mutter/src/wayland/meta-wayland-pointer.c

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/*
* Wayland Support
*
* Copyright (C) 2013 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
* License along with this library. If not, see <http://www.gnu.org/licenses/>.
*/
/*
* Copyright © 2008 Kristian Høgsberg
*
* Permission to use, copy, modify, distribute, and sell this software and its
* documentation for any purpose is hereby granted without fee, provided that
* the above copyright notice appear in all copies and that both that copyright
* notice and this permission notice appear in supporting documentation, and
* that the name of the copyright holders not be used in advertising or
* publicity pertaining to distribution of the software without specific,
* written prior permission. The copyright holders make no representations
* about the suitability of this software for any purpose. It is provided "as
* is" without express or implied warranty.
*
* THE COPYRIGHT HOLDERS DISCLAIM ALL WARRANTIES WITH REGARD TO THIS SOFTWARE,
* INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO
* EVENT SHALL THE COPYRIGHT HOLDERS BE LIABLE FOR ANY SPECIAL, INDIRECT OR
* CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE,
* DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
* TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE
* OF THIS SOFTWARE.
*/
/* The file is based on src/input.c from Weston */
#include "config.h"
#include <clutter/clutter.h>
#include <clutter/evdev/clutter-evdev.h>
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
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#include <cogl/cogl.h>
#include <cogl/cogl-wayland-server.h>
#include <linux/input.h>
#include "meta-wayland-pointer.h"
#include "meta-wayland-popup.h"
#include "meta-wayland-private.h"
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
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#include "meta-wayland-surface.h"
#include "meta-wayland-buffer.h"
#include "meta-wayland-surface-role-cursor.h"
#include "meta-xwayland.h"
#include "meta-cursor.h"
#include "meta-cursor-tracker-private.h"
#include "meta-surface-actor-wayland.h"
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
#include "meta/meta-cursor-tracker.h"
#include "backends/meta-backend-private.h"
#include "backends/meta-cursor-tracker-private.h"
#include "backends/meta-cursor-renderer.h"
#include "relative-pointer-unstable-v1-server-protocol.h"
#ifdef HAVE_NATIVE_BACKEND
#include "backends/native/meta-backend-native.h"
#endif
#include <string.h>
#define DEFAULT_AXIS_STEP_DISTANCE wl_fixed_from_int (10)
static MetaWaylandPointerClient *
meta_wayland_pointer_client_new (void)
{
MetaWaylandPointerClient *pointer_client;
pointer_client = g_slice_new0 (MetaWaylandPointerClient);
wl_list_init (&pointer_client->pointer_resources);
wl_list_init (&pointer_client->swipe_gesture_resources);
wl_list_init (&pointer_client->pinch_gesture_resources);
wl_list_init (&pointer_client->relative_pointer_resources);
return pointer_client;
}
static void
meta_wayland_pointer_client_free (MetaWaylandPointerClient *pointer_client)
{
struct wl_resource *resource, *next;
/* Since we make every wl_pointer resource defunct when we stop advertising
* the pointer capability on the wl_seat, we need to make sure all the
* resources in the pointer client instance gets removed.
*/
wl_resource_for_each_safe (resource, next, &pointer_client->pointer_resources)
{
wl_list_remove (wl_resource_get_link (resource));
wl_list_init (wl_resource_get_link (resource));
}
wl_resource_for_each_safe (resource, next, &pointer_client->swipe_gesture_resources)
{
wl_list_remove (wl_resource_get_link (resource));
wl_list_init (wl_resource_get_link (resource));
}
wl_resource_for_each_safe (resource, next, &pointer_client->pinch_gesture_resources)
{
wl_list_remove (wl_resource_get_link (resource));
wl_list_init (wl_resource_get_link (resource));
}
wl_resource_for_each_safe (resource, next, &pointer_client->relative_pointer_resources)
{
wl_list_remove (wl_resource_get_link (resource));
wl_list_init (wl_resource_get_link (resource));
