/* GDK - The GIMP Drawing Kit * Copyright (C) 1995-2007 Peter Mattis, Spencer Kimball, * Josh MacDonald, Ryan Lortie * * 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 . */ /* * Modified by the GTK+ Team and others 1997-2000. See the AUTHORS * file for a list of people on the GTK+ Team. See the ChangeLog * files for a list of changes. These files are distributed with * GTK+ at ftp://ftp.gtk.org/pub/gtk/. */ #include "config.h" #include #include "gdksurface.h" #include "gdk-private.h" #include "gdkdeviceprivate.h" #include "gdkdisplayprivate.h" #include "gdkdragsurfaceprivate.h" #include "gdkeventsprivate.h" #include "gdkframeclockidleprivate.h" #include "gdkglcontextprivate.h" #include "gdkinternals.h" #include "gdkintl.h" #include "gdkmarshalers.h" #include "gdkpopupprivate.h" #include "gdkrectangle.h" #include "gdktoplevelprivate.h" #include #include #ifdef GDK_WINDOWING_WAYLAND #include "wayland/gdkwayland.h" #endif /** * SECTION:gdksurface * @Short_description: Onscreen display areas in the target window system * @Title: Surfaces * * A #GdkSurface is a (usually) rectangular region on the screen. * It’s a low-level object, used to implement high-level objects such as * #GtkWindow on the GTK level. */ /** * GdkSurface: * * The GdkSurface struct contains only private fields and * should not be accessed directly. */ enum { POPUP_LAYOUT_CHANGED, SIZE_CHANGED, RENDER, EVENT, ENTER_MONITOR, LEAVE_MONITOR, LAST_SIGNAL }; enum { PROP_0, PROP_CURSOR, PROP_DISPLAY, PROP_FRAME_CLOCK, PROP_MAPPED, PROP_WIDTH, PROP_HEIGHT, LAST_PROP }; /* Global info */ static void gdk_surface_finalize (GObject *object); static void gdk_surface_set_property (GObject *object, guint prop_id, const GValue *value, GParamSpec *pspec); static void gdk_surface_get_property (GObject *object, guint prop_id, GValue *value, GParamSpec *pspec); static void update_cursor (GdkDisplay *display, GdkDevice *device); static void gdk_surface_set_frame_clock (GdkSurface *surface, GdkFrameClock *clock); static guint signals[LAST_SIGNAL] = { 0 }; static GParamSpec *properties[LAST_PROP] = { NULL, }; G_DEFINE_ABSTRACT_TYPE (GdkSurface, gdk_surface, G_TYPE_OBJECT) static gboolean gdk_surface_real_beep (GdkSurface *surface) { return FALSE; } static GdkDisplay * get_display_for_surface (GdkSurface *primary, GdkSurface *secondary) { GdkDisplay *display = primary->display; if (display) return display; display = secondary->display; if (display) return display; g_warning ("no display for surface, using default"); return gdk_display_get_default (); } static GdkMonitor * get_monitor_for_rect (GdkDisplay *display, const GdkRectangle *rect, void (*get_bounds) (GdkMonitor *monitor, GdkRectangle *bounds)) { int biggest_area = G_MININT; GdkMonitor *best_monitor = NULL; GdkMonitor *monitor; GdkRectangle workarea; GdkRectangle intersection; GListModel *monitors; guint i; monitors = gdk_display_get_monitors (display); for (i = 0; i < g_list_model_get_n_items (monitors); i++) { monitor = g_list_model_get_item (monitors, i); get_bounds (monitor, &workarea); if (gdk_rectangle_intersect (&workarea, rect, &intersection)) { if (intersection.width * intersection.height > biggest_area) { biggest_area = intersection.width * intersection.height; best_monitor = monitor; } } g_object_unref (monitor); } return best_monitor; } static int get_anchor_x_sign (GdkGravity anchor) { switch (anchor) { case GDK_GRAVITY_STATIC: case GDK_GRAVITY_NORTH_WEST: case GDK_GRAVITY_WEST: case GDK_GRAVITY_SOUTH_WEST: return -1; default: case GDK_GRAVITY_NORTH: case GDK_GRAVITY_CENTER: case GDK_GRAVITY_SOUTH: return 0; case GDK_GRAVITY_NORTH_EAST: case GDK_GRAVITY_EAST: case GDK_GRAVITY_SOUTH_EAST: return 1; } } static int get_anchor_y_sign (GdkGravity anchor) { switch (anchor) { case GDK_GRAVITY_STATIC: case GDK_GRAVITY_NORTH_WEST: case GDK_GRAVITY_NORTH: case GDK_GRAVITY_NORTH_EAST: return -1; default: case GDK_GRAVITY_WEST: case GDK_GRAVITY_CENTER: case GDK_GRAVITY_EAST: return 0; case GDK_GRAVITY_SOUTH_WEST: case GDK_GRAVITY_SOUTH: case GDK_GRAVITY_SOUTH_EAST: return 1; } } static int maybe_flip_position (int bounds_pos, int bounds_size, int rect_pos, int rect_size, int surface_size, int rect_sign, int surface_sign, int offset, gboolean flip, gboolean *flipped) { int primary; int secondary; *flipped = FALSE; primary = rect_pos + (1 + rect_sign) * rect_size / 2 + offset - (1 + surface_sign) * surface_size / 2; if (!flip || (primary >= bounds_pos && primary + surface_size <= bounds_pos + bounds_size)) return primary; *flipped = TRUE; secondary = rect_pos + (1 - rect_sign) * rect_size / 2 - offset - (1 - surface_sign) * surface_size / 2; if (secondary >= bounds_pos && secondary + surface_size <= bounds_pos + bounds_size) return secondary; *flipped = FALSE; return primary; } GdkMonitor * gdk_surface_get_layout_monitor (GdkSurface *surface, GdkPopupLayout *layout, void (*get_bounds) (GdkMonitor *monitor, GdkRectangle *bounds)) { GdkDisplay *display; GdkRectangle root_rect; root_rect = *gdk_popup_layout_get_anchor_rect (layout); gdk_surface_get_root_coords (surface->parent, root_rect.x, root_rect.y, &root_rect.x, &root_rect.y); root_rect.width = MAX (1, root_rect.width); root_rect.height = MAX (1, root_rect.height); display = get_display_for_surface (surface, surface->transient_for); return get_monitor_for_rect (display, &root_rect, get_bounds); } void gdk_surface_layout_popup_helper (GdkSurface *surface, int width, int height, GdkMonitor *monitor, GdkRectangle *bounds, GdkPopupLayout *layout, GdkRectangle *out_final_rect) { GdkRectangle root_rect; GdkGravity rect_anchor; GdkGravity surface_anchor; int rect_anchor_dx; int rect_anchor_dy; GdkAnchorHints anchor_hints; GdkRectangle final_rect; gboolean flipped_x; gboolean flipped_y; int x, y; g_return_if_fail (GDK_IS_POPUP (surface)); root_rect = *gdk_popup_layout_get_anchor_rect (layout); gdk_surface_get_root_coords (surface->parent, root_rect.x, root_rect.y, &root_rect.x, &root_rect.y); rect_anchor = gdk_popup_layout_get_rect_anchor (layout); surface_anchor = gdk_popup_layout_get_surface_anchor (layout); gdk_popup_layout_get_offset (layout, &rect_anchor_dx, &rect_anchor_dy); anchor_hints = gdk_popup_layout_get_anchor_hints (layout); final_rect.width = width - surface->shadow_left - surface->shadow_right; final_rect.height = height - surface->shadow_top - surface->shadow_bottom; final_rect.x = maybe_flip_position (bounds->x, bounds->width, root_rect.x, root_rect.width, final_rect.width, get_anchor_x_sign (rect_anchor), get_anchor_x_sign (surface_anchor), rect_anchor_dx, anchor_hints & GDK_ANCHOR_FLIP_X, &flipped_x); final_rect.y = maybe_flip_position (bounds->y, bounds->height, root_rect.y, root_rect.height, final_rect.height, get_anchor_y_sign (rect_anchor), get_anchor_y_sign (surface_anchor), rect_anchor_dy, anchor_hints & GDK_ANCHOR_FLIP_Y, &flipped_y); if (anchor_hints & GDK_ANCHOR_SLIDE_X) { if (final_rect.x + final_rect.width > bounds->x + bounds->width) final_rect.x = bounds->x + bounds->width - final_rect.width; if (final_rect.x < bounds->x) final_rect.x = bounds->x; } if (anchor_hints & GDK_ANCHOR_SLIDE_Y) { if (final_rect.y + final_rect.height > bounds->y + bounds->height) final_rect.y = bounds->y + bounds->height - final_rect.height; if (final_rect.y < bounds->y) final_rect.y = bounds->y; } if (anchor_hints & GDK_ANCHOR_RESIZE_X) { if (final_rect.x < bounds->x) { final_rect.width -= bounds->x - final_rect.x; final_rect.x = bounds->x; } if (final_rect.x + final_rect.width > bounds->x + bounds->width) final_rect.width = bounds->x + bounds->width - final_rect.x; } if (anchor_hints & GDK_ANCHOR_RESIZE_Y) { if (final_rect.y < bounds->y) { final_rect.height -= bounds->y - final_rect.y; final_rect.y = bounds->y; } if (final_rect.y + final_rect.height > bounds->y + bounds->height) final_rect.height = bounds->y + bounds->height - final_rect.y; } final_rect.x -= surface->shadow_left; final_rect.y -= surface->shadow_top; final_rect.width += surface->shadow_left + surface->shadow_right; final_rect.height += surface->shadow_top + surface->shadow_bottom; gdk_surface_get_origin (surface->parent, &x, &y); final_rect.x -= x; final_rect.y -= y; if (flipped_x) { rect_anchor = gdk_gravity_flip_horizontally (rect_anchor); surface_anchor = gdk_gravity_flip_horizontally (surface_anchor); } if (flipped_y) { rect_anchor = gdk_gravity_flip_vertically (rect_anchor); surface_anchor = gdk_gravity_flip_vertically (surface_anchor); } surface->popup.rect_anchor = rect_anchor; surface->popup.surface_anchor = surface_anchor; *out_final_rect = final_rect; } /* Since GdkEvent is a GTypeInstance, GValue can only store it as a pointer, * and GClosure does not know how to handle its memory management. To avoid * the event going away in the middle of the signal emission, we provide a * marshaller that keeps the event alive for the duration of the closure. */ static void gdk_surface_event_marshaller (GClosure *closure, GValue *return_value, guint n_param_values, const GValue *param_values, gpointer invocation_hint, gpointer marshal_data) { GdkEvent *event = g_value_get_pointer (¶m_values[1]); gdk_event_ref (event); _gdk_marshal_BOOLEAN__POINTER (closure, return_value, n_param_values, param_values, invocation_hint, marshal_data); gdk_event_unref (event); } static void gdk_surface_event_marshallerv (GClosure *closure, GValue *return_value, gpointer instance, va_list args, gpointer marshal_data, int n_params, GType *param_types) { va_list args_copy; GdkEvent *event; G_VA_COPY (args_copy, args); event = va_arg (args_copy, gpointer); gdk_event_ref (event); _gdk_marshal_BOOLEAN__POINTERv (closure, return_value, instance, args, marshal_data, n_params, param_types); gdk_event_unref (event); va_end (args_copy); } static void gdk_surface_init (GdkSurface *surface) { /* 0-initialization is good for all other fields. */ surface->state = GDK_TOPLEVEL_STATE_WITHDRAWN; surface->fullscreen_mode = GDK_FULLSCREEN_ON_CURRENT_MONITOR; surface->width = 1; surface->height = 1; surface->alpha = 255; surface->device_cursor = g_hash_table_new_full (NULL, NULL, NULL, g_object_unref); } static void gdk_surface_class_init (GdkSurfaceClass *klass) { GObjectClass *object_class = G_OBJECT_CLASS (klass); object_class->finalize = gdk_surface_finalize; object_class->set_property = gdk_surface_set_property; object_class->get_property = gdk_surface_get_property; klass->beep = gdk_surface_real_beep; /** * GdkSurface:cursor: * * The mouse pointer for a #GdkSurface. See gdk_surface_set_cursor() and * gdk_surface_get_cursor() for details. */ properties[PROP_CURSOR] = g_param_spec_object ("cursor", P_("Cursor"), P_("Cursor"), GDK_TYPE_CURSOR, G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS); /** * GdkSurface:display: * * The #GdkDisplay connection of the surface. See gdk_surface_get_display() * for details. */ properties[PROP_DISPLAY] = g_param_spec_object ("display", P_("Display"), P_("Display"), GDK_TYPE_DISPLAY, G_PARAM_READWRITE | G_PARAM_CONSTRUCT_ONLY | G_PARAM_STATIC_STRINGS); properties[PROP_FRAME_CLOCK] = g_param_spec_object ("frame-clock", P_("Frame Clock"), P_("Frame Clock"), GDK_TYPE_FRAME_CLOCK, G_PARAM_READWRITE | G_PARAM_CONSTRUCT_ONLY | G_PARAM_STATIC_STRINGS); properties[PROP_MAPPED] = g_param_spec_boolean ("mapped", P_("Mapped"), P_("Mapped"), FALSE, G_PARAM_READABLE | G_PARAM_STATIC_STRINGS); properties[PROP_WIDTH] = g_param_spec_int ("width", P_("Width"), P_("Width"), 0, G_MAXINT, 0, G_PARAM_READABLE | G_PARAM_STATIC_STRINGS); properties[PROP_HEIGHT] = g_param_spec_int ("height", P_("Height"), P_("Height"), 0, G_MAXINT, 0, G_PARAM_READABLE | G_PARAM_STATIC_STRINGS); g_object_class_install_properties (object_class, LAST_PROP, properties); /** * GdkSurface::size-changed: * @surface: the #GdkSurface * @width: the new width * @height: the new height * * Emitted when the size of @surface is changed. * * Surface size is reported in ”application pixels”, not * ”device pixels” (see gdk_surface_get_scale_factor()). */ signals[SIZE_CHANGED] = g_signal_new (g_intern_static_string ("size-changed"), G_OBJECT_CLASS_TYPE (object_class), G_SIGNAL_RUN_FIRST, 0, NULL, NULL, NULL, G_TYPE_NONE, 2, G_TYPE_INT, G_TYPE_INT); /** * GdkSurface::render: * @surface: the #GdkSurface * @region: the region that needs to be redrawn * * Emitted when part of the surface needs to be redrawn. * * Returns: %TRUE to indicate that the signal has been handled */ signals[RENDER] = g_signal_new (g_intern_static_string ("render"), G_OBJECT_CLASS_TYPE (object_class), G_SIGNAL_RUN_LAST, 0, g_signal_accumulator_true_handled, NULL, _gdk_marshal_BOOLEAN__BOXED, G_TYPE_BOOLEAN, 1, CAIRO_GOBJECT_TYPE_REGION); g_signal_set_va_marshaller (signals[RENDER], G_OBJECT_CLASS_TYPE (object_class), _gdk_marshal_BOOLEAN__BOXEDv); /** * GdkSurface::event: * @surface: the #GdkSurface * @event: (type Gdk.Event): an input event * * Emitted when GDK receives an input event for @surface. * * Returns: %TRUE to indicate that the event has been handled */ signals[EVENT] = g_signal_new (g_intern_static_string ("event"), G_OBJECT_CLASS_TYPE (object_class), G_SIGNAL_RUN_LAST, 0, g_signal_accumulator_true_handled, NULL, gdk_surface_event_marshaller, G_TYPE_BOOLEAN, 1, G_TYPE_POINTER); g_signal_set_va_marshaller (signals[EVENT], G_OBJECT_CLASS_TYPE (object_class), gdk_surface_event_marshallerv); /** * GdkSurface::enter-monitor: * @surface: the #GdkSurface * @monitor: the monitor * * Emitted when @surface starts being present on the monitor. */ signals[ENTER_MONITOR] = g_signal_new (g_intern_static_string ("enter-monitor"), G_OBJECT_CLASS_TYPE (object_class), G_SIGNAL_RUN_FIRST, 0, NULL, NULL, NULL, G_TYPE_NONE, 1, GDK_TYPE_MONITOR); /** * GdkSurface::leave-monitor: * @surface: the #GdkSurface * @monitor: the monitor * * Emitted when @surface stops being present on the monitor. */ signals[LEAVE_MONITOR] = g_signal_new (g_intern_static_string ("leave-monitor"), G_OBJECT_CLASS_TYPE (object_class), G_SIGNAL_RUN_FIRST, 0, NULL, NULL, NULL, G_TYPE_NONE, 1, GDK_TYPE_MONITOR); } static void seat_removed_cb (GdkDisplay *display, GdkSeat *seat, GdkSurface *surface) { GdkDevice *device = gdk_seat_get_pointer (seat); surface->devices_inside = g_list_remove (surface->devices_inside, device); g_hash_table_remove (surface->device_cursor, device); } static void gdk_surface_finalize (GObject *object) { GdkSurface *surface = GDK_SURFACE (object); g_signal_handlers_disconnect_by_func (surface->display, seat_removed_cb, surface); if (!GDK_SURFACE_DESTROYED (surface)) { g_warning ("losing last reference to undestroyed surface"); _gdk_surface_destroy (surface, FALSE); } if (surface->input_region) cairo_region_destroy (surface->input_region); if (surface->cursor) g_object_unref (surface->cursor); if (surface->device_cursor) g_hash_table_destroy (surface->device_cursor); if (surface->devices_inside) g_list_free (surface->devices_inside); g_clear_object (&surface->display); if (surface->opaque_region) cairo_region_destroy (surface->opaque_region); if (surface->parent) surface->parent->children = g_list_remove (surface->parent->children, surface); G_OBJECT_CLASS (gdk_surface_parent_class)->finalize (object); } static void gdk_surface_set_property (GObject *object, guint prop_id, const GValue *value, GParamSpec *pspec) { GdkSurface *surface = GDK_SURFACE (object); switch (prop_id) { case PROP_CURSOR: gdk_surface_set_cursor (surface, g_value_get_object (value)); break; case PROP_DISPLAY: surface->display = g_value_dup_object (value); g_assert (surface->display != NULL); g_signal_connect (surface->display, "seat-removed", G_CALLBACK (seat_removed_cb), surface); break; case PROP_FRAME_CLOCK: gdk_surface_set_frame_clock (surface, GDK_FRAME_CLOCK (g_value_get_object (value))); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec); break; } } #define GDK_SURFACE_IS_STICKY(surface) (((surface)->state & GDK_TOPLEVEL_STATE_STICKY)) static void gdk_surface_get_property (GObject *object, guint prop_id, GValue *value, GParamSpec *pspec) { GdkSurface *surface = GDK_SURFACE (object); switch (prop_id) { case PROP_CURSOR: g_value_set_object (value, gdk_surface_get_cursor (surface)); break; case PROP_DISPLAY: g_value_set_object (value, surface->display); break; case PROP_FRAME_CLOCK: g_value_set_object (value, surface->frame_clock); break; case PROP_MAPPED: g_value_set_boolean (value, GDK_SURFACE_IS_MAPPED (surface)); break; case PROP_WIDTH: g_value_set_int (value, surface->width); break; case PROP_HEIGHT: g_value_set_int (value, surface->height); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec); break; } } void _gdk_surface_update_size (GdkSurface *surface) { GSList *l; for (l = surface->draw_contexts; l; l = l->next) gdk_draw_context_surface_resized (l->data); g_object_notify (G_OBJECT (surface), "width"); g_object_notify (G_OBJECT (surface), "height"); } static GdkSurface * gdk_surface_new (GdkDisplay *display, GdkSurfaceType surface_type, GdkSurface *parent, int x, int y, int width, int height) { return gdk_display_create_surface (display, surface_type, parent, x, y, width, height); } /** * gdk_surface_new_toplevel: (constructor) * @display: the display to create the surface on * * Creates a new toplevel surface. * * Returns: (transfer full): the new #GdkSurface **/ GdkSurface * gdk_surface_new_toplevel (GdkDisplay *display) { g_return_val_if_fail (GDK_IS_DISPLAY (display), NULL); return gdk_surface_new (display, GDK_SURFACE_TOPLEVEL, NULL, 0, 0, 1, 1); } /** * gdk_surface_new_temp: (constructor) * @display: the display to create the surface on * @position: position of the surface on screen * * Creates a new temporary surface. * The surface will bypass surface management. * * Returns: (transfer full): the new #GdkSurface **/ GdkSurface * gdk_surface_new_temp (GdkDisplay *display, const GdkRectangle *position) { g_return_val_if_fail (GDK_IS_DISPLAY (display), NULL); g_return_val_if_fail (position != NULL, NULL); return gdk_surface_new (display, GDK_SURFACE_TEMP, NULL, position->x, position->y, position->width, position->height); } /** * gdk_surface_new_popup: (constructor) * @parent: the parent surface to attach the surface to * @autohide: whether to hide the surface on outside clicks * * Create a new popup surface. * * The surface will be attached to @parent and can be positioned * relative to it using gdk_popup_present(). * * Returns: (transfer full): a new #GdkSurface */ GdkSurface * gdk_surface_new_popup (GdkSurface *parent, gboolean autohide) { GdkSurface *surface; g_return_val_if_fail (GDK_IS_SURFACE (parent), NULL); surface = gdk_surface_new (parent->display, GDK_SURFACE_POPUP, parent, 0, 0, 100, 100); surface->autohide = autohide; return surface; } static void update_pointer_info_foreach (GdkDisplay *display, GdkDevice *device, GdkPointerSurfaceInfo *pointer_info, gpointer user_data) { GdkSurface *surface = user_data; if (pointer_info->surface_under_pointer == surface) { g_object_unref (pointer_info->surface_under_pointer); pointer_info->surface_under_pointer = NULL; } } static void surface_remove_from_pointer_info (GdkSurface *surface, GdkDisplay *display) { _gdk_display_pointer_info_foreach (display, update_pointer_info_foreach, surface); } /** * _gdk_surface_destroy_hierarchy: * @surface: a #GdkSurface * @recursing_native: If %TRUE, then this is being called because a native parent * was destroyed. This generally means that the call to the * windowing system to destroy the surface can be omitted, since * it will be destroyed as a result of the parent being destroyed. * Unless @foreign_destroy. * @foreign_destroy: If %TRUE, the surface or a parent was destroyed by some * external agency. The surface has already been destroyed and no * windowing system calls should be made. (This may never happen * for some windowing systems.) * * Internal function to destroy a surface. Like gdk_surface_destroy(), * but does not drop the reference count created by gdk_surface_new(). **/ static void _gdk_surface_destroy_hierarchy (GdkSurface *surface, gboolean foreign_destroy) { g_return_if_fail (GDK_IS_SURFACE (surface)); if (GDK_SURFACE_DESTROYED (surface)) return; GDK_SURFACE_GET_CLASS (surface)->destroy (surface, foreign_destroy); if (surface->gl_paint_context) { /* Make sure to destroy if current */ g_object_run_dispose (G_OBJECT (surface->gl_paint_context)); g_object_unref (surface->gl_paint_context); surface->gl_paint_context = NULL; } if (surface->frame_clock) { if (surface->parent == NULL) g_object_run_dispose (G_OBJECT (surface->frame_clock)); gdk_surface_set_frame_clock (surface, NULL); } _gdk_surface_clear_update_area (surface); surface->state |= GDK_TOPLEVEL_STATE_WITHDRAWN; surface->destroyed = TRUE; surface_remove_from_pointer_info (surface, surface->display); if (GDK_IS_TOPLEVEL (surface)) g_object_notify (G_OBJECT (surface), "state"); g_object_notify_by_pspec (G_OBJECT (surface), properties[PROP_MAPPED]); } /** * _gdk_surface_destroy: * @surface: a #GdkSurface * @foreign_destroy: If %TRUE, the surface or a parent was destroyed by some * external agency. The surface has already been destroyed and no * windowing system calls should be made. (This may never happen * for some windowing systems.) * * Internal function to destroy a surface. Like gdk_surface_destroy(), * but does not drop the reference count created by gdk_surface_new(). **/ void _gdk_surface_destroy (GdkSurface *surface, gboolean foreign_destroy) { _gdk_surface_destroy_hierarchy (surface, foreign_destroy); } /** * gdk_surface_destroy: * @surface: a #GdkSurface * * Destroys the window system resources associated with @surface and decrements @surface's * reference count. The window system resources for all children of @surface are also * destroyed, but the children’s reference counts are not decremented. * * Note that a surface will not be destroyed automatically when its reference count * reaches zero. You must call this function yourself before that happens. * **/ void gdk_surface_destroy (GdkSurface *surface) { _gdk_surface_destroy_hierarchy (surface, FALSE); g_object_unref (surface); } void gdk_surface_set_widget (GdkSurface *surface, gpointer widget) { surface->widget = widget; } gpointer gdk_surface_get_widget (GdkSurface *surface) { return surface->widget; } /** * gdk_surface_get_display: * @surface: a #GdkSurface * * Gets the #GdkDisplay associated with a #GdkSurface. * * Returns: (transfer none): the #GdkDisplay associated with @surface **/ GdkDisplay * gdk_surface_get_display (GdkSurface *surface) { g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); return surface->display; } /** * gdk_surface_is_destroyed: * @surface: a #GdkSurface * * Check to see if a surface is destroyed.. * * Returns: %TRUE if the surface is destroyed **/ gboolean gdk_surface_is_destroyed (GdkSurface *surface) { return GDK_SURFACE_DESTROYED (surface); } /** * gdk_surface_get_mapped: * @surface: a #GdkSurface * * Checks whether the surface has been mapped (with gdk_toplevel_present() * or gdk_popup_present()). * * Returns: %TRUE if the surface is mapped **/ gboolean gdk_surface_get_mapped (GdkSurface *surface) { g_return_val_if_fail (GDK_IS_SURFACE (surface), FALSE); return GDK_SURFACE_IS_MAPPED (surface); } GdkGLContext * gdk_surface_get_shared_data_gl_context (GdkSurface *surface) { static int in_shared_data_creation; GdkDisplay *display; GdkGLContext *context; if (in_shared_data_creation) return NULL; in_shared_data_creation = 1; display = gdk_surface_get_display (surface); context = (GdkGLContext *)g_object_get_data (G_OBJECT (display), "gdk-gl-shared-data-context"); if (context == NULL) { GError *error = NULL; context = GDK_SURFACE_GET_CLASS (surface)->create_gl_context (surface, FALSE, NULL, &error); if (context == NULL) { g_warning ("Failed to create shared context: %s", error->message); g_clear_error (&error); } gdk_gl_context_realize (context, &error); if (context == NULL) { g_warning ("Failed to realize shared context: %s", error->message); g_clear_error (&error); } g_object_set_data (G_OBJECT (display), "gdk-gl-shared-data-context", context); } in_shared_data_creation = 0; return context; } GdkGLContext * gdk_surface_get_paint_gl_context (GdkSurface *surface, GError **error) { GError *internal_error = NULL; if (GDK_DISPLAY_DEBUG_CHECK (surface->display, GL_DISABLE)) { g_set_error_literal (error, GDK_GL_ERROR, GDK_GL_ERROR_NOT_AVAILABLE, _("GL support disabled via GDK_DEBUG")); return NULL; } if (surface->gl_paint_context == NULL) { GdkSurfaceClass *class = GDK_SURFACE_GET_CLASS (surface); if (class->create_gl_context == NULL) { g_set_error_literal (error, GDK_GL_ERROR, GDK_GL_ERROR_NOT_AVAILABLE, _("The current backend does not support OpenGL")); return NULL; } surface->gl_paint_context = class->create_gl_context (surface, TRUE, NULL, &internal_error); } if (internal_error != NULL) { g_propagate_error (error, internal_error); g_clear_object (&(surface->gl_paint_context)); return NULL; } gdk_gl_context_realize (surface->gl_paint_context, &internal_error); if (internal_error != NULL) { g_propagate_error (error, internal_error); g_clear_object (&(surface->gl_paint_context)); return NULL; } return surface->gl_paint_context; } /** * gdk_surface_create_gl_context: * @surface: a #GdkSurface * @error: return location for an error * * Creates a new #GdkGLContext matching the * framebuffer format to the visual of the #GdkSurface. The context * is disconnected from any particular surface or surface. * * If the creation of the #GdkGLContext failed, @error will be set. * * Before using the returned #GdkGLContext, you will need to * call gdk_gl_context_make_current() or gdk_gl_context_realize(). * * Returns: (transfer full): the newly created #GdkGLContext, or * %NULL on error **/ GdkGLContext * gdk_surface_create_gl_context (GdkSurface *surface, GError **error) { GdkGLContext *paint_context; g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); g_return_val_if_fail (error == NULL || *error == NULL, NULL); paint_context = gdk_surface_get_paint_gl_context (surface, error); if (paint_context == NULL) return NULL; return GDK_SURFACE_GET_CLASS (surface)->create_gl_context (surface, FALSE, paint_context, error); } /** * gdk_surface_create_cairo_context: * @surface: a #GdkSurface * * Creates a new #GdkCairoContext for rendering on @surface. * * Returns: (transfer full): the newly created #GdkCairoContext **/ GdkCairoContext * gdk_surface_create_cairo_context (GdkSurface *surface) { GdkDisplay *display; g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); display = surface->display; return g_object_new (GDK_DISPLAY_GET_CLASS (display)->cairo_context_type, "surface", surface, NULL); } /** * gdk_surface_create_vulkan_context: * @surface: a #GdkSurface * @error: return location for an error * * Creates a new #GdkVulkanContext for rendering on @surface. * * If the creation of the #GdkVulkanContext failed, @error will be set. * * Returns: (transfer full): the newly created #GdkVulkanContext, or * %NULL on error **/ GdkVulkanContext * gdk_surface_create_vulkan_context (GdkSurface *surface, GError **error) { GdkDisplay *display; g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); g_return_val_if_fail (error == NULL || *error == NULL, NULL); if (GDK_DISPLAY_DEBUG_CHECK (surface->display, VULKAN_DISABLE)) { g_set_error_literal (error, GDK_VULKAN_ERROR, GDK_VULKAN_ERROR_NOT_AVAILABLE, _("Vulkan support disabled via GDK_DEBUG")); return NULL; } display = surface->display; if (GDK_DISPLAY_GET_CLASS (display)->vk_extension_name == NULL) { g_set_error (error, GDK_VULKAN_ERROR, GDK_VULKAN_ERROR_UNSUPPORTED, "The %s backend has no Vulkan support.", G_OBJECT_TYPE_NAME (display)); return FALSE; } return g_initable_new (GDK_DISPLAY_GET_CLASS (display)->vk_context_type, NULL, error, "surface", surface, NULL); } /* Code for dirty-region queueing */ static GSList *update_surfaces = NULL; static void gdk_surface_add_update_surface (GdkSurface *surface) { GSList *tmp; /* Check whether "surface" is already in "update_surfaces" list. * It could be added during execution of gtk_widget_destroy() when * setting focus widget to NULL and redrawing old focus widget. * See bug 711552. */ tmp = g_slist_find (update_surfaces, surface); if (tmp != NULL) return; update_surfaces = g_slist_prepend (update_surfaces, g_object_ref (surface)); } static void gdk_surface_remove_update_surface (GdkSurface *surface) { GSList *link; link = g_slist_find (update_surfaces, surface); if (link != NULL) { update_surfaces = g_slist_delete_link (update_surfaces, link); g_object_unref (surface); } } static gboolean gdk_surface_is_toplevel_frozen (GdkSurface *surface) { return surface->update_and_descendants_freeze_count > 0; } static void gdk_surface_schedule_update (GdkSurface *surface) { GdkFrameClock *frame_clock; g_return_if_fail (surface); if (surface->update_freeze_count || gdk_surface_is_toplevel_frozen (surface)) { surface->pending_schedule_update = TRUE; return; } /* If there's no frame clock (a foreign surface), then the invalid * region will just stick around unless gdk_surface_process_updates() * is called. */ frame_clock = gdk_surface_get_frame_clock (surface); if (frame_clock) gdk_frame_clock_request_phase (gdk_surface_get_frame_clock (surface), GDK_FRAME_CLOCK_PHASE_PAINT); } static void gdk_surface_process_updates_internal (GdkSurface *surface) { /* Ensure the surface lives while updating it */ g_object_ref (surface); surface->in_update = TRUE; /* If an update got queued during update processing, we can get a * surface in the update queue that has an empty update_area. * just ignore it. */ if (surface->update_area) { g_assert (surface->active_update_area == NULL); /* No reentrancy */ surface->active_update_area = surface->update_area; surface->update_area = NULL; if (GDK_SURFACE_IS_MAPPED (surface)) { cairo_region_t *expose_region; gboolean handled; expose_region = cairo_region_copy (surface->active_update_area); g_signal_emit (surface, signals[RENDER], 0, expose_region, &handled); cairo_region_destroy (expose_region); } cairo_region_destroy (surface->active_update_area); surface->active_update_area = NULL; } surface->in_update = FALSE; g_object_unref (surface); } static void gdk_surface_paint_on_clock (GdkFrameClock *clock, void *data) { GdkSurface *surface = GDK_SURFACE (data); g_return_if_fail (GDK_IS_SURFACE (surface)); if (GDK_SURFACE_DESTROYED (surface)) return; g_object_ref (surface); if (surface->update_area && !surface->update_freeze_count && !gdk_surface_is_toplevel_frozen (surface) && /* Don't recurse into process_updates_internal, we'll * do the update later when idle instead. */ !surface->in_update) { gdk_surface_process_updates_internal (surface); gdk_surface_remove_update_surface (surface); } g_object_unref (surface); } /* * gdk_surface_invalidate_rect: * @surface: a #GdkSurface * @rect: (allow-none): rectangle to invalidate or %NULL to invalidate the whole * surface * * A convenience wrapper around gdk_surface_invalidate_region() * which invalidates a rectangular region. * See gdk_surface_invalidate_region() for details. **/ void gdk_surface_invalidate_rect (GdkSurface *surface, const GdkRectangle *rect) { GdkRectangle surface_rect; cairo_region_t *region; g_return_if_fail (GDK_IS_SURFACE (surface)); if (!GDK_SURFACE_IS_MAPPED (surface)) return; if (!rect) { surface_rect.x = 0; surface_rect.y = 0; surface_rect.width = surface->width; surface_rect.height = surface->height; rect = &surface_rect; } region = cairo_region_create_rectangle (rect); gdk_surface_invalidate_region (surface, region); cairo_region_destroy (region); } static void impl_surface_add_update_area (GdkSurface *impl_surface, cairo_region_t *region) { if (impl_surface->update_area) cairo_region_union (impl_surface->update_area, region); else { gdk_surface_add_update_surface (impl_surface); impl_surface->update_area = cairo_region_copy (region); gdk_surface_schedule_update (impl_surface); } } /** * gdk_surface_queue_render: * @surface: a #GdkSurface * * Forces a #GdkSurface::render signal emission for @surface * to be scheduled. * * This function is useful for implementations that track invalid * regions on their own. **/ void gdk_surface_queue_render (GdkSurface *surface) { cairo_region_t *region; g_return_if_fail (GDK_IS_SURFACE (surface)); region = cairo_region_create (); impl_surface_add_update_area (surface, region); cairo_region_destroy (region); } /* * gdk_surface_invalidate_region: * @surface: a #GdkSurface * @region: a #cairo_region_t * * Adds @region to the update area for @surface. The update area is * the region that needs to be redrawn, or “dirty region.” * * GDK will process all updates whenever the frame clock schedules a * redraw, so there’s no need to do forces redraws manually, you just * need to invalidate regions that you know should be redrawn. **/ void gdk_surface_invalidate_region (GdkSurface *surface, const cairo_region_t *region) { cairo_region_t *visible_region; cairo_rectangle_int_t r; g_return_if_fail (GDK_IS_SURFACE (surface)); if (!GDK_SURFACE_IS_MAPPED (surface)) return; if (cairo_region_is_empty (region)) return; r.x = 0; r.y = 0; r.width = surface->width; r.height = surface->height; visible_region = cairo_region_copy (region); cairo_region_intersect_rectangle (visible_region, &r); impl_surface_add_update_area (surface, visible_region); cairo_region_destroy (visible_region); } /* * _gdk_surface_clear_update_area: * @surface: a #GdkSurface. * * Internal function to clear the update area for a surface. * This is called when the surface is hidden or destroyed. **/ void _gdk_surface_clear_update_area (GdkSurface *surface) { g_return_if_fail (GDK_IS_SURFACE (surface)); if (surface->update_area) { gdk_surface_remove_update_surface (surface); cairo_region_destroy (surface->update_area); surface->update_area = NULL; } } /* * gdk_surface_freeze_updates: * @surface: a #GdkSurface * * Temporarily freezes a surface such that it won’t receive expose * events. The surface will begin receiving expose events again when * gdk_surface_thaw_updates() is called. If gdk_surface_freeze_updates() * has been called more than once, gdk_surface_thaw_updates() must be * called an equal number of times to begin processing exposes. **/ void gdk_surface_freeze_updates (GdkSurface *surface) { g_return_if_fail (GDK_IS_SURFACE (surface)); surface->update_freeze_count++; if (surface->update_freeze_count == 1) _gdk_frame_clock_uninhibit_freeze (surface->frame_clock); } /* * gdk_surface_thaw_updates: * @surface: a #GdkSurface * * Thaws a surface frozen with gdk_surface_freeze_updates(). Note that this * will not necessarily schedule updates if the surface freeze count reaches * zero. **/ void gdk_surface_thaw_updates (GdkSurface *surface) { g_return_if_fail (GDK_IS_SURFACE (surface)); g_return_if_fail (surface->update_freeze_count > 0); if (--surface->update_freeze_count == 0) { _gdk_frame_clock_inhibit_freeze (surface->frame_clock); if (surface->pending_schedule_update) { surface->pending_schedule_update = FALSE; gdk_surface_schedule_update (surface); } } } void gdk_surface_freeze_toplevel_updates (GdkSurface *surface) { g_return_if_fail (GDK_IS_SURFACE (surface)); surface->update_and_descendants_freeze_count++; gdk_surface_freeze_updates (surface); } void gdk_surface_thaw_toplevel_updates (GdkSurface *surface) { g_return_if_fail (GDK_IS_SURFACE (surface)); g_return_if_fail (surface->update_and_descendants_freeze_count > 0); surface->update_and_descendants_freeze_count--; gdk_surface_schedule_update (surface); gdk_surface_thaw_updates (surface); } /* * gdk_surface_constrain_size: * @geometry: a #GdkGeometry structure * @flags: a mask indicating what portions of @geometry are set * @width: desired width of surface * @height: desired height of the surface * @new_width: (out): location to store resulting width * @new_height: (out): location to store resulting height * * Constrains a desired width and height according to a * set of geometry hints (such as minimum and maximum size). */ void gdk_surface_constrain_size (GdkGeometry *geometry, GdkSurfaceHints flags, int width, int height, int *new_width, int *new_height) { /* This routine is partially borrowed from fvwm. * * Copyright 1993, Robert Nation * You may use this code for any purpose, as long as the original * copyright remains in the source code and all documentation * * which in turn borrows parts of the algorithm from uwm */ int min_width = 0; int min_height = 0; int max_width = G_MAXINT; int max_height = G_MAXINT; if (flags & GDK_HINT_MIN_SIZE) { min_width = geometry->min_width; min_height = geometry->min_height; } if (flags & GDK_HINT_MAX_SIZE) { max_width = geometry->max_width ; max_height = geometry->max_height; } /* clamp width and height to min and max values */ width = CLAMP (width, min_width, max_width); height = CLAMP (height, min_height, max_height); *new_width = width; *new_height = height; } /** * gdk_surface_get_device_position: * @surface: a #GdkSurface. * @device: pointer #GdkDevice to query to. * @x: (out) (allow-none): return location for the X coordinate of @device, or %NULL. * @y: (out) (allow-none): return location for the Y coordinate of @device, or %NULL. * @mask: (out) (allow-none): return location for the modifier mask, or %NULL. * * Obtains the current device position in doubles and modifier state. * The position is given in coordinates relative to the upper left * corner of @surface. * * Return: %TRUE if the device is over the surface **/ gboolean gdk_surface_get_device_position (GdkSurface *surface, GdkDevice *device, double *x, double *y, GdkModifierType *mask) { double tmp_x, tmp_y; GdkModifierType tmp_mask; gboolean ret; g_return_val_if_fail (GDK_IS_SURFACE (surface), FALSE); g_return_val_if_fail (GDK_IS_DEVICE (device), FALSE); g_return_val_if_fail (gdk_device_get_source (device) != GDK_SOURCE_KEYBOARD, FALSE); tmp_x = 0; tmp_y = 0; tmp_mask = 0; ret = GDK_SURFACE_GET_CLASS (surface)->get_device_state (surface, device, &tmp_x, &tmp_y, &tmp_mask); if (x) *x = tmp_x; if (y) *y = tmp_y; if (mask) *mask = tmp_mask; return ret; } /** * gdk_surface_hide: * @surface: a #GdkSurface * * For toplevel surfaces, withdraws them, so they will no longer be * known to the window manager; for all surfaces, unmaps them, so * they won’t be displayed. Normally done automatically as * part of gtk_widget_hide(). */ void gdk_surface_hide (GdkSurface *surface) { gboolean was_mapped; g_return_if_fail (GDK_IS_SURFACE (surface)); if (surface->destroyed) return; was_mapped = GDK_SURFACE_IS_MAPPED (surface); if (GDK_SURFACE_IS_MAPPED (surface)) gdk_synthesize_surface_state (surface, 0, GDK_TOPLEVEL_STATE_WITHDRAWN); if (was_mapped) { GdkDisplay *display; GdkSeat *seat; GList *devices, *d; /* May need to break grabs on children */ display = surface->display; seat = gdk_display_get_default_seat (display); if (seat) { devices = gdk_seat_get_devices (seat, GDK_SEAT_CAPABILITY_ALL); devices = g_list_prepend (devices, gdk_seat_get_keyboard (seat)); devices = g_list_prepend (devices, gdk_seat_get_pointer (seat)); } else devices = NULL; for (d = devices; d; d = d->next) { GdkDevice *device = d->data; if (_gdk_display_end_device_grab (display, device, _gdk_display_get_next_serial (display), surface, TRUE)) { G_GNUC_BEGIN_IGNORE_DEPRECATIONS gdk_device_ungrab (device, GDK_CURRENT_TIME); G_GNUC_END_IGNORE_DEPRECATIONS } } g_list_free (devices); } GDK_SURFACE_GET_CLASS (surface)->hide (surface); surface->popup.rect_anchor = 0; surface->popup.surface_anchor = 0; surface->x = 0; surface->y = 0; } static void gdk_surface_set_cursor_internal (GdkSurface *surface, GdkDevice *device, GdkCursor *cursor) { GdkPointerSurfaceInfo *pointer_info; if (GDK_SURFACE_DESTROYED (surface)) return; g_assert (surface->display == gdk_device_get_display (device)); pointer_info = _gdk_display_get_pointer_info (surface->display, device); if (surface == pointer_info->surface_under_pointer) update_cursor (surface->display, device); } /** * gdk_surface_get_cursor: * @surface: a #GdkSurface * * Retrieves a #GdkCursor pointer for the cursor currently set on the * specified #GdkSurface, or %NULL. If the return value is %NULL then * there is no custom cursor set on the specified surface, and it is * using the cursor for its parent surface. * * Returns: (nullable) (transfer none): a #GdkCursor, or %NULL. The * returned object is owned by the #GdkSurface and should not be * unreferenced directly. Use gdk_surface_set_cursor() to unset the * cursor of the surface */ GdkCursor * gdk_surface_get_cursor (GdkSurface *surface) { g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); return surface->cursor; } /** * gdk_surface_set_cursor: * @surface: a #GdkSurface * @cursor: (allow-none): a cursor * * Sets the default mouse pointer for a #GdkSurface. * * Note that @cursor must be for the same display as @surface. * * Use gdk_cursor_new_from_name() or gdk_cursor_new_from_texture() to * create the cursor. To make the cursor invisible, use %GDK_BLANK_CURSOR. * Passing %NULL for the @cursor argument to gdk_surface_set_cursor() means * that @surface will use the cursor of its parent surface. Most surfaces * should use this default. */ void gdk_surface_set_cursor (GdkSurface *surface, GdkCursor *cursor) { g_return_if_fail (GDK_IS_SURFACE (surface)); if (surface->cursor) { g_object_unref (surface->cursor); surface->cursor = NULL; } if (!GDK_SURFACE_DESTROYED (surface)) { GdkDevice *device; GList *seats, *s; if (cursor) surface->cursor = g_object_ref (cursor); seats = gdk_display_list_seats (surface->display); for (s = seats; s; s = s->next) { GList *devices, *d; device = gdk_seat_get_pointer (s->data); gdk_surface_set_cursor_internal (surface, device, surface->cursor); devices = gdk_seat_get_devices (s->data, GDK_SEAT_CAPABILITY_TABLET_STYLUS); for (d = devices; d; d = d->next) { device = d->data; gdk_surface_set_cursor_internal (surface, device, surface->cursor); } g_list_free (devices); } g_list_free (seats); g_object_notify_by_pspec (G_OBJECT (surface), properties[PROP_CURSOR]); } } /** * gdk_surface_get_device_cursor: * @surface: a #GdkSurface. * @device: a logical, pointer #GdkDevice. * * Retrieves a #GdkCursor pointer for the @device currently set on the * specified #GdkSurface, or %NULL. If the return value is %NULL then * there is no custom cursor set on the specified surface, and it is * using the cursor for its parent surface. * * Returns: (nullable) (transfer none): a #GdkCursor, or %NULL. The * returned object is owned by the #GdkSurface and should not be * unreferenced directly. Use gdk_surface_set_cursor() to unset the * cursor of the surface **/ GdkCursor * gdk_surface_get_device_cursor (GdkSurface *surface, GdkDevice *device) { g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); g_return_val_if_fail (GDK_IS_DEVICE (device), NULL); g_return_val_if_fail (gdk_device_get_source (device) != GDK_SOURCE_KEYBOARD, NULL); return g_hash_table_lookup (surface->device_cursor, device); } /** * gdk_surface_set_device_cursor: * @surface: a #GdkSurface * @device: a logical, pointer #GdkDevice * @cursor: a #GdkCursor * * Sets a specific #GdkCursor for a given device when it gets inside @surface. * Use gdk_cursor_new_from_name() or gdk_cursor_new_from_texture() to create * the cursor. To make the cursor invisible, use %GDK_BLANK_CURSOR. Passing * %NULL for the @cursor argument to gdk_surface_set_cursor() means that * @surface will use the cursor of its parent surface. Most surfaces should * use this default. **/ void gdk_surface_set_device_cursor (GdkSurface *surface, GdkDevice *device, GdkCursor *cursor) { g_return_if_fail (GDK_IS_SURFACE (surface)); g_return_if_fail (GDK_IS_DEVICE (device)); g_return_if_fail (gdk_device_get_source (device) != GDK_SOURCE_KEYBOARD); if (!cursor) g_hash_table_remove (surface->device_cursor, device); else g_hash_table_replace (surface->device_cursor, device, g_object_ref (cursor)); gdk_surface_set_cursor_internal (surface, device, cursor); } /* * gdk_surface_get_geometry: * @surface: a #GdkSurface * @x: (out) (allow-none): return location for X coordinate of surface (relative to its parent) * @y: (out) (allow-none): return location for Y coordinate of surface (relative to its parent) * @width: (out) (allow-none): return location for width of surface * @height: (out) (allow-none): return location for height of surface * * Any of the return location arguments to this function may be %NULL, * if you aren’t interested in getting the value of that field. * * The X and Y coordinates returned are relative to the parent surface * of @surface, which for toplevels usually means relative to the * surface decorations (titlebar, etc.) rather than relative to the * root window (screen-size background window). * * On the X11 platform, the geometry is obtained from the X server, * so reflects the latest position of @surface; this may be out-of-sync * with the position of @surface delivered in the most-recently-processed * #GdkEventConfigure. gdk_surface_get_position() in contrast gets the * position from the most recent configure event. * * Note: If @surface is not a toplevel, it is much better * to call gdk_surface_get_position(), gdk_surface_get_width() and * gdk_surface_get_height() instead, because it avoids the roundtrip to * the X server and because these functions support the full 32-bit * coordinate space, whereas gdk_surface_get_geometry() is restricted to * the 16-bit coordinates of X11. */ void gdk_surface_get_geometry (GdkSurface *surface, int *x, int *y, int *width, int *height) { g_return_if_fail (GDK_IS_SURFACE (surface)); if (GDK_SURFACE_DESTROYED (surface)) return; GDK_SURFACE_GET_CLASS (surface)->get_geometry (surface, x, y, width, height); } /** * gdk_surface_get_width: * @surface: a #GdkSurface * * Returns the width of the given @surface. * * Surface size is reported in ”application pixels”, not * ”device pixels” (see gdk_surface_get_scale_factor()). * * Returns: The width of @surface */ int gdk_surface_get_width (GdkSurface *surface) { g_return_val_if_fail (GDK_IS_SURFACE (surface), 0); return surface->width; } /** * gdk_surface_get_height: * @surface: a #GdkSurface * * Returns the height of the given @surface. * * Surface size is reported in ”application pixels”, not * ”device pixels” (see gdk_surface_get_scale_factor()). * * Returns: The height of @surface */ int gdk_surface_get_height (GdkSurface *surface) { g_return_val_if_fail (GDK_IS_SURFACE (surface), 0); return surface->height; } /* * gdk_surface_get_origin: * @surface: a #GdkSurface * @x: (out): return location for X coordinate * @y: (out): return location for Y coordinate * * Obtains the position of a surface in root window coordinates. * (Compare with gdk_surface_get_position() and * gdk_surface_get_geometry() which return the position * of a surface relative to its parent surface.) */ void gdk_surface_get_origin (GdkSurface *surface, int *x, int *y) { g_return_if_fail (GDK_IS_SURFACE (surface)); gdk_surface_get_root_coords (surface, 0, 0, x, y); } /* * gdk_surface_get_root_coords: * @surface: a #GdkSurface * @x: X coordinate in surface * @y: Y coordinate in surface * @root_x: (out): return location for X coordinate * @root_y: (out): return location for Y coordinate * * Obtains the position of a surface position in root * window coordinates. This is similar to * gdk_surface_get_origin() but allows you to pass * in any position in the surface, not just the origin. */ void gdk_surface_get_root_coords (GdkSurface *surface, int x, int y, int *root_x, int *root_y) { g_return_if_fail (GDK_IS_SURFACE (surface)); if (GDK_SURFACE_DESTROYED (surface)) { *root_x = 0; *root_y = 0; return; } GDK_SURFACE_GET_CLASS (surface)->get_root_coords (surface, x, y, root_x, root_y); } /** * gdk_surface_set_input_region: * @surface: a #GdkSurface * @region: region of surface to be reactive * * Apply the region to the surface for the purpose of event * handling. Mouse events which happen while the pointer position * corresponds to an unset bit in the mask will be passed on the * surface below @surface. * * An input region is typically used with RGBA surfaces. * The alpha channel of the surface defines which pixels are * invisible and allows for nicely antialiased borders, * and the input region controls where the surface is * “clickable”. * * Use gdk_display_supports_input_shapes() to find out if * a particular backend supports input regions. */ void gdk_surface_set_input_region (GdkSurface *surface, cairo_region_t *region) { g_return_if_fail (GDK_IