (cairo_surface, &gdk_wayland_window_cairo_key);
g_return_if_fail (GDK_IS_WINDOW_IMPL_WAYLAND (impl));
/* The released buffer isn't the latest committed one, we have no further
* use for it, so clean it up.
*/
if (impl->committed_cairo_surface != cairo_surface)
{
/* If this fails, then the surface buffer got reused before it was
* released from the compositor
*/
g_warn_if_fail (impl->staging_cairo_surface != cairo_surface);
cairo_surface_destroy (cairo_surface);
return;
}
if (impl->staged_updates_region != NULL)
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
{
/* If this fails, then we're tracking staged updates on a staging surface
* that doesn't exist.
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
*/
g_warn_if_fail (impl->staging_cairo_surface != NULL);
/* If we've staged updates into a new buffer before the release for this
* buffer came in, then we can't reuse this buffer, so unref it. It may still
* be alive as a readback buffer though (via impl->backfill_cairo_surface).
*
* It's possible a staging surface was allocated but no updates were staged.
* If that happened, clean up that staging surface now, since the old commit
* buffer is available again, and reusing the old commit buffer for future
* updates will save having to do a read back later.
*/
if (!cairo_region_is_empty (impl->staged_updates_region))
{
g_clear_pointer (&impl->committed_cairo_surface, cairo_surface_destroy);
return;
}
else
{
g_clear_pointer (&impl->staged_updates_region, cairo_region_destroy);
g_clear_pointer (&impl->staging_cairo_surface, cairo_surface_destroy);
}
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
}
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
/* Release came in, we haven't done any interim updates, so we can just use
* the old committed buffer again.
*/
impl->staging_cairo_surface = g_steal_pointer (&impl->committed_cairo_surface);
}
static const struct wl_buffer_listener buffer_listener = {
buffer_release_callback
};
static void
gdk_wayland_window_ensure_cairo_surface (GdkWindow *window)
2010-12-18 20:38:49 +00:00
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
/* If we are drawing using OpenGL then we only need a logical 1x1 surface. */
if (impl->display_server.egl_window)
{
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
if (impl->staging_cairo_surface &&
_gdk_wayland_is_shm_surface (impl->staging_cairo_surface))
cairo_surface_destroy (impl->staging_cairo_surface);
impl->staging_cairo_surface = cairo_image_surface_create (CAIRO_FORMAT_ARGB32,
impl->scale,
impl->scale);
cairo_surface_set_device_scale (impl->staging_cairo_surface,
impl->scale, impl->scale);
}
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
else if (!impl->staging_cairo_surface)
2010-12-18 20:38:49 +00:00
{
2014-02-23 18:57:24 +00:00
GdkWaylandDisplay *display_wayland = GDK_WAYLAND_DISPLAY (gdk_window_get_display (impl->wrapper));
struct wl_buffer *buffer;
2014-02-23 18:57:24 +00:00
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
impl->staging_cairo_surface = _gdk_wayland_display_create_shm_surface (display_wayland,
impl->wrapper->width,
impl->wrapper->height,
impl->scale);
cairo_surface_set_user_data (impl->staging_cairo_surface,
&gdk_wayland_window_cairo_key,
g_object_ref (impl),
(cairo_destroy_func_t)
g_object_unref);
buffer = _gdk_wayland_shm_surface_get_wl_buffer (impl->staging_cairo_surface);
wl_buffer_add_listener (buffer, &buffer_listener, impl->staging_cairo_surface);
2010-12-18 20:38:49 +00:00
}
}
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
/* The cairo surface returned here uses a memory segment that's shared
* with the display server. This is not a temporary buffer that gets
* copied to the display server, but the actual buffer the display server
* will ultimately end up sending to the GPU. At the time this happens
* impl->committed_cairo_surface gets set to impl->staging_cairo_surface, and
* impl->staging_cairo_surface gets nullified.
*/
static cairo_surface_t *
gdk_wayland_window_ref_cairo_surface (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (GDK_WINDOW_DESTROYED (impl->wrapper))
return NULL;
gdk_wayland_window_ensure_cairo_surface (window);
2011-01-08 01:49:40 +00:00
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
cairo_surface_reference (impl->staging_cairo_surface);
2010-12-18 20:38:49 +00:00
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
return impl->staging_cairo_surface;
2010-12-18 20:38:49 +00:00
}
static cairo_surface_t *
gdk_wayland_window_create_similar_image_surface (GdkWindow * window,
cairo_format_t format,
int width,
int height)
{
return cairo_image_surface_create (format, width, height);
}
static gboolean
gdk_window_impl_wayland_begin_paint (GdkWindow *window)
{
gdk_wayland_window_ensure_cairo_surface (window);
2015-02-28 03:28:28 +00:00
return FALSE;
}
static void
gdk_window_impl_wayland_end_paint (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
cairo_rectangle_int_t rect;
int i, n;
if (!window->current_paint.use_gl &&
!cairo_region_is_empty (window->current_paint.region))
{
gdk_wayland_window_attach_image (window);
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
/* If there's a committed buffer pending, then track which
* updates are staged until the next frame, so we can back
* fill the unstaged parts of the staging buffer with the
* last frame.
*/
if (impl->committed_cairo_surface != NULL)
{
if (impl->staged_updates_region == NULL)
{
impl->staged_updates_region = cairo_region_copy (window->current_paint.region);
impl->backfill_cairo_surface = cairo_surface_reference (impl->committed_cairo_surface);
}
else
{
cairo_region_union (impl->staged_updates_region, window->current_paint.region);
}
}
n = cairo_region_num_rectangles (window->current_paint.region);
for (i = 0; i < n; i++)
{
cairo_region_get_rectangle (window->current_paint.region, i, &rect);
wl_surface_damage (impl->display_server.wl_surface, rect.x, rect.y, rect.width, rect.height);
}
impl->pending_commit = TRUE;
}
}
static gboolean
gdk_window_impl_wayland_beep (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWaylandDisplay *display_wayland =
GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
if (!display_wayland->gtk_shell)
return FALSE;
gtk_shell1_system_bell (display_wayland->gtk_shell,
impl->display_server.gtk_surface);
return TRUE;
}
static void
gdk_window_impl_wayland_finalize (GObject *object)
{
GdkWindowImplWayland *impl;
g_return_if_fail (GDK_IS_WINDOW_IMPL_WAYLAND (object));
impl = GDK_WINDOW_IMPL_WAYLAND (object);
g_free (impl->title);
g_free (impl->application.application_id);
g_free (impl->application.app_menu_path);
g_free (impl->application.menubar_path);
g_free (impl->application.window_object_path);
g_free (impl->application.application_object_path);
g_free (impl->application.unique_bus_name);
g_clear_pointer (&impl->opaque_region, cairo_region_destroy);
2014-03-17 20:02:47 +00:00
g_clear_pointer (&impl->input_region, cairo_region_destroy);
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
g_clear_pointer (&impl->staged_updates_region, cairo_region_destroy);
G_OBJECT_CLASS (_gdk_window_impl_wayland_parent_class)->finalize (object);
}
static void
gdk_wayland_window_configure (GdkWindow *window,
2013-09-16 21:23:29 +00:00
int width,
int height,
int scale)
{
GdkDisplay *display;
GdkEvent *event;
event = gdk_event_new (GDK_CONFIGURE);
event->configure.window = g_object_ref (window);
event->configure.send_event = FALSE;
event->configure.width = width;
event->configure.height = height;
gdk_wayland_window_update_size (window, width, height, scale);
_gdk_window_update_size (window);
display = gdk_window_get_display (window);
_gdk_wayland_display_deliver_event (display, event);
}
static void
gdk_wayland_window_sync_parent (GdkWindow *window,
GdkWindow *parent)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWindowImplWayland *impl_parent = NULL;
struct xdg_surface *parent_surface;
if (!impl->display_server.xdg_surface)
return;
if (impl->transient_for)
impl_parent = GDK_WINDOW_IMPL_WAYLAND (impl->transient_for->impl);
else if (parent)
impl_parent = GDK_WINDOW_IMPL_WAYLAND (parent->impl);
if (impl_parent)
{
/* XXX: Is this correct? */
if (!impl_parent->display_server.wl_surface)
return;
parent_surface = impl_parent->display_server.xdg_surface;
}
else
parent_surface = NULL;
xdg_surface_set_parent (impl->display_server.xdg_surface, parent_surface);
}
static void
gdk_wayland_window_update_dialogs (GdkWindow *window)
{
GList *l;
if (!orphan_dialogs)
return;
for (l = orphan_dialogs; l; l = l->next)
{
GdkWindow *w = l->data;
GdkWindowImplWayland *impl;
if (!GDK_IS_WINDOW_IMPL_WAYLAND(w->impl))
continue;
impl = GDK_WINDOW_IMPL_WAYLAND (w->impl);
if (w == window)
continue;
if (impl->hint != GDK_WINDOW_TYPE_HINT_DIALOG)
continue;
if (impl->transient_for)
continue;
/* Update the parent relationship only for dialogs without transients */
gdk_wayland_window_sync_parent (w, window);
}
}
static void
gdk_wayland_window_sync_title (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (!impl->display_server.xdg_surface)
return;
if (!impl->title)
return;
xdg_surface_set_title (impl->display_server.xdg_surface, impl->title);
}
static void
gdk_wayland_window_sync_margin (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
gint x, y, width, height;
if (!impl->display_server.xdg_surface)
return;
x = impl->margin_left;
y = impl->margin_top;
width = window->width - (impl->margin_left + impl->margin_right);
height = window->height - (impl->margin_top + impl->margin_bottom);
xdg_surface_set_window_geometry (impl->display_server.xdg_surface, x, y, width, height);
}
static struct wl_region *
wl_region_from_cairo_region (GdkWaylandDisplay *display,