}
g_slice_free (MetaWaylandPointerClient, pointer_client);
}
static gboolean
meta_wayland_pointer_client_is_empty (MetaWaylandPointerClient *pointer_client)
{
return (wl_list_empty (&pointer_client->pointer_resources) &&
wl_list_empty (&pointer_client->swipe_gesture_resources) &&
wl_list_empty (&pointer_client->pinch_gesture_resources) &&
wl_list_empty (&pointer_client->relative_pointer_resources));
}
MetaWaylandPointerClient *
meta_wayland_pointer_get_pointer_client (MetaWaylandPointer *pointer,
struct wl_client *client)
{
if (!pointer->pointer_clients)
return NULL;
return g_hash_table_lookup (pointer->pointer_clients, client);
}
static MetaWaylandPointerClient *
meta_wayland_pointer_ensure_pointer_client (MetaWaylandPointer *pointer,
struct wl_client *client)
{
MetaWaylandPointerClient *pointer_client;
pointer_client = meta_wayland_pointer_get_pointer_client (pointer, client);
if (pointer_client)
return pointer_client;
pointer_client = meta_wayland_pointer_client_new ();
g_hash_table_insert (pointer->pointer_clients, client, pointer_client);
if (!pointer->focus_client &&
pointer->focus_surface &&
wl_resource_get_client (pointer->focus_surface->resource) == client)
pointer->focus_client = pointer_client;
return pointer_client;
}
static void
meta_wayland_pointer_cleanup_pointer_client (MetaWaylandPointer *pointer,
MetaWaylandPointerClient *pointer_client,
struct wl_client *client)
{
if (meta_wayland_pointer_client_is_empty (pointer_client))
{
if (pointer->focus_client == pointer_client)
pointer->focus_client = NULL;
g_hash_table_remove (pointer->pointer_clients, client);
}
}
void
meta_wayland_pointer_unbind_pointer_client_resource (struct wl_resource *resource)
{
MetaWaylandPointer *pointer = wl_resource_get_user_data (resource);
MetaWaylandPointerClient *pointer_client;
struct wl_client *client = wl_resource_get_client (resource);
wl_list_remove (wl_resource_get_link (resource));
pointer_client = meta_wayland_pointer_get_pointer_client (pointer, client);
if (!pointer_client)
{
/* This happens if all pointer devices were unplugged and no new resources
* were created by the client.
*
* If this is a resource that was previously made defunct, pointer_client
* be non-NULL but it is harmless since the below cleanup call will be
* prevented from removing the pointer client because of valid resources.
*/
return;
}
meta_wayland_pointer_cleanup_pointer_client (pointer,
pointer_client,
client);
}
static void
sync_focus_surface (MetaWaylandPointer *pointer)
{
MetaDisplay *display = meta_get_display ();
switch (display->event_route)
{
case META_EVENT_ROUTE_WINDOW_OP:
case META_EVENT_ROUTE_COMPOSITOR_GRAB:
case META_EVENT_ROUTE_FRAME_BUTTON:
/* The compositor has a grab, so remove our focus... */
meta_wayland_pointer_set_focus (pointer, NULL);
break;
case META_EVENT_ROUTE_NORMAL:
case META_EVENT_ROUTE_WAYLAND_POPUP:
{
const MetaWaylandPointerGrabInterface *interface = pointer->grab->interface;
interface->focus (pointer->grab, pointer->current);
}
break;
default:
g_assert_not_reached ();
}
}
static void
pointer_handle_focus_surface_destroy (struct wl_listener *listener, void *data)
{
MetaWaylandPointer *pointer = wl_container_of (listener, pointer, focus_surface_listener);
meta_wayland_pointer_set_focus (pointer, NULL);
}
static void
meta_wayland_pointer_send_frame (MetaWaylandPointer *pointer,
struct wl_resource *resource)
{
if (wl_resource_get_version (resource) >= WL_POINTER_AXIS_SOURCE_SINCE_VERSION)
wl_pointer_send_frame (resource);
}
void
meta_wayland_pointer_broadcast_frame (MetaWaylandPointer *pointer)
{
struct wl_resource *resource;
if (!pointer->focus_client)
return;
wl_resource_for_each (resource, &pointer->focus_client->pointer_resources)
{
meta_wayland_pointer_send_frame (pointer, resource);
}
}
void
meta_wayland_pointer_send_relative_motion (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
struct wl_resource *resource;
double dx, dy;
double dx_unaccel, dy_unaccel;
uint64_t time_us;
uint32_t time_us_hi;
uint32_t time_us_lo;
wl_fixed_t dxf, dyf;
wl_fixed_t dx_unaccelf, dy_unaccelf;
if (!pointer->focus_client)
return;
if (!meta_backend_get_relative_motion_deltas (meta_get_backend (),
event,
&dx, &dy,
&dx_unaccel, &dy_unaccel))
return;
#ifdef HAVE_NATIVE_BACKEND
time_us = clutter_evdev_event_get_time_usec (event);
if (time_us == 0)
#endif
time_us = clutter_event_get_time (event) * 1000ULL;
time_us_hi = (uint32_t) (time_us >> 32);
time_us_lo = (uint32_t) time_us;
dxf = wl_fixed_from_double (dx);
dyf = wl_fixed_from_double (dy);
dx_unaccelf = wl_fixed_from_double (dx_unaccel);
dy_unaccelf = wl_fixed_from_double (dy_unaccel);
wl_resource_for_each (resource,
&pointer->focus_client->relative_pointer_resources)
{
zwp_relative_pointer_v1_send_relative_motion (resource,
time_us_hi,
time_us_lo,
dxf,
dyf,
dx_unaccelf,
dy_unaccelf);
}
}
void
meta_wayland_pointer_send_motion (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
struct wl_resource *resource;
uint32_t time;
float sx, sy;
if (!pointer->focus_client)
return;
time = clutter_event_get_time (event);
meta_wayland_surface_get_relative_coordinates (pointer->focus_surface,
event->motion.x,
event->motion.y,
&sx, &sy);
wl_resource_for_each (resource, &pointer->focus_client->pointer_resources)
{
wl_pointer_send_motion (resource, time,
wl_fixed_from_double (sx),
wl_fixed_from_double (sy));
}
meta_wayland_pointer_send_relative_motion (pointer, event);
meta_wayland_pointer_broadcast_frame (pointer);
}
void
meta_wayland_pointer_send_button (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
struct wl_resource *resource;
ClutterEventType event_type;
event_type = clutter_event_type (event);
if (pointer->focus_client &&
!wl_list_empty (&pointer->focus_client->pointer_resources))
{
struct wl_client *client = wl_resource_get_client (pointer->focus_surface->resource);
struct wl_display *display = wl_client_get_display (client);
uint32_t time;
uint32_t button;
uint32_t serial;
#ifdef HAVE_NATIVE_BACKEND
MetaBackend *backend = meta_get_backend ();
if (META_IS_BACKEND_NATIVE (backend))
button = clutter_evdev_event_get_event_code (event);
else
#endif
{
button = clutter_event_get_button (event);
switch (button)
{
case 1:
button = BTN_LEFT;
break;
/* The evdev input right and middle button numbers are swapped
relative to how Clutter numbers them */
case 2:
button = BTN_MIDDLE;
break;
case 3:
button = BTN_RIGHT;
break;
default:
button = button + (BTN_LEFT - 1) + 4;
break;
}
}
time = clutter_event_get_time (event);
serial = wl_display_next_serial (display);
wl_resource_for_each (resource, &pointer->focus_client->pointer_resources)
{
wl_pointer_send_button (resource, serial,
time, button,
event_type == CLUTTER_BUTTON_PRESS ? 1 : 0);
}
meta_wayland_pointer_broadcast_frame (pointer);
}
if (pointer->button_count == 0 && event_type == CLUTTER_BUTTON_RELEASE)
sync_focus_surface (pointer);
}
static void
default_grab_focus (MetaWaylandPointerGrab *grab,
MetaWaylandSurface *surface)
{
MetaWaylandPointer *pointer = grab->pointer;
if (pointer->button_count > 0)
return;
meta_wayland_pointer_set_focus (pointer, surface);
}
static void
default_grab_motion (MetaWaylandPointerGrab *grab,
const ClutterEvent *event)
{
MetaWaylandPointer *pointer = grab->pointer;
meta_wayland_pointer_send_motion (pointer, event);
}
static void
default_grab_button (MetaWaylandPointerGrab *grab,
const ClutterEvent *event)
{
MetaWaylandPointer *pointer = grab->pointer;
meta_wayland_pointer_send_button (pointer, event);
}
static const MetaWaylandPointerGrabInterface default_pointer_grab_interface = {
default_grab_focus,
default_grab_motion,
default_grab_button
};
static void
meta_wayland_pointer_on_cursor_changed (MetaCursorTracker *cursor_tracker,
MetaWaylandPointer *pointer)
{
if (pointer->cursor_surface)
meta_wayland_surface_update_outputs (pointer->cursor_surface);
}
void
meta_wayland_pointer_init (MetaWaylandPointer *pointer,
struct wl_display *display)
{
MetaCursorTracker *cursor_tracker = meta_cursor_tracker_get_for_screen (NULL);
ClutterDeviceManager *manager;
memset (pointer, 0, sizeof *pointer);
pointer->display = display;
pointer->pointer_clients =
g_hash_table_new_full (NULL, NULL, NULL,
(GDestroyNotify) meta_wayland_pointer_client_free);
pointer->focus_surface_listener.notify = pointer_handle_focus_surface_destroy;
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pointer->cursor_surface = NULL;
pointer->default_grab.interface = &default_pointer_grab_interface;
pointer->default_grab.pointer = pointer;
pointer->grab = &pointer->default_grab;
manager = clutter_device_manager_get_default ();
pointer->device = clutter_device_manager_get_core_device (manager, CLUTTER_POINTER_DEVICE);
g_signal_connect (cursor_tracker,
"cursor-changed",
G_CALLBACK (meta_wayland_pointer_on_cursor_changed),
pointer);
}
void
meta_wayland_pointer_release (MetaWaylandPointer *pointer)
{
MetaCursorTracker *cursor_tracker = meta_cursor_tracker_get_for_screen (NULL);
g_signal_handlers_disconnect_by_func (cursor_tracker,
(gpointer) meta_wayland_pointer_on_cursor_changed,
pointer);
if (pointer->cursor_surface && pointer->cursor_surface_destroy_id)
{
g_signal_handler_disconnect (pointer->cursor_surface,
pointer->cursor_surface_destroy_id);
}
meta_wayland_pointer_set_focus (pointer, NULL);
g_clear_pointer (&pointer->pointer_clients, g_hash_table_unref);
pointer->display = NULL;
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
pointer->cursor_surface = NULL;
}
static int
count_buttons (const ClutterEvent *event)
{
static gint maskmap[5] =
{
CLUTTER_BUTTON1_MASK, CLUTTER_BUTTON2_MASK, CLUTTER_BUTTON3_MASK,
CLUTTER_BUTTON4_MASK, CLUTTER_BUTTON5_MASK
};
ClutterModifierType mod_mask;
int i, count;
mod_mask = clutter_event_get_state (event);
count = 0;
for (i = 0; i < 5; i++)
{
if (mod_mask & maskmap[i])
count++;
}
return count;
}
static void
repick_for_event (MetaWaylandPointer *pointer,
const ClutterEvent *for_event)
{
ClutterActor *actor;
if (for_event)
actor = clutter_event_get_source (for_event);
else
actor = clutter_input_device_get_pointer_actor (pointer->device);
if (META_IS_SURFACE_ACTOR_WAYLAND (actor))
pointer->current = meta_surface_actor_wayland_get_surface (META_SURFACE_ACTOR_WAYLAND (actor));
else
pointer->current = NULL;
sync_focus_surface (pointer);
meta_wayland_pointer_update_cursor_surface (pointer);
}
void
meta_wayland_pointer_update (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
repick_for_event (pointer, event);
pointer->button_count = count_buttons (event);
}
static void
notify_motion (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
pointer->grab->interface->motion (pointer->grab, event);
}
static void
handle_motion_event (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
notify_motion (pointer, event);
}
static void
handle_button_event (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
gboolean implicit_grab;
implicit_grab = (event->type == CLUTTER_BUTTON_PRESS) && (pointer->button_count == 1);
if (implicit_grab)
{
pointer->grab_button = clutter_event_get_button (event);
pointer->grab_time = clutter_event_get_time (event);
clutter_event_get_coords (event, &pointer->grab_x, &pointer->grab_y);
}
pointer->grab->interface->button (pointer->grab, event);
if (implicit_grab)
pointer->grab_serial = wl_display_get_serial (pointer->display);
}
static void
handle_scroll_event (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
struct wl_resource *resource;
wl_fixed_t x_value = 0, y_value = 0;
int x_discrete = 0, y_discrete = 0;
enum wl_pointer_axis_source source = -1;
if (clutter_event_is_pointer_emulated (event))
return;
switch (event->scroll.scroll_source)
{
case CLUTTER_SCROLL_SOURCE_WHEEL:
source = WL_POINTER_AXIS_SOURCE_WHEEL;
break;
case CLUTTER_SCROLL_SOURCE_FINGER:
source = WL_POINTER_AXIS_SOURCE_FINGER;
break;
case CLUTTER_SCROLL_SOURCE_CONTINUOUS:
source = WL_POINTER_AXIS_SOURCE_CONTINUOUS;
break;
default:
source = WL_POINTER_AXIS_SOURCE_WHEEL;
break;
}
switch (clutter_event_get_scroll_direction (event))
{
case CLUTTER_SCROLL_UP:
y_value = -DEFAULT_AXIS_STEP_DISTANCE;
y_discrete = -1;
break;
case CLUTTER_SCROLL_DOWN:
y_value = DEFAULT_AXIS_STEP_DISTANCE;
y_discrete = 1;
break;
case CLUTTER_SCROLL_LEFT:
x_value = -DEFAULT_AXIS_STEP_DISTANCE;
x_discrete = -1;
break;
case CLUTTER_SCROLL_RIGHT:
x_value = DEFAULT_AXIS_STEP_DISTANCE;
x_discrete = 1;
break;
case CLUTTER_SCROLL_SMOOTH:
{
double dx, dy;
/* Clutter smooth scroll events are in discrete steps (1 step = 1.0 long
* vector along one axis). To convert to smooth scroll events that are
* in pointer motion event space, multiply the vector with the 10. */
const double factor = 10.0;
clutter_event_get_scroll_delta (event, &dx, &dy);
x_value = wl_fixed_from_double (dx) * factor;
y_value = wl_fixed_from_double (dy) * factor;
}
break;
default:
return;
}
if (pointer->focus_client)
{
wl_resource_for_each (resource, &pointer->focus_client->pointer_resources)
{
if (wl_resource_get_version (resource) >= WL_POINTER_AXIS_SOURCE_SINCE_VERSION)
wl_pointer_send_axis_source (resource, source);
/* X axis */
if (x_discrete != 0 &&
wl_resource_get_version (resource) >= WL_POINTER_AXIS_DISCRETE_SINCE_VERSION)
wl_pointer_send_axis_discrete (resource,
WL_POINTER_AXIS_HORIZONTAL_SCROLL,
x_discrete);
if (x_value)
wl_pointer_send_axis (resource, clutter_event_get_time (event),
WL_POINTER_AXIS_HORIZONTAL_SCROLL, x_value);
if ((event->scroll.finish_flags & CLUTTER_SCROLL_FINISHED_HORIZONTAL) &&
wl_resource_get_version (resource) >= WL_POINTER_AXIS_STOP_SINCE_VERSION)
wl_pointer_send_axis_stop (resource,
clutter_event_get_time (event),
WL_POINTER_AXIS_HORIZONTAL_SCROLL);
/* Y axis */
if (y_discrete != 0 &&
wl_resource_get_version (resource) >= WL_POINTER_AXIS_DISCRETE_SINCE_VERSION)
wl_pointer_send_axis_discrete (resource,
WL_POINTER_AXIS_VERTICAL_SCROLL,
y_discrete);
if (y_value)
wl_pointer_send_axis (resource, clutter_event_get_time (event),
WL_POINTER_AXIS_VERTICAL_SCROLL, y_value);
if ((event->scroll.finish_flags & CLUTTER_SCROLL_FINISHED_VERTICAL) &&
wl_resource_get_version (resource) >= WL_POINTER_AXIS_STOP_SINCE_VERSION)
wl_pointer_send_axis_stop (resource,
clutter_event_get_time (event),
WL_POINTER_AXIS_VERTICAL_SCROLL);
}
meta_wayland_pointer_broadcast_frame (pointer);
}
}
gboolean
meta_wayland_pointer_handle_event (MetaWaylandPointer *pointer,
const ClutterEvent *event)
{
switch (event->type)
{
case CLUTTER_MOTION:
handle_motion_event (pointer, event);
break;
case CLUTTER_BUTTON_PRESS:
case CLUTTER_BUTTON_RELEASE:
handle_button_event (pointer, event);
break;
case CLUTTER_SCROLL:
handle_scroll_event (pointer, event);
break;
case CLUTTER_TOUCHPAD_SWIPE:
meta_wayland_pointer_gesture_swipe_handle_event (pointer, event);
break;
case CLUTTER_TOUCHPAD_PINCH:
meta_wayland_pointer_gesture_pinch_handle_event (pointer, event);
break;
default:
break;
}
return FALSE;
}
static void
meta_wayland_pointer_send_enter (MetaWaylandPointer *pointer,
struct wl_resource *pointer_resource,
uint32_t serial,
MetaWaylandSurface *surface)
{
wl_fixed_t sx, sy;
meta_wayland_pointer_get_relative_coordinates (pointer, surface, &sx, &sy);
wl_pointer_send_enter (pointer_resource,
serial,
surface->resource,
sx, sy);
}
static void
meta_wayland_pointer_send_leave (MetaWaylandPointer *pointer,
struct wl_resource *pointer_resource,
uint32_t serial,
MetaWaylandSurface *surface)
{
wl_pointer_send_leave (pointer_resource, serial, surface->resource);
}
static void
meta_wayland_pointer_broadcast_enter (MetaWaylandPointer *pointer,
uint32_t serial,
MetaWaylandSurface *surface)
{
struct wl_resource *pointer_resource;
wl_resource_for_each (pointer_resource,
&pointer->focus_client->pointer_resources)
meta_wayland_pointer_send_enter (pointer, pointer_resource,
serial, surface);
meta_wayland_pointer_broadcast_frame (pointer);
}
static void
meta_wayland_pointer_broadcast_leave (MetaWaylandPointer *pointer,
uint32_t serial,
MetaWaylandSurface *surface)
{
struct wl_resource *pointer_resource;
wl_resource_for_each (pointer_resource,
&pointer->focus_client->pointer_resources)
meta_wayland_pointer_send_leave (pointer, pointer_resource,
serial, surface);
meta_wayland_pointer_broadcast_frame (pointer);
}
void
meta_wayland_pointer_set_focus (MetaWaylandPointer *pointer,
MetaWaylandSurface *surface)
{
if (pointer->display == NULL)
return;
if (pointer->focus_surface == surface)
return;
if (pointer->focus_surface != NULL)
{
struct wl_client *client =
wl_resource_get_client (pointer->focus_surface->resource);
struct wl_display *display = wl_client_get_display (client);
uint32_t serial;
serial = wl_display_next_serial (display);
if (pointer->focus_client)
{
meta_wayland_pointer_broadcast_leave (pointer,
serial,
pointer->focus_surface);
pointer->focus_client = NULL;
}
wl_list_remove (&pointer->focus_surface_listener.link);
pointer->focus_surface = NULL;
}
if (surface != NULL)
{
struct wl_client *client = wl_resource_get_client (surface->resource);
struct wl_display *display = wl_client_get_display (client);
ClutterPoint pos;
pointer->focus_surface = surface;
wl_resource_add_destroy_listener (pointer->focus_surface->resource, &pointer->focus_surface_listener);
clutter_input_device_get_coords (pointer->device, NULL, &pos);
if (pointer->focus_surface->window)
meta_window_handle_enter (pointer->focus_surface->window,
/* XXX -- can we reliably get a timestamp for setting focus? */
clutter_get_current_event_time (),
pos.x, pos.y);
pointer->focus_client =
meta_wayland_pointer_get_pointer_client (pointer, client);
if (pointer->focus_client)
{
pointer->focus_serial = wl_display_next_serial (display);
meta_wayland_pointer_broadcast_enter (pointer,
pointer->focus_serial,
pointer->focus_surface);
}
}
meta_wayland_pointer_update_cursor_surface (pointer);
}
void
meta_wayland_pointer_start_grab (MetaWaylandPointer *pointer,
MetaWaylandPointerGrab *grab)
{
const MetaWaylandPointerGrabInterface *interface;
pointer->grab = grab;
interface = pointer->grab->interface;
grab->pointer = pointer;
interface->focus (pointer->grab, pointer->current);
}
void
meta_wayland_pointer_end_grab (MetaWaylandPointer *pointer)
{
const MetaWaylandPointerGrabInterface *interface;
pointer->grab = &pointer->default_grab;
interface = pointer->grab->interface;
interface->focus (pointer->grab, pointer->current);
meta_wayland_pointer_update_cursor_surface (pointer);
}
void
meta_wayland_pointer_end_popup_grab (MetaWaylandPointer *pointer)
{
MetaWaylandPopupGrab *popup_grab = (MetaWaylandPopupGrab*)pointer->grab;
meta_wayland_popup_grab_destroy (popup_grab);
}
MetaWaylandPopup *
meta_wayland_pointer_start_popup_grab (MetaWaylandPointer *pointer,
MetaWaylandPopupSurface *popup_surface)
{
MetaWaylandPopupGrab *grab;
if (pointer->grab != &pointer->default_grab &&
!meta_wayland_pointer_grab_is_popup_grab (pointer->grab))
return NULL;
if (pointer->grab == &pointer->default_grab)
grab = meta_wayland_popup_grab_create (pointer, popup_surface);
else
grab = (MetaWaylandPopupGrab*)pointer->grab;
return meta_wayland_popup_create (popup_surface, grab);
}
void
meta_wayland_pointer_repick (MetaWaylandPointer *pointer)
{
repick_for_event (pointer, NULL);
}
void
meta_wayland_pointer_get_relative_coordinates (MetaWaylandPointer *pointer,
MetaWaylandSurface *surface,
wl_fixed_t *sx,
wl_fixed_t *sy)
{
float xf = 0.0f, yf = 0.0f;
ClutterPoint pos;
clutter_input_device_get_coords (pointer->device, NULL, &pos);
meta_wayland_surface_get_relative_coordinates (surface, pos.x, pos.y, &xf, &yf);
*sx = wl_fixed_from_double (xf);
*sy = wl_fixed_from_double (yf);
}
void
meta_wayland_pointer_update_cursor_surface (MetaWaylandPointer *pointer)
{
MetaCursorTracker *cursor_tracker = meta_cursor_tracker_get_for_screen (NULL);
if (pointer->current)
{
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
MetaCursorSprite *cursor_sprite = NULL;
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
if (pointer->cursor_surface)
{
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
MetaWaylandSurfaceRoleCursor *cursor_role =
META_WAYLAND_SURFACE_ROLE_CURSOR (pointer->cursor_surface->role);
cursor_sprite = meta_wayland_surface_role_cursor_get_sprite (cursor_role);
}
meta_cursor_tracker_set_window_cursor (cursor_tracker, cursor_sprite);
}
else
{
meta_cursor_tracker_unset_window_cursor (cursor_tracker);
}
}
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
static void
ensure_update_cursor_surface (MetaWaylandPointer *pointer,
MetaWaylandSurface *surface)
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
{
if (pointer->cursor_surface != surface)
return;
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
pointer->cursor_surface = NULL;
meta_wayland_pointer_update_cursor_surface (pointer);
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
}
static void
meta_wayland_pointer_set_cursor_surface (MetaWaylandPointer *pointer,
MetaWaylandSurface *cursor_surface)
{
MetaWaylandSurface *prev_cursor_surface;
prev_cursor_surface = pointer->cursor_surface;
if (prev_cursor_surface == cursor_surface)
return;
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
pointer->cursor_surface = cursor_surface;
if (prev_cursor_surface)
{
meta_wayland_surface_update_outputs (prev_cursor_surface);
g_signal_handler_disconnect (prev_cursor_surface,
pointer->cursor_surface_destroy_id);
}
if (cursor_surface)
{
pointer->cursor_surface_destroy_id =
g_signal_connect_swapped (cursor_surface, "destroy",
G_CALLBACK (ensure_update_cursor_surface),
pointer);
}
meta_wayland_pointer_update_cursor_surface (pointer);
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
}
static void
pointer_set_cursor (struct wl_client *client,
struct wl_resource *resource,
uint32_t serial,
struct wl_resource *surface_resource,
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
int32_t hot_x, int32_t hot_y)
{
MetaWaylandPointer *pointer = wl_resource_get_user_data (resource);
MetaWaylandSurface *surface;
surface = (surface_resource ? wl_resource_get_user_data (surface_resource) : NULL);
if (pointer->focus_surface == NULL)
return;
if (wl_resource_get_client (pointer->focus_surface->resource) != client)
return;
if (pointer->focus_serial - serial > G_MAXUINT32 / 2)
return;
if (surface &&
!meta_wayland_surface_assign_role (surface,
META_TYPE_WAYLAND_SURFACE_ROLE_CURSOR,
NULL))
{
wl_resource_post_error (resource, WL_POINTER_ERROR_ROLE,
"wl_surface@%d already has a different role",
wl_resource_get_id (surface_resource));
return;
}
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
if (surface)
{
MetaCursorRenderer *cursor_renderer =
meta_backend_get_cursor_renderer (meta_get_backend ());
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
MetaWaylandSurfaceRoleCursor *cursor_role;
cursor_role = META_WAYLAND_SURFACE_ROLE_CURSOR (surface->role);
meta_wayland_surface_role_cursor_set_renderer (cursor_role,
cursor_renderer);
meta_wayland_surface_role_cursor_set_hotspot (cursor_role,
hot_x, hot_y);
Support scaling of cursor sprites given what output they are on This commits refactors cursor handling code and plugs in logic so that cursor sprites changes appearance as it moves across the screen. Renderers are adapted to handle the necessary functionality. The logic for changing the cursor sprite appearance is done outside of MetaCursorSprite, and actually where depends on what type of cursor it is. In mutter we now have two types of cursors that may have their appearance changed: - Themed cursors (aka root cursors) - wl_surface cursors Themed cursors are created by MetaScreen and when created, when applicable(*), it will extend the cursor via connecting to a signal which is emitted everytime the cursor is moved. The signal handler will calculate the expected scale given the monitor it is on and reload the theme in a correct size when needed. wl_surface cursors are created when a wl_surface is assigned the "cursor" role, i.e. when a client calls wl_pointer.set_cursor. A cursor role object is created which is connected to the cursor object by the position signal, and will set a correct texture scale given what monitor the cursor is on and what scale the wl_surface's active buffer is in. It will also push new buffers to the same to the cursor object when new ones are committed to the surface. This commit also makes texture loading lazy, since the renderer doesn't calculate a rectangle when the cursor position changes. The native backend is refactored to be triple-buffered; see the comment in meta-cursor-renderer-native.c for further explanations. * when we are running as a Wayland compositor https://bugzilla.gnome.org/show_bug.cgi?id=744932
2015-07-17 11:16:39 -04:00
}
meta_wayland_pointer_set_cursor_surface (pointer, surface);
}
static void
pointer_release (struct wl_client *client,
struct wl_resource *resource)
{
wl_resource_destroy (resource);
}
static const struct wl_pointer_interface pointer_interface = {
pointer_set_cursor,
pointer_release,
};
void
meta_wayland_pointer_create_new_resource (MetaWaylandPointer *pointer,
struct wl_client *client,
struct wl_resource *seat_resource,
uint32_t id)
{
struct wl_resource *cr;
MetaWaylandPointerClient *pointer_client;
cr = wl_resource_create (client, &wl_pointer_interface, wl_resource_get_version (seat_resource), id);
wl_resource_set_implementation (cr, &pointer_interface, pointer,
meta_wayland_pointer_unbind_pointer_client_resource);
pointer_client = meta_wayland_pointer_ensure_pointer_client (pointer, client);
wl_list_insert (&pointer_client->pointer_resources,
wl_resource_get_link (cr));
if (pointer->focus_client == pointer_client)
{
meta_wayland_pointer_send_enter (pointer, cr,
pointer->focus_serial,
pointer->focus_surface);
meta_wayland_pointer_send_frame (pointer, cr);
}
}
gboolean
meta_wayland_pointer_can_grab_surface (MetaWaylandPointer *pointer,
MetaWaylandSurface *surface,
uint32_t serial)
{
return (pointer->grab_serial == serial &&
pointer->focus_surface == surface);
}
gboolean
meta_wayland_pointer_can_popup (MetaWaylandPointer *pointer, uint32_t serial)
{
return pointer->grab_serial == serial;
}
MetaWaylandSurface *
meta_wayland_pointer_get_top_popup (MetaWaylandPointer *pointer)
{
MetaWaylandPopupGrab *grab;
if (!meta_wayland_pointer_grab_is_popup_grab (pointer->grab))
return NULL;
grab = (MetaWaylandPopupGrab*)pointer->grab;
return meta_wayland_popup_grab_get_top_popup(grab);
}
static void
relative_pointer_destroy (struct wl_client *client,
struct wl_resource *resource)
{
wl_resource_destroy (resource);
}
static const struct zwp_relative_pointer_v1_interface relative_pointer_interface = {
relative_pointer_destroy
};
static void
relative_pointer_manager_destroy (struct wl_client *client,
struct wl_resource *resource)
{
wl_resource_destroy (resource);
}
static void
relative_pointer_manager_get_relative_pointer (struct wl_client *client,
struct wl_resource *resource,
uint32_t id,
struct wl_resource *pointer_resource)
{
MetaWaylandPointer *pointer = wl_resource_get_user_data (pointer_resource);
struct wl_resource *cr;
MetaWaylandPointerClient *pointer_client;
cr = wl_resource_create (client, &zwp_relative_pointer_v1_interface,
wl_resource_get_version (resource), id);
if (cr == NULL)
{
wl_client_post_no_memory (client);
return;
}
wl_resource_set_implementation (cr, &relative_pointer_interface,
pointer,
meta_wayland_pointer_unbind_pointer_client_resource);
pointer_client = meta_wayland_pointer_ensure_pointer_client (pointer, client);
wl_list_insert (&pointer_client->relative_pointer_resources,
wl_resource_get_link (cr));
}
static const struct zwp_relative_pointer_manager_v1_interface relative_pointer_manager = {
relative_pointer_manager_destroy,
relative_pointer_manager_get_relative_pointer,
};
static void
bind_relative_pointer_manager (struct wl_client *client,
void *data,
uint32_t version,
uint32_t id)
{
MetaWaylandCompositor *compositor = data;
struct wl_resource *resource;
resource = wl_resource_create (client,
&zwp_relative_pointer_manager_v1_interface,
1, id);
if (version != 1)
wl_resource_post_error (resource,
WL_DISPLAY_ERROR_INVALID_OBJECT,
"bound invalid version %u of "
"wp_relative_pointer_manager",
version);
wl_resource_set_implementation (resource, &relative_pointer_manager,
compositor,
NULL);
}
void
meta_wayland_relative_pointer_init (MetaWaylandCompositor *compositor)
{
/* Relative pointer events are currently only supported by the native backend
* so lets just advertise the extension when the native backend is used.
*/
#ifdef HAVE_NATIVE_BACKEND
if (!META_IS_BACKEND_NATIVE (meta_get_backend ()))
return;
#else
return;
#endif
if (!wl_global_create (compositor->wayland_display,
&zwp_relative_pointer_manager_v1_interface, 1,
compositor, bind_relative_pointer_manager))
g_error ("Could not create relative pointer manager global");
}
MetaWaylandSeat *
meta_wayland_pointer_get_seat (MetaWaylandPointer *pointer)
{
MetaWaylandSeat *seat = wl_container_of (pointer, seat, pointer);
return seat;
}