cairo_region_t *region)
{
struct wl_region *wl_region;
int i, n_rects;
wl_region = wl_compositor_create_region (display->compositor);
if (wl_region == NULL)
return NULL;
n_rects = cairo_region_num_rectangles (region);
for (i = 0; i < n_rects; i++)
{
cairo_rectangle_int_t rect;
cairo_region_get_rectangle (region, i, &rect);
wl_region_add (wl_region, rect.x, rect.y, rect.width, rect.height);
}
return wl_region;
}
static void
gdk_wayland_window_sync_opaque_region (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
struct wl_region *wl_region = NULL;
if (!impl->display_server.wl_surface)
return;
if (impl->opaque_region != NULL)
wl_region = wl_region_from_cairo_region (GDK_WAYLAND_DISPLAY (gdk_window_get_display (window)),
impl->opaque_region);
wl_surface_set_opaque_region (impl->display_server.wl_surface, wl_region);
if (wl_region != NULL)
wl_region_destroy (wl_region);
}
2014-03-17 20:02:47 +00:00
static void
gdk_wayland_window_sync_input_region (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
struct wl_region *wl_region = NULL;
if (!impl->display_server.wl_surface)
2014-03-17 20:02:47 +00:00
return;
if (impl->input_region != NULL)
wl_region = wl_region_from_cairo_region (GDK_WAYLAND_DISPLAY (gdk_window_get_display (window)),
impl->input_region);
wl_surface_set_input_region (impl->display_server.wl_surface, wl_region);
2014-03-17 20:02:47 +00:00
if (wl_region != NULL)
wl_region_destroy (wl_region);
}
static void
2013-09-16 21:23:29 +00:00
surface_enter (void *data,
struct wl_surface *wl_surface,
2013-09-16 21:23:29 +00:00
struct wl_output *output)
{
GdkWindow *window = GDK_WINDOW (data);
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
2015-02-28 05:15:13 +00:00
GDK_NOTE (EVENTS,
g_message ("surface enter, window %p output %p", window, output));
impl->display_server.outputs = g_slist_prepend (impl->display_server.outputs, output);
window_update_scale (window);
}
static void
2013-09-16 21:23:29 +00:00
surface_leave (void *data,
struct wl_surface *wl_surface,
2013-09-16 21:23:29 +00:00
struct wl_output *output)
{
GdkWindow *window = GDK_WINDOW (data);
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
2015-02-28 05:15:13 +00:00
GDK_NOTE (EVENTS,
g_message ("surface leave, window %p output %p", window, output));
impl->display_server.outputs = g_slist_remove (impl->display_server.outputs, output);
window_update_scale (window);
}
static const struct wl_surface_listener surface_listener = {
surface_enter,
surface_leave
};
static void
on_parent_surface_committed (GdkWindowImplWayland *parent_impl,
GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
g_signal_handlers_disconnect_by_func (parent_impl,
(gpointer) on_parent_surface_committed,
window);
wl_subsurface_set_desync (impl->display_server.wl_subsurface);
}
static void
gdk_wayland_window_create_subsurface (GdkWindow *window)
{
GdkWindowImplWayland *impl, *parent_impl = NULL;
GdkWaylandDisplay *display_wayland;
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (!impl->display_server.wl_surface)
return; /* Bail out, surface and subsurface will be created later when shown */
if (impl->display_server.wl_subsurface)
return;
if (impl->transient_for)
parent_impl = GDK_WINDOW_IMPL_WAYLAND (impl->transient_for->impl);
if (parent_impl)
{
display_wayland = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
impl->display_server.wl_subsurface =
wl_subcompositor_get_subsurface (display_wayland->subcompositor,
impl->display_server.wl_surface, parent_impl->display_server.wl_surface);
wl_subsurface_set_position (impl->display_server.wl_subsurface, window->x, window->y);
/* In order to synchronize the initial position with the initial frame
* content, wait with making the subsurface desynchronized until after
* the parent was committed.
*/
g_signal_connect_object (parent_impl, "committed",
G_CALLBACK (on_parent_surface_committed),
window, 0);
gdk_window_request_transient_parent_commit (window);
}
}
static void
gdk_wayland_window_create_surface (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWaylandDisplay *display_wayland = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
impl->display_server.wl_surface = wl_compositor_create_surface (display_wayland->compositor);
wl_surface_add_listener (impl->display_server.wl_surface, &surface_listener, window);
gdk_wayland_window_sync_opaque_region (window);
2014-03-17 20:02:47 +00:00
gdk_wayland_window_sync_input_region (window);
}
static void
xdg_surface_configure (void *data,
struct xdg_surface *xdg_surface,
int32_t width,
int32_t height,
struct wl_array *states,
uint32_t serial)
{
GdkWindow *window = GDK_WINDOW (data);
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWindowState new_state = 0;
gboolean maximized_or_fullscreen;
uint32_t *p;
2015-02-28 03:28:28 +00:00
wl_array_for_each (p, states)
{
uint32_t state = *p;
switch (state)
{
case XDG_SURFACE_STATE_FULLSCREEN:
new_state |= GDK_WINDOW_STATE_FULLSCREEN;
break;
case XDG_SURFACE_STATE_MAXIMIZED:
new_state |= GDK_WINDOW_STATE_MAXIMIZED;
break;
case XDG_SURFACE_STATE_ACTIVATED:
new_state |= GDK_WINDOW_STATE_FOCUSED;
break;
case XDG_SURFACE_STATE_RESIZING:
break;
default:
/* Unknown state */
break;
}
}
maximized_or_fullscreen =
new_state & (GDK_WINDOW_STATE_MAXIMIZED | GDK_WINDOW_STATE_FULLSCREEN);
/* According to xdg_shell, an xdg_surface.configure with size 0x0
* should be interpreted as that it is up to the client to set a
* size.
*
* When transitioning from maximize or fullscreen state, this means
* the client should configure its size back to what it was before
* being maximize or fullscreen.
*/
if (width == 0 && height == 0 && !maximized_or_fullscreen)
{
width = impl->saved_width;
height = impl->saved_height;
}
if (width > 0 && height > 0)
{
GdkWindowHints geometry_mask = impl->geometry_mask;
/* Ignore size increments for maximized/fullscreen windows */
if (maximized_or_fullscreen)
geometry_mask &= ~GDK_HINT_RESIZE_INC;
gdk_window_constrain_size (&impl->geometry_hints,
geometry_mask,
width + impl->margin_left + impl->margin_right,
height + impl->margin_top + impl->margin_bottom,
&width,
&height);
/* Save size for next time we get 0x0 */
_gdk_wayland_window_save_size (window);
gdk_wayland_window_configure (window, width, height, impl->scale);
}
2015-02-28 05:15:13 +00:00
GDK_NOTE (EVENTS,
g_message ("configure, window %p %dx%d,%s%s%s",
window, width, height,
(new_state & GDK_WINDOW_STATE_FULLSCREEN) ? " fullscreen" : "",
(new_state & GDK_WINDOW_STATE_MAXIMIZED) ? " maximized" : "",
(new_state & GDK_WINDOW_STATE_FOCUSED) ? " focused" : ""));
_gdk_set_window_state (window, new_state);
gdk_wayland_window_sync_margin (window);
2014-05-13 20:21:11 +00:00
xdg_surface_ack_configure (xdg_surface, serial);
if (impl->hint != GDK_WINDOW_TYPE_HINT_DIALOG &&
new_state & GDK_WINDOW_STATE_FOCUSED)
gdk_wayland_window_update_dialogs (window);
}
2014-02-07 22:16:40 +00:00
static void
2015-02-28 03:28:28 +00:00
xdg_surface_close (void *data,
struct xdg_surface *xdg_surface)
2014-02-07 22:16:40 +00:00
{
GdkWindow *window = GDK_WINDOW (data);
GdkDisplay *display;
GdkEvent *event;
2015-02-28 05:15:13 +00:00
GDK_NOTE (EVENTS,
g_message ("close %p", window));
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event = gdk_event_new (GDK_DELETE);
2014-06-19 18:55:04 +00:00
event->any.window = g_object_ref (window);
2014-02-07 22:16:40 +00:00
event->any.send_event = TRUE;
display = gdk_window_get_display (window);
2014-02-07 22:16:40 +00:00
_gdk_wayland_display_deliver_event (display, event);
}
static const struct xdg_surface_listener xdg_surface_listener = {
xdg_surface_configure,
xdg_surface_close,
};
static void
gdk_wayland_window_create_xdg_surface (GdkWindow *window)
{
GdkWaylandDisplay *display_wayland = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
const gchar *app_id;
GdkScreen *screen = gdk_window_get_screen (window);
struct wl_output *fullscreen_output = NULL;
if (impl->initial_fullscreen_monitor >= 0 &&
impl->initial_fullscreen_monitor < gdk_screen_get_n_monitors (screen))
fullscreen_output = _gdk_wayland_screen_get_wl_output (screen, impl->initial_fullscreen_monitor);
impl->display_server.xdg_surface = xdg_shell_get_xdg_surface (display_wayland->xdg_shell, impl->display_server.wl_surface);
xdg_surface_add_listener (impl->display_server.xdg_surface, &xdg_surface_listener, window);
gdk_wayland_window_sync_parent (window, NULL);
gdk_wayland_window_sync_title (window);
gdk_wayland_window_sync_margin (window);
if (window->state & GDK_WINDOW_STATE_MAXIMIZED)
xdg_surface_set_maximized (impl->display_server.xdg_surface);
if (window->state & GDK_WINDOW_STATE_FULLSCREEN)
xdg_surface_set_fullscreen (impl->display_server.xdg_surface, fullscreen_output);
app_id = g_get_prgname ();
if (app_id == NULL)
app_id = gdk_get_program_class ();
xdg_surface_set_app_id (impl->display_server.xdg_surface, app_id);
maybe_set_gtk_surface_dbus_properties (window);
maybe_set_gtk_surface_modal (window);
if (impl->hint == GDK_WINDOW_TYPE_HINT_DIALOG)
_gdk_wayland_screen_add_orphan_dialog (window);
}
static void
xdg_popup_done (void *data,
struct xdg_popup *xdg_popup)
{
GdkWindow *window = GDK_WINDOW (data);
2015-02-28 05:15:13 +00:00
GDK_NOTE (EVENTS,
g_message ("done %p", window));
gdk_window_hide (window);
}
static const struct xdg_popup_listener xdg_popup_listener = {
xdg_popup_done,
};
/**
* gdk_wayland_window_get_fake_root_coords:
* @window: A #GdkWindow
* @x_out: (out): The X offset of this window
* @y_out: (out): The Y offset of this window
*
* Wayland does not have a global coordinate space shared between
* surfaces. In fact, for regular toplevels, we have no idea where
* our surfaces are positioned, relatively.
*
* However, there are some cases like popups and subsurfaces where
* we do have some amount of control over the placement of our
* window, and we can semi-accurately control the x/y position of
* these windows, if they are relative to another surface.
*
* GTK+ loves to position "relative" popups like menus in root
* window coordinates, since it was built for display servers that
* have queryable absolute coordinate spaces. In these cases, GTK+
* might ask for the root coordinates of a widget window, add a
* few values, and then call gdk_window_move() with that absolute
* value.
*
* In Wayland, we have to "reverse-engineer" this use, and figure
* out the root coordinates from the relative position, and the
* relative position from the root coordinates.
*
* We invent a coordinate space called the "fake root coordinate"
* space in which a toplevel is always at 0,0, and all popups are
* relative to that space.
*
* gdk_wayland_window_get_fake_root_coords() gives you the
* position of a #GdkWindow in "fake root" coordinates.
*/
static void
gdk_wayland_window_get_fake_root_coords (GdkWindow *window,
gint *x_out,
gint *y_out)
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{
gint x_offset = 0, y_offset = 0;
while (window)
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{
GdkWindowImplWayland *impl;
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x_offset += window->x;
y_offset += window->y;
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
window = impl->transient_for;
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}
*x_out = x_offset;
*y_out = y_offset;
}
static void
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gdk_wayland_window_create_xdg_popup (GdkWindow *window,
GdkWindow *parent,
struct wl_seat *seat)
{
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GdkWaylandDisplay *display = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWindowImplWayland *parent_impl = GDK_WINDOW_IMPL_WAYLAND (parent->impl);
GdkSeat *gdk_seat;
guint32 serial;
int x, y;
int parent_x, parent_y;
if (!impl->display_server.wl_surface)
return;
if (!parent_impl->display_server.wl_surface)
return;
gdk_seat = gdk_display_get_default_seat (GDK_DISPLAY (display));
gdk_wayland_window_get_fake_root_coords (parent, &parent_x, &parent_y);
x = window->x - parent_x;
y = window->y - parent_y;
serial = _gdk_wayland_seat_get_last_implicit_grab_serial (gdk_seat, NULL);
impl->display_server.xdg_popup = xdg_shell_get_xdg_popup (display->xdg_shell,
impl->display_server.wl_surface,
parent_impl->display_server.wl_surface,
seat, serial,
x, y);
xdg_popup_add_listener (impl->display_server.xdg_popup, &xdg_popup_listener, window);
}
static struct wl_seat *
find_grab_input_seat (GdkWindow *window, GdkWindow *transient_for)
{
GdkWindow *attached_grab_window;
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWindowImplWayland *tmp_impl;
/* Use the device that was used for the grab as the device for
* the popup window setup - so this relies on GTK+ taking the
* grab before showing the popup window.
*/
if (impl->grab_input_seat)
return gdk_wayland_seat_get_wl_seat (impl->grab_input_seat);
/* HACK: GtkMenu grabs a special window known as the "grab transfer window"
* and then transfers the grab over to the correct window later. Look for
* this window when taking the grab to know it's correct.
*
* See: associate_menu_grab_transfer_window in gtkmenu.c
*/
attached_grab_window = g_object_get_data (G_OBJECT (window), "gdk-attached-grab-window");
if (attached_grab_window)
{
tmp_impl = GDK_WINDOW_IMPL_WAYLAND (attached_grab_window->impl);
if (tmp_impl->grab_input_seat)
return gdk_wayland_seat_get_wl_seat (tmp_impl->grab_input_seat);
}
while (transient_for)
{
tmp_impl = GDK_WINDOW_IMPL_WAYLAND (transient_for->impl);
if (tmp_impl->grab_input_seat)
return gdk_wayland_seat_get_wl_seat (tmp_impl->grab_input_seat);
transient_for = tmp_impl->transient_for;
}
return NULL;
}
static struct wl_seat *
find_default_input_seat (GdkWindow *window)
{
GdkDisplay *display;
GdkSeat *seat;
display = gdk_window_get_display (window);
seat = gdk_display_get_default_seat (display);
return gdk_wayland_seat_get_wl_seat (seat);
}
static gboolean
should_be_mapped (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
/* Don't map crazy temp that GTK+ uses for internal X11 shenanigans. */
if (window->window_type == GDK_WINDOW_TEMP && window->x < 0 && window->y < 0)
return FALSE;
if (impl->hint == GDK_WINDOW_TYPE_HINT_DND)
return FALSE;
return TRUE;
}
static gboolean
should_map_as_popup (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
/* Ideally, popup would be temp windows with a parent and grab */
if (GDK_WINDOW_TYPE (window) == GDK_WINDOW_TEMP)
{
/* If a temp window has a parent and a grab, we can use a popup */
if (impl->transient_for)
{
if (impl->grab_input_seat)
return TRUE;
}
else
g_message ("Window %p is a temporary window without parent, "
"application will not be able to position it on screen.",
window);
}
/* Yet we need to keep the window type hint tests for compatibility */
switch (impl->hint)
{
case GDK_WINDOW_TYPE_HINT_POPUP_MENU:
case GDK_WINDOW_TYPE_HINT_DROPDOWN_MENU:
case GDK_WINDOW_TYPE_HINT_COMBO:
return TRUE;
case GDK_WINDOW_TYPE_HINT_UTILITY:
if (GDK_WINDOW_TYPE (window) != GDK_WINDOW_TEMP)
return TRUE;
break;
default:
break;
}
return FALSE;
}
static gboolean
should_map_as_subsurface (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (GDK_WINDOW_TYPE (window) == GDK_WINDOW_SUBSURFACE)
return TRUE;
if (GDK_WINDOW_TYPE (window) != GDK_WINDOW_TEMP)
return FALSE;
/* if we want a popup, we do not want a subsurface */
if (should_map_as_popup (window))
return FALSE;
if (impl->transient_for)
{
GdkWindowImplWayland *impl_parent;
impl_parent = GDK_WINDOW_IMPL_WAYLAND (impl->transient_for->impl);
/* subsurface require that the parent is mapped */
if (impl_parent->mapped)
return TRUE;
else
g_warning ("Couldn't map window %p as susburface because its parent is not mapped.",
window);
}
return FALSE;
}
/* Get the window that can be used as a parent for a popup, i.e. a xdg_surface
* or xdg_popup. If the window is not, traverse up the transiency parents until
* we find one.
*/
static GdkWindow *
get_popup_parent (GdkWindow *window)
{
while (window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (impl->display_server.xdg_popup || impl->display_server.xdg_surface)
return window;
window = impl->transient_for;
}
return NULL;
}
static void
gdk_wayland_window_map (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWindow *transient_for = NULL;
if (!should_be_mapped (window))
return;
if (impl->mapped || impl->use_custom_surface)
return;
if (should_map_as_subsurface (window))
{
if (impl->transient_for)
gdk_wayland_window_create_subsurface (window);
else
g_warning ("Couldn't map window %p as susburface yet because it doesn't have a parent",
window);
}
else if (should_map_as_popup (window))
{
gboolean create_fallback = FALSE;
struct wl_seat *grab_input_seat;
/* Popup menus can appear without a transient parent, which means they
* cannot be positioned properly on Wayland. This attempts to guess the
* surface they should be positioned with by finding the surface beneath
* the device that created the grab for the popup window.
*/
if (!impl->transient_for && impl->hint == GDK_WINDOW_TYPE_HINT_POPUP_MENU)
{
GdkDevice *grab_device = NULL;
/* The popup menu window is not the grabbed window. This may mean
* that a "transfer window" (see gtkmenu.c) is used, and we need
* to find that window to get the grab device. If so is the case
* the "transfer window" can be retrieved via the
* "gdk-attached-grab-window" associated data field.
*/
if (!impl->grab_input_seat)
{
GdkWindow *attached_grab_window =
g_object_get_data (G_OBJECT (window),
"gdk-attached-grab-window");
if (attached_grab_window)
{
GdkWindowImplWayland *attached_impl =
GDK_WINDOW_IMPL_WAYLAND (attached_grab_window->impl);
grab_device = gdk_seat_get_pointer (attached_impl->grab_input_seat);
transient_for =
gdk_device_get_window_at_position (grab_device,
NULL, NULL);
}
}
else
{
grab_device = gdk_seat_get_pointer (impl->grab_input_seat);
transient_for =
gdk_device_get_window_at_position (grab_device, NULL, NULL);
}
if (transient_for)
transient_for = get_popup_parent (gdk_window_get_effective_toplevel (transient_for));
/* If the position was not explicitly set, start the popup at the
* position of the device that holds the grab.
*/
if (!impl->position_set && grab_device)
gdk_window_get_device_position (transient_for, grab_device,
&window->x, &window->y, NULL);
}
else
transient_for = get_popup_parent (impl->transient_for);
if (!transient_for)
{
g_warning ("Couldn't map as window %p as popup because it doesn't have a parent",
window);
create_fallback = TRUE;
}
else
{
grab_input_seat = find_grab_input_seat (window, transient_for);
if (!grab_input_seat)
{
g_warning ("No grabbed seat found, using the default one in "
"order to map popup window %p. You may find oddities "
"ahead, gdk_seat_grab() should be used to "
"simultaneously grab input and show this popup",
window);
grab_input_seat = find_default_input_seat (window);
}
}
if (!create_fallback)
{
gdk_wayland_window_create_xdg_popup (window,
transient_for,
grab_input_seat);
}
else
{
gdk_wayland_window_create_xdg_surface (window);
}
}
else
{
gdk_wayland_window_create_xdg_surface (window);
}
impl->mapped = TRUE;
}
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static void
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gdk_wayland_window_show (GdkWindow *window,
gboolean already_mapped)
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{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (!impl->display_server.wl_surface)
gdk_wayland_window_create_surface (window);
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gdk_wayland_window_map (window);
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_gdk_make_event (window, GDK_MAP, NULL, FALSE);
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
if (impl->staging_cairo_surface &&
_gdk_wayland_is_shm_surface (impl->staging_cairo_surface))
gdk_wayland_window_attach_image (window);
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}
static void
unmap_subsurface (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWindowImplWayland *parent_impl;
g_return_if_fail (impl->display_server.wl_subsurface);
g_return_if_fail (impl->transient_for);
parent_impl = GDK_WINDOW_IMPL_WAYLAND (impl->transient_for->impl);
wl_subsurface_destroy (impl->display_server.wl_subsurface);
g_signal_handlers_disconnect_by_func (parent_impl,
(gpointer) on_parent_surface_committed,
window);
impl->display_server.wl_subsurface = NULL;
}
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static void
gdk_wayland_window_hide_surface (GdkWindow *window)
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{
GdkWaylandDisplay *display_wayland = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
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GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (impl->display_server.wl_surface)
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{
if (impl->dummy_egl_surface)
{
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eglDestroySurface (display_wayland->egl_display, impl->dummy_egl_surface);
impl->dummy_egl_surface = NULL;
}
if (impl->display_server.dummy_egl_window)
{
wl_egl_window_destroy (impl->display_server.dummy_egl_window);
impl->display_server.dummy_egl_window = NULL;
}
if (impl->egl_surface)
{
2015-08-28 17:51:11 +00:00
eglDestroySurface (display_wayland->egl_display, impl->egl_surface);
impl->egl_surface = NULL;
}
if (impl->display_server.egl_window)
{
wl_egl_window_destroy (impl->display_server.egl_window);
impl->display_server.egl_window = NULL;
}
if (impl->display_server.xdg_surface)
{
xdg_surface_destroy (impl->display_server.xdg_surface);
impl->display_server.xdg_surface = NULL;
}
else if (impl->display_server.xdg_popup)
{
xdg_popup_destroy (impl->display_server.xdg_popup);
impl->display_server.xdg_popup = NULL;
}
if (impl->display_server.wl_subsurface)
unmap_subsurface (window);
if (impl->awaiting_frame)
{
GdkFrameClock *frame_clock;
impl->awaiting_frame = FALSE;
frame_clock = gdk_window_get_frame_clock (window);
if (frame_clock)
_gdk_frame_clock_thaw (frame_clock);
}
if (impl->display_server.gtk_surface)
{
gtk_surface1_destroy (impl->display_server.gtk_surface);
impl->display_server.gtk_surface = NULL;
}
wl_surface_destroy (impl->display_server.wl_surface);
impl->display_server.wl_surface = NULL;
g_slist_free (impl->display_server.outputs);
impl->display_server.outputs = NULL;
if (impl->hint == GDK_WINDOW_TYPE_HINT_DIALOG && !impl->transient_for)
orphan_dialogs = g_list_remove (orphan_dialogs, window);
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}
_gdk_wayland_window_clear_saved_size (window);
impl->pending_commit = FALSE;
impl->mapped = FALSE;
}
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static void
gdk_wayland_window_hide (GdkWindow *window)
{
gdk_wayland_window_hide_surface (window);
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_gdk_window_clear_update_area (window);
}
static void
gdk_window_wayland_withdraw (GdkWindow *window)
{
if (!window->destroyed)
{
if (GDK_WINDOW_IS_MAPPED (window))
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gdk_synthesize_window_state (window, 0, GDK_WINDOW_STATE_WITHDRAWN);
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g_assert (!GDK_WINDOW_IS_MAPPED (window));
gdk_wayland_window_hide_surface (window);
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}
}
static void
gdk_window_wayland_set_events (GdkWindow *window,
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GdkEventMask event_mask)
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{
GDK_WINDOW (window)->event_mask = event_mask;
}
static GdkEventMask
gdk_window_wayland_get_events (GdkWindow *window)
{
if (GDK_WINDOW_DESTROYED (window))
return 0;
else
return GDK_WINDOW (window)->event_mask;
}
static void
gdk_window_wayland_raise (GdkWindow *window)
{
}
static void
gdk_window_wayland_lower (GdkWindow *window)
{
}
static void
gdk_window_wayland_restack_under (GdkWindow *window,
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GList *native_siblings)
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{
}
static void
gdk_window_wayland_restack_toplevel (GdkWindow *window,
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GdkWindow *sibling,
gboolean above)
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{
}
static void
gdk_window_request_transient_parent_commit (GdkWindow *window)
{
GdkWindowImplWayland *window_impl, *impl;
GdkFrameClock *frame_clock;
window_impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (!window_impl->transient_for)
return;
impl = GDK_WINDOW_IMPL_WAYLAND (window_impl->transient_for->impl);
if (!impl->display_server.wl_surface || impl->pending_commit)
return;
frame_clock = gdk_window_get_frame_clock (window_impl->transient_for);
if (!frame_clock)
return;
impl->pending_commit = TRUE;
gdk_frame_clock_request_phase (frame_clock,
GDK_FRAME_CLOCK_PHASE_AFTER_PAINT);
}
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static void
gdk_window_wayland_move_resize (GdkWindow *window,
gboolean with_move,
gint x,
gint y,
gint width,
gint height)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (with_move)
{
/* Each toplevel has in its own "root" coordinate system */
if (GDK_WINDOW_TYPE (window) != GDK_WINDOW_TOPLEVEL)
{
window->x = x;
window->y = y;
impl->position_set = 1;
if (impl->display_server.wl_subsurface)
{
wl_subsurface_set_position (impl->display_server.wl_subsurface, x, y);
gdk_window_request_transient_parent_commit (window);
}
}
}
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/* If this function is called with width and height = -1 then that means
* just move the window - don't update its size
*/
if (width > 0 && height > 0)
gdk_wayland_window_configure (window, width, height, impl->scale);
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}
static void
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gdk_window_wayland_set_background (GdkWindow *window,
cairo_pattern_t *pattern)
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{
}
static gboolean
gdk_window_wayland_reparent (GdkWindow *window,
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GdkWindow *new_parent,
gint x,
gint y)
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{
return FALSE;
}
static void
gdk_window_wayland_set_device_cursor (GdkWindow *window,
2013-09-16 21:23:29 +00:00
GdkDevice *device,
GdkCursor *cursor)
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{
g_return_if_fail (GDK_IS_WINDOW (window));
g_return_if_fail (GDK_IS_DEVICE (device));
if (!GDK_WINDOW_DESTROYED (window))
GDK_DEVICE_GET_CLASS (device)->set_window_cursor (device, window, cursor);
}
static void
gdk_window_wayland_get_geometry (GdkWindow *window,
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gint *x,
gint *y,
gint *width,
gint *height)
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{
if (!GDK_WINDOW_DESTROYED (window))
{
if (x)
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*x = window->x;
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if (y)
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*y = window->y;
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if (width)
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*width = window->width;
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if (height)
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*height = window->height;
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}
}
static void
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gdk_window_wayland_get_root_coords (GdkWindow *window,
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gint x,
gint y,
gint *root_x,
gint *root_y)
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{
gint x_offset, y_offset;
gdk_wayland_window_get_fake_root_coords (window, &x_offset, &y_offset);
if (root_x)
*root_x = x_offset + x;
if (root_y)
*root_y = y_offset + y;
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}
static gboolean
gdk_window_wayland_get_device_state (GdkWindow *window,
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GdkDevice *device,
gdouble *x,
gdouble *y,
GdkModifierType *mask)
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{
gboolean return_val;
g_return_val_if_fail (window == NULL || GDK_IS_WINDOW (window), FALSE);
return_val = TRUE;
if (!GDK_WINDOW_DESTROYED (window))
{
GdkWindow *child;
GDK_DEVICE_GET_CLASS (device)->query_state (device, window,
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NULL, &child,
NULL, NULL,
x, y, mask);
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return_val = (child != NULL);
}
return return_val;
}
static void
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gdk_window_wayland_shape_combine_region (GdkWindow *window,
const cairo_region_t *shape_region,
gint offset_x,
gint offset_y)
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{
}
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static void
gdk_window_wayland_input_shape_combine_region (GdkWindow *window,
const cairo_region_t *shape_region,
gint offset_x,
gint offset_y)
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{
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GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (GDK_WINDOW_DESTROYED (window))
return;
g_clear_pointer (&impl->input_region, cairo_region_destroy);
if (shape_region)
{
impl->input_region = cairo_region_copy (shape_region);
cairo_region_translate (impl->input_region, offset_x, offset_y);
}
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gdk_wayland_window_sync_input_region (window);
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}
static void
gdk_wayland_window_destroy (GdkWindow *window,
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gboolean recursing,
gboolean foreign_destroy)
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{
g_return_if_fail (GDK_IS_WINDOW (window));
/* Wayland windows can't be externally destroyed; we may possibly
2013-09-16 21:23:29 +00:00
* eventually want to use this path at display close-down
*/
g_return_if_fail (!foreign_destroy);
gdk_wayland_window_hide_surface (window);
wayland: stage uncommitted changes to dedicated buffer Right now we use one buffer for both staged changes (freshly painted changes waiting for the frame clock to send to the compositor) and committed changes (changes actively being read by the compositor process). This creates a problem in the event we need to stage updates at the same time the compositor is processing committed updates: we can't change what the compositor is actively processing. The current solution for handling this contention is to allocate a temporary buffer on the spot at the time the updates are staged, and to copy that buffer back to the shared buffer later. The problem, though, is that the copy to the shared buffer currently happens as soon as the updates are finished being staged, not when the shared buffer is done being processed by the compositor. In order to address that problem, this commit changes the code to always stage changes to a dedicated staging buffer. The staging buffer is used exclusively by the client until the client is done with it, and then once that staging buffer is committed, the client never writes to that buffer again. If the client needs to stage new updates, it allocates a brand new staging buffer, draws to it, and back fills the undrawn parts of the buffer from a copy of the contents of the committed buffer. As an optimization, the compositor has the option of releasing the committed buffer back to the client. If it does so before the client needs to stage new updates, then the client will reuse the buffer for staging future updates. This optimization prevents having to allocate a new staging buffer and the associated cost of back filling that new buffer with a readback of the committed buffer. https://bugzilla.gnome.org/show_bug.cgi?id=761312
2016-01-29 16:19:03 +00:00
drop_cairo_surfaces (window);
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}
static void
gdk_window_wayland_destroy_foreign (GdkWindow *window)
{
}
static cairo_region_t *
gdk_wayland_window_get_shape (GdkWindow *window)
{
return NULL;
}
static cairo_region_t *
gdk_wayland_window_get_input_shape (GdkWindow *window)
{
return NULL;
}
static void
gdk_wayland_window_focus (GdkWindow *window,
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guint32 timestamp)
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{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (!impl->display_server.gtk_surface)
return;
/* We didn't have an event to fetch a time from, meaning we have nothing valid
* to send. This should rather be translated to a 'needs-attention' request or
* something.
*/
if (timestamp == GDK_CURRENT_TIME)
return;
gtk_surface1_present (impl->display_server.gtk_surface, timestamp);
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}
static void
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gdk_wayland_window_set_type_hint (GdkWindow *window,
GdkWindowTypeHint hint)
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{
GdkWindowImplWayland *impl;
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
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if (GDK_WINDOW_DESTROYED (window))
return;
impl->hint = hint;
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}
static GdkWindowTypeHint
gdk_wayland_window_get_type_hint (GdkWindow *window)
{
GdkWindowImplWayland *impl;
if (GDK_WINDOW_DESTROYED (window))
return GDK_WINDOW_TYPE_HINT_NORMAL;
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
return impl->hint;
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}
static void
gdk_wayland_window_init_gtk_surface (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWaylandDisplay *display =
GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
if (impl->display_server.gtk_surface != NULL)
return;
if (impl->display_server.xdg_surface == NULL)
return;
if (display->gtk_shell == NULL)
return;
impl->display_server.gtk_surface =
gtk_shell1_get_gtk_surface (display->gtk_shell,
impl->display_server.wl_surface);
}
static void
maybe_set_gtk_surface_modal (GdkWindow *window)
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{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
gdk_wayland_window_init_gtk_surface (window);
if (impl->display_server.gtk_surface == NULL)
return;
if (window->modal_hint)
gtk_surface1_set_modal (impl->display_server.gtk_surface);
else
gtk_surface1_unset_modal (impl->display_server.gtk_surface);
}
static void
gdk_wayland_window_set_modal_hint (GdkWindow *window,
gboolean modal)
{
window->modal_hint = modal;
maybe_set_gtk_surface_modal (window);
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}
static void
gdk_wayland_window_set_skip_taskbar_hint (GdkWindow *window,
2013-09-16 21:23:29 +00:00
gboolean skips_taskbar)
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{
}
static void
gdk_wayland_window_set_skip_pager_hint (GdkWindow *window,
2013-09-16 21:23:29 +00:00
gboolean skips_pager)
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{
}
static void
gdk_wayland_window_set_urgency_hint (GdkWindow *window,
2013-09-16 21:23:29 +00:00
gboolean urgent)
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{
}
static void
gdk_wayland_window_set_geometry_hints (GdkWindow *window,
2013-09-16 21:23:29 +00:00
const GdkGeometry *geometry,
GdkWindowHints geom_mask)
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{
GdkWindowImplWayland *impl;
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if (GDK_WINDOW_DESTROYED (window) ||
!WINDOW_IS_TOPLEVEL_OR_FOREIGN (window))
return;
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
impl->geometry_hints = *geometry;
impl->geometry_mask = geom_mask;
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}
static void
gdk_wayland_window_set_title (GdkWindow *window,
2013-09-16 21:23:29 +00:00
const gchar *title)
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{
GdkWindowImplWayland *impl;
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g_return_if_fail (title != NULL);
if (GDK_WINDOW_DESTROYED (window))
return;
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
g_free (impl->title);
impl->title = g_strdup (title);
gdk_wayland_window_sync_title (window);
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}
static void
gdk_wayland_window_set_role (GdkWindow *window,
2013-09-16 21:23:29 +00:00
const gchar *role)
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{
}
static void
gdk_wayland_window_set_startup_id (GdkWindow *window,
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const gchar *startup_id)
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{
}
static gboolean
check_transient_for_loop (GdkWindow *window,
GdkWindow *parent)
{
while (parent)
{
GdkWindowImplWayland *impl;
if (!GDK_IS_WINDOW_IMPL_WAYLAND(parent->impl))
return FALSE;
impl = GDK_WINDOW_IMPL_WAYLAND (parent->impl);
if (impl->transient_for == window)
return TRUE;
parent = impl->transient_for;
}
return FALSE;
}
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static void
gdk_wayland_window_set_transient_for (GdkWindow *window,
2013-09-16 21:23:29 +00:00
GdkWindow *parent)
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{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkWindow *previous_parent;
if (check_transient_for_loop (window, parent))
{
g_warning ("Setting %p transient for %p would create a loop", window, parent);
return;
}
if (impl->display_server.wl_subsurface)
unmap_subsurface (window);
previous_parent = impl->transient_for;
impl->transient_for = parent;
if (impl->hint == GDK_WINDOW_TYPE_HINT_DIALOG)
{
if (!parent)
_gdk_wayland_screen_add_orphan_dialog (window);
else if (!previous_parent)
orphan_dialogs = g_list_remove (orphan_dialogs, window);
}
gdk_wayland_window_sync_parent (window, NULL);
if (should_map_as_subsurface (window) &&
parent && gdk_window_is_visible (window))
gdk_wayland_window_create_subsurface (window);
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}
static void
gdk_wayland_window_get_frame_extents (GdkWindow *window,
2013-09-16 21:23:29 +00:00
GdkRectangle *rect)
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{
gdk_wayland_window_get_fake_root_coords (window, &rect->x, &rect->y);
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rect->width = window->width;
rect->height = window->height;
}
static void
gdk_wayland_window_set_override_redirect (GdkWindow *window,
2013-09-16 21:23:29 +00:00
gboolean override_redirect)
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{
}
static void
gdk_wayland_window_set_accept_focus (GdkWindow *window,
2013-09-16 21:23:29 +00:00
gboolean accept_focus)
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{
}
static void
gdk_wayland_window_set_focus_on_map (GdkWindow *window,
2013-09-16 21:23:29 +00:00
gboolean focus_on_map)
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{
}
static void
gdk_wayland_window_set_icon_list (GdkWindow *window,
2013-09-16 21:23:29 +00:00
GList *pixbufs)
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{
}
static void
gdk_wayland_window_set_icon_name (GdkWindow *window,
2013-09-16 21:23:29 +00:00
const gchar *name)
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{
if (GDK_WINDOW_DESTROYED (window))
return;
}
static void
gdk_wayland_window_iconify (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (GDK_WINDOW_DESTROYED (window) ||
!WINDOW_IS_TOPLEVEL_OR_FOREIGN (window))
return;
if (!impl->display_server.xdg_surface)
return;
xdg_surface_set_minimized (impl->display_server.xdg_surface);
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}
static void
gdk_wayland_window_deiconify (GdkWindow *window)
{
if (GDK_WINDOW_DESTROYED (window) ||
!WINDOW_IS_TOPLEVEL_OR_FOREIGN (window))
return;
if (GDK_WINDOW_IS_MAPPED (window))
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gdk_window_show (window);
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else
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/* Flip our client side flag, the real work happens on map. */
gdk_synthesize_window_state (window, GDK_WINDOW_STATE_ICONIFIED, 0);
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}
static void
gdk_wayland_window_stick (GdkWindow *window)
{
}
static void
gdk_wayland_window_unstick (GdkWindow *window)
{
}
static void
gdk_wayland_window_maximize (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (GDK_WINDOW_DESTROYED (window))
2010-12-18 20:38:49 +00:00
return;
_gdk_wayland_window_save_size (window);
if (impl->display_server.xdg_surface)
xdg_surface_set_maximized (impl->display_server.xdg_surface);
else
gdk_synthesize_window_state (window, 0, GDK_WINDOW_STATE_MAXIMIZED);
2010-12-18 20:38:49 +00:00
}
static void
gdk_wayland_window_unmaximize (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (GDK_WINDOW_DESTROYED (window))
2010-12-18 20:38:49 +00:00
return;
if (impl->display_server.xdg_surface)
xdg_surface_unset_maximized (impl->display_server.xdg_surface);
else
gdk_synthesize_window_state (window, GDK_WINDOW_STATE_MAXIMIZED, 0);
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}
static void
gdk_wayland_window_fullscreen_on_monitor (GdkWindow *window, gint monitor)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
GdkScreen *screen = gdk_window_get_screen (window);
struct wl_output *fullscreen_output =
_gdk_wayland_screen_get_wl_output (screen, monitor);
if (GDK_WINDOW_DESTROYED (window))
return;
_gdk_wayland_window_save_size (window);
if (impl->display_server.xdg_surface)
xdg_surface_set_fullscreen (impl->display_server.xdg_surface, fullscreen_output);
else {
gdk_synthesize_window_state (window, 0, GDK_WINDOW_STATE_FULLSCREEN);
impl->initial_fullscreen_monitor = monitor;
}
}
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static void
gdk_wayland_window_fullscreen (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
2010-12-18 20:38:49 +00:00
if (GDK_WINDOW_DESTROYED (window))
return;
impl->initial_fullscreen_monitor = -1;
_gdk_wayland_window_save_size (window);
if (impl->display_server.xdg_surface)
xdg_surface_set_fullscreen (impl->display_server.xdg_surface, NULL);
else
gdk_synthesize_window_state (window, 0, GDK_WINDOW_STATE_FULLSCREEN);
2010-12-18 20:38:49 +00:00
}
static void
gdk_wayland_window_unfullscreen (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
2010-12-18 20:38:49 +00:00
if (GDK_WINDOW_DESTROYED (window))
return;
impl->initial_fullscreen_monitor = -1;
if (impl->display_server.xdg_surface)
xdg_surface_unset_fullscreen (impl->display_server.xdg_surface);
else
gdk_synthesize_window_state (window, GDK_WINDOW_STATE_FULLSCREEN, 0);
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}
static void
gdk_wayland_window_set_keep_above (GdkWindow *window, gboolean setting)
2010-12-18 20:38:49 +00:00
{
}
static void
gdk_wayland_window_set_keep_below (GdkWindow *window, gboolean setting)
{
}
static GdkWindow *
gdk_wayland_window_get_group (GdkWindow *window)
{
return NULL;
}
static void
gdk_wayland_window_set_group (GdkWindow *window,
2013-09-16 21:23:29 +00:00
GdkWindow *leader)
2010-12-18 20:38:49 +00:00
{
}
static void
2013-09-16 21:23:29 +00:00
gdk_wayland_window_set_decorations (GdkWindow *window,
GdkWMDecoration decorations)
2010-12-18 20:38:49 +00:00
{
}
static gboolean
gdk_wayland_window_get_decorations (GdkWindow *window,
2013-09-16 21:23:29 +00:00
GdkWMDecoration *decorations)
2010-12-18 20:38:49 +00:00
{
return FALSE;
}
static void
2013-09-16 21:23:29 +00:00
gdk_wayland_window_set_functions (GdkWindow *window,
GdkWMFunction functions)
2010-12-18 20:38:49 +00:00
{
}
static void
gdk_wayland_window_begin_resize_drag (GdkWindow *window,
2013-09-16 21:23:29 +00:00
GdkWindowEdge edge,
GdkDevice *device,
2013-09-16 21:23:29 +00:00
gint button,
gint root_x,
gint root_y,
guint32 timestamp)
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{
GdkWindowImplWayland *impl;
GdkEventSequence *sequence;
uint32_t resize_edges, serial;
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if (GDK_WINDOW_DESTROYED (window) ||
!WINDOW_IS_TOPLEVEL_OR_FOREIGN (window))
return;
switch (edge)
{
case GDK_WINDOW_EDGE_NORTH_WEST:
2014-02-07 22:16:28 +00:00
resize_edges = XDG_SURFACE_RESIZE_EDGE_TOP_LEFT;
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break;
case GDK_WINDOW_EDGE_NORTH:
2014-02-07 22:16:28 +00:00
resize_edges = XDG_SURFACE_RESIZE_EDGE_TOP;
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break;
case GDK_WINDOW_EDGE_NORTH_EAST:
resize_edges = XDG_SURFACE_RESIZE_EDGE_TOP_RIGHT;
2010-12-18 20:38:49 +00:00
break;
case GDK_WINDOW_EDGE_WEST:
2014-02-07 22:16:28 +00:00
resize_edges = XDG_SURFACE_RESIZE_EDGE_LEFT;
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break;
case GDK_WINDOW_EDGE_EAST:
2014-02-07 22:16:28 +00:00
resize_edges = XDG_SURFACE_RESIZE_EDGE_RIGHT;
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break;
case GDK_WINDOW_EDGE_SOUTH_WEST:
2014-02-07 22:16:28 +00:00
resize_edges = XDG_SURFACE_RESIZE_EDGE_BOTTOM_LEFT;
2010-12-18 20:38:49 +00:00
break;
case GDK_WINDOW_EDGE_SOUTH:
2014-02-07 22:16:28 +00:00
resize_edges = XDG_SURFACE_RESIZE_EDGE_BOTTOM;
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break;
case GDK_WINDOW_EDGE_SOUTH_EAST:
2014-02-07 22:16:28 +00:00
resize_edges = XDG_SURFACE_RESIZE_EDGE_BOTTOM_RIGHT;
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break;
default:
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g_warning ("gdk_window_begin_resize_drag: bad resize edge %d!", edge);
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return;
}
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (!impl->display_server.xdg_surface)
return;
2013-09-16 21:23:29 +00:00
serial = _gdk_wayland_seat_get_last_implicit_grab_serial (gdk_device_get_seat (device),
&sequence);
xdg_surface_resize (impl->display_server.xdg_surface,
gdk_wayland_device_get_wl_seat (device),
serial, resize_edges);
if (sequence)
gdk_wayland_device_unset_touch_grab (device, sequence);
/* This is needed since Wayland will absorb all the pointer events after the
* above function - FIXME: Is this always safe..?
*/
gdk_seat_ungrab (gdk_device_get_seat (device));
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}
static void
gdk_wayland_window_begin_move_drag (GdkWindow *window,
GdkDevice *device,
2013-09-16 21:23:29 +00:00
gint button,
gint root_x,
gint root_y,
guint32 timestamp)
2010-12-18 20:38:49 +00:00
{
GdkWindowImplWayland *impl;
GdkEventSequence *sequence;
uint32_t serial;
2010-12-18 20:38:49 +00:00
if (GDK_WINDOW_DESTROYED (window) ||
!WINDOW_IS_TOPLEVEL (window))
return;
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (!impl->display_server.xdg_surface)
return;
serial = _gdk_wayland_seat_get_last_implicit_grab_serial (gdk_device_get_seat (device),
&sequence);
xdg_surface_move (impl->display_server.xdg_surface,
gdk_wayland_device_get_wl_seat (device),
serial);
if (sequence)
gdk_wayland_device_unset_touch_grab (device, sequence);
/* This is needed since Wayland will absorb all the pointer events after the
* above function - FIXME: Is this always safe..?
*/
gdk_seat_ungrab (gdk_device_get_seat (device));
2010-12-18 20:38:49 +00:00
}
static void
gdk_wayland_window_set_opacity (GdkWindow *window,
2013-09-16 21:23:29 +00:00
gdouble opacity)
2010-12-18 20:38:49 +00:00
{
}
static void
gdk_wayland_window_set_composited (GdkWindow *window,
2013-09-16 21:23:29 +00:00
gboolean composited)
2010-12-18 20:38:49 +00:00
{
}
static void
gdk_wayland_window_destroy_notify (GdkWindow *window)
{
if (!GDK_WINDOW_DESTROYED (window))
{
2013-09-16 21:23:29 +00:00
if (GDK_WINDOW_TYPE (window) != GDK_WINDOW_FOREIGN)
g_warning ("GdkWindow %p unexpectedly destroyed", window);
2010-12-18 20:38:49 +00:00
_gdk_window_destroy (window, TRUE);
}
g_object_unref (window);
}
static void
gdk_wayland_window_sync_rendering (GdkWindow *window)
{
}
static gboolean
2013-09-16 21:23:29 +00:00
gdk_wayland_window_simulate_key (GdkWindow *window,
gint x,
gint y,
guint keyval,
GdkModifierType modifiers,
GdkEventType key_pressrelease)
2010-12-18 20:38:49 +00:00
{
return FALSE;
}
static gboolean
2013-09-16 21:23:29 +00:00
gdk_wayland_window_simulate_button (GdkWindow *window,
gint x,
gint y,
guint button,
GdkModifierType modifiers,
GdkEventType button_pressrelease)
2010-12-18 20:38:49 +00:00
{
return FALSE;
}
static gboolean
gdk_wayland_window_get_property (GdkWindow *window,
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GdkAtom property,
GdkAtom type,
gulong offset,
gulong length,
gint pdelete,
GdkAtom *actual_property_type,
gint *actual_format_type,
gint *actual_length,
guchar **data)
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{
return FALSE;
}
static void
gdk_wayland_window_change_property (GdkWindow *window,
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GdkAtom property,
GdkAtom type,
gint format,
GdkPropMode mode,
const guchar *data,
gint nelements)
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{
if (property == gdk_atom_intern_static_string ("GDK_SELECTION"))
gdk_wayland_selection_store (window, type, mode, data, nelements * (format / 8));
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}
static void
gdk_wayland_window_delete_property (GdkWindow *window,
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GdkAtom property)
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{
}
static gint
gdk_wayland_window_get_scale_factor (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (GDK_WINDOW_DESTROYED (window))
return 1;
return impl->scale;
}
static void
gdk_wayland_window_set_opaque_region (GdkWindow *window,
cairo_region_t *region)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (GDK_WINDOW_DESTROYED (window))
return;
g_clear_pointer (&impl->opaque_region, cairo_region_destroy);
impl->opaque_region = cairo_region_reference (region);
gdk_wayland_window_sync_opaque_region (window);
}
static void
gdk_wayland_window_set_shadow_width (GdkWindow *window,
int left,
int right,
int top,
int bottom)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
gint new_width, new_height;
if (GDK_WINDOW_DESTROYED (window))
return;
/* Reconfigure window to keep the same window geometry */
new_width = window->width -
(impl->margin_left + impl->margin_right) + (left + right);
new_height = window->height -
(impl->margin_top + impl->margin_bottom) + (top + bottom);
gdk_wayland_window_configure (window, new_width, new_height, impl->scale);
impl->margin_left = left;
impl->margin_right = right;
impl->margin_top = top;
impl->margin_bottom = bottom;
gdk_wayland_window_sync_margin (window);
}
static gboolean
gdk_wayland_window_show_window_menu (GdkWindow *window,
GdkEvent *event)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
struct wl_seat *seat;
GdkWaylandDevice *device;
double x, y;
switch (event->type)
{
case GDK_BUTTON_PRESS:
case GDK_BUTTON_RELEASE:
case GDK_TOUCH_BEGIN:
case GDK_TOUCH_END:
break;
default:
return FALSE;
}
if (!impl->display_server.xdg_surface)
return FALSE;
device = GDK_WAYLAND_DEVICE (gdk_event_get_device (event));
seat = gdk_wayland_device_get_wl_seat (GDK_DEVICE (device));
gdk_event_get_coords (event, &x, &y);
xdg_surface_show_window_menu (impl->display_server.xdg_surface,
seat,
_gdk_wayland_device_get_implicit_grab_serial (device, event),
x, y);
return TRUE;
}
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static void
_gdk_window_impl_wayland_class_init (GdkWindowImplWaylandClass *klass)
{
GObjectClass *object_class = G_OBJECT_CLASS (klass);
GdkWindowImplClass *impl_class = GDK_WINDOW_IMPL_CLASS (klass);
object_class->finalize = gdk_window_impl_wayland_finalize;
impl_class->ref_cairo_surface = gdk_wayland_window_ref_cairo_surface;
impl_class->create_similar_image_surface = gdk_wayland_window_create_similar_image_surface;
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impl_class->show = gdk_wayland_window_show;
impl_class->hide = gdk_wayland_window_hide;
impl_class->withdraw = gdk_window_wayland_withdraw;
impl_class->set_events = gdk_window_wayland_set_events;
impl_class->get_events = gdk_window_wayland_get_events;
impl_class->raise = gdk_window_wayland_raise;
impl_class->lower = gdk_window_wayland_lower;
impl_class->restack_under = gdk_window_wayland_restack_under;
impl_class->restack_toplevel = gdk_window_wayland_restack_toplevel;
impl_class->move_resize = gdk_window_wayland_move_resize;
impl_class->set_background = gdk_window_wayland_set_background;
impl_class->reparent = gdk_window_wayland_reparent;
impl_class->set_device_cursor = gdk_window_wayland_set_device_cursor;
impl_class->get_geometry = gdk_window_wayland_get_geometry;
impl_class->get_root_coords = gdk_window_wayland_get_root_coords;
impl_class->get_device_state = gdk_window_wayland_get_device_state;
impl_class->shape_combine_region = gdk_window_wayland_shape_combine_region;
impl_class->input_shape_combine_region = gdk_window_wayland_input_shape_combine_region;
impl_class->destroy = gdk_wayland_window_destroy;
impl_class->destroy_foreign = gdk_window_wayland_destroy_foreign;
impl_class->get_shape = gdk_wayland_window_get_shape;
impl_class->get_input_shape = gdk_wayland_window_get_input_shape;
impl_class->begin_paint = gdk_window_impl_wayland_begin_paint;
impl_class->end_paint = gdk_window_impl_wayland_end_paint;
impl_class->beep = gdk_window_impl_wayland_beep;
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impl_class->focus = gdk_wayland_window_focus;
impl_class->set_type_hint = gdk_wayland_window_set_type_hint;
impl_class->get_type_hint = gdk_wayland_window_get_type_hint;
impl_class->set_modal_hint = gdk_wayland_window_set_modal_hint;
impl_class->set_skip_taskbar_hint = gdk_wayland_window_set_skip_taskbar_hint;
impl_class->set_skip_pager_hint = gdk_wayland_window_set_skip_pager_hint;
impl_class->set_urgency_hint = gdk_wayland_window_set_urgency_hint;
impl_class->set_geometry_hints = gdk_wayland_window_set_geometry_hints;
impl_class->set_title = gdk_wayland_window_set_title;
impl_class->set_role = gdk_wayland_window_set_role;
impl_class->set_startup_id = gdk_wayland_window_set_startup_id;
impl_class->set_transient_for = gdk_wayland_window_set_transient_for;
impl_class->get_frame_extents = gdk_wayland_window_get_frame_extents;
impl_class->set_override_redirect = gdk_wayland_window_set_override_redirect;
impl_class->set_accept_focus = gdk_wayland_window_set_accept_focus;
impl_class->set_focus_on_map = gdk_wayland_window_set_focus_on_map;
impl_class->set_icon_list = gdk_wayland_window_set_icon_list;
impl_class->set_icon_name = gdk_wayland_window_set_icon_name;
impl_class->iconify = gdk_wayland_window_iconify;
impl_class->deiconify = gdk_wayland_window_deiconify;
impl_class->stick = gdk_wayland_window_stick;
impl_class->unstick = gdk_wayland_window_unstick;
impl_class->maximize = gdk_wayland_window_maximize;
impl_class->unmaximize = gdk_wayland_window_unmaximize;
impl_class->fullscreen = gdk_wayland_window_fullscreen;
impl_class->fullscreen_on_monitor = gdk_wayland_window_fullscreen_on_monitor;
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impl_class->unfullscreen = gdk_wayland_window_unfullscreen;
impl_class->set_keep_above = gdk_wayland_window_set_keep_above;
impl_class->set_keep_below = gdk_wayland_window_set_keep_below;
impl_class->get_group = gdk_wayland_window_get_group;
impl_class->set_group = gdk_wayland_window_set_group;
impl_class->set_decorations = gdk_wayland_window_set_decorations;
impl_class->get_decorations = gdk_wayland_window_get_decorations;
impl_class->set_functions = gdk_wayland_window_set_functions;
impl_class->begin_resize_drag = gdk_wayland_window_begin_resize_drag;
impl_class->begin_move_drag = gdk_wayland_window_begin_move_drag;
impl_class->set_opacity = gdk_wayland_window_set_opacity;
impl_class->set_composited = gdk_wayland_window_set_composited;
impl_class->destroy_notify = gdk_wayland_window_destroy_notify;
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impl_class->get_drag_protocol = _gdk_wayland_window_get_drag_protocol;
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impl_class->register_dnd = _gdk_wayland_window_register_dnd;
impl_class->drag_begin = _gdk_wayland_window_drag_begin;
impl_class->sync_rendering = gdk_wayland_window_sync_rendering;
impl_class->simulate_key = gdk_wayland_window_simulate_key;
impl_class->simulate_button = gdk_wayland_window_simulate_button;
impl_class->get_property = gdk_wayland_window_get_property;
impl_class->change_property = gdk_wayland_window_change_property;
impl_class->delete_property = gdk_wayland_window_delete_property;
impl_class->get_scale_factor = gdk_wayland_window_get_scale_factor;
impl_class->set_opaque_region = gdk_wayland_window_set_opaque_region;
impl_class->set_shadow_width = gdk_wayland_window_set_shadow_width;
impl_class->show_window_menu = gdk_wayland_window_show_window_menu;
impl_class->create_gl_context = gdk_wayland_window_create_gl_context;
impl_class->invalidate_for_new_frame = gdk_wayland_window_invalidate_for_new_frame;
signals[COMMITTED] = g_signal_new ("committed",
G_TYPE_FROM_CLASS (object_class),
G_SIGNAL_RUN_LAST,
0,
NULL, NULL, NULL,
G_TYPE_NONE, 0);
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}
void
_gdk_wayland_window_set_grab_seat (GdkWindow *window,
GdkSeat *seat)
{
GdkWindowImplWayland *impl;
g_return_if_fail (window != NULL);
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
impl->grab_input_seat = seat;
}
/**
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* gdk_wayland_window_get_wl_surface:
* @window: (type GdkWaylandWindow): a #GdkWindow
*
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* Returns the Wayland surface of a #GdkWindow.
*
* Returns: (transfer none): a Wayland wl_surface
*
* Since: 3.8
*/
struct wl_surface *
gdk_wayland_window_get_wl_surface (GdkWindow *window)
{
g_return_val_if_fail (GDK_IS_WAYLAND_WINDOW (window), NULL);
return GDK_WINDOW_IMPL_WAYLAND (window->impl)->display_server.wl_surface;
}
static struct wl_egl_window *
gdk_wayland_window_get_wl_egl_window (GdkWindow *window)
{
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GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (impl->display_server.egl_window == NULL)
{
impl->display_server.egl_window =
wl_egl_window_create (impl->display_server.wl_surface,
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impl->wrapper->width * impl->scale,
impl->wrapper->height * impl->scale);
wl_surface_set_buffer_scale (impl->display_server.wl_surface, impl->scale);
}
return impl->display_server.egl_window;
}
EGLSurface
gdk_wayland_window_get_egl_surface (GdkWindow *window,
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EGLConfig config)
{
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GdkWaylandDisplay *display = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
GdkWindowImplWayland *impl;
struct wl_egl_window *egl_window;
g_return_val_if_fail (GDK_IS_WAYLAND_WINDOW (window), NULL);
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (impl->egl_surface == NULL)
{
egl_window = gdk_wayland_window_get_wl_egl_window (window);
impl->egl_surface =
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eglCreateWindowSurface (display->egl_display, config, egl_window, NULL);
}
return impl->egl_surface;
}
EGLSurface
gdk_wayland_window_get_dummy_egl_surface (GdkWindow *window,
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EGLConfig config)
{
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GdkWaylandDisplay *display = GDK_WAYLAND_DISPLAY (gdk_window_get_display (window));
GdkWindowImplWayland *impl;
g_return_val_if_fail (GDK_IS_WAYLAND_WINDOW (window), NULL);
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (impl->dummy_egl_surface == NULL)
{
impl->display_server.dummy_egl_window =
wl_egl_window_create (impl->display_server.wl_surface, 1, 1);
impl->dummy_egl_surface =
eglCreateWindowSurface (display->egl_display, config, impl->display_server.dummy_egl_window, NULL);
}
return impl->dummy_egl_surface;
}
/**
* gdk_wayland_window_set_use_custom_surface:
* @window: (type GdkWaylandWindow): a #GdkWindow
*
* Marks a #GdkWindow as a custom Wayland surface. The application is
* expected to register the surface as some type of surface using
* some Wayland interface.
*
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* A good example would be writing a panel or on-screen-keyboard as an
* out-of-process helper - as opposed to having those in the compositor
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* process. In this case the underlying surface isnt an xdg_shell
* surface and the panel or OSK client need to identify the wl_surface
* as a panel or OSK to the compositor. The assumption is that the
* compositor will expose a private interface to the special client
* that lets the client identify the wl_surface as a panel or such.
*
* This function should be called before a #GdkWindow is shown. This is
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* best done by connecting to the #GtkWidget::realize signal:
*
* |[<!-- language="C" -->
* static void
* widget_realize_cb (GtkWidget *widget)
* {
* GdkWindow *window;
* struct wl_surface *surface;
* struct input_panel_surface *ip_surface;
*
* window = gtk_widget_get_window (widget);
* gdk_wayland_window_set_custom_surface (window);
*
* surface = gdk_wayland_window_get_wl_surface (window);
* ip_surface = input_panel_get_input_panel_surface (input_panel, surface);
* input_panel_surface_set_panel (ip_surface);
* }
*
* static void
* setup_window (GtkWindow *window)
* {
* g_signal_connect (window, "realize", G_CALLBACK (widget_realize_cb), NULL);
* }
* ]|
*
* Since: 3.10
*/
void
gdk_wayland_window_set_use_custom_surface (GdkWindow *window)
{
GdkWindowImplWayland *impl;
g_return_if_fail (GDK_IS_WAYLAND_WINDOW (window));
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (!impl->display_server.wl_surface)
gdk_wayland_window_create_surface (window);
impl->use_custom_surface = TRUE;
}
static void
maybe_set_gtk_surface_dbus_properties (GdkWindow *window)
{
GdkWindowImplWayland *impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
if (impl->application.was_set)
return;
if (impl->application.application_id == NULL &&
impl->application.app_menu_path == NULL &&
impl->application.menubar_path == NULL &&
impl->application.window_object_path == NULL &&
impl->application.application_object_path == NULL &&
impl->application.unique_bus_name == NULL)
return;
gdk_wayland_window_init_gtk_surface (window);
if (impl->display_server.gtk_surface == NULL)
return;
gtk_surface1_set_dbus_properties (impl->display_server.gtk_surface,
impl->application.application_id,
impl->application.app_menu_path,
impl->application.menubar_path,
impl->application.window_object_path,
impl->application.application_object_path,
impl->application.unique_bus_name);
impl->application.was_set = TRUE;
}
void
gdk_wayland_window_set_dbus_properties_libgtk_only (GdkWindow *window,
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const char *application_id,
const char *app_menu_path,
const char *menubar_path,
const char *window_object_path,
const char *application_object_path,
const char *unique_bus_name)
{
GdkWindowImplWayland *impl;
g_return_if_fail (GDK_IS_WAYLAND_WINDOW (window));
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
impl->application.application_id = g_strdup (application_id);
impl->application.app_menu_path = g_strdup (app_menu_path);
impl->application.menubar_path = g_strdup (menubar_path);
impl->application.window_object_path = g_strdup (window_object_path);
impl->application.application_object_path =
g_strdup (application_object_path);
impl->application.unique_bus_name = g_strdup (unique_bus_name);
maybe_set_gtk_surface_dbus_properties (window);
}
void
_gdk_wayland_window_offset_next_wl_buffer (GdkWindow *window,
int x,
int y)
{
GdkWindowImplWayland *impl;
g_return_if_fail (GDK_IS_WAYLAND_WINDOW (window));
impl = GDK_WINDOW_IMPL_WAYLAND (window->impl);
impl->pending_buffer_offset_x = x;
impl->pending_buffer_offset_y = y;
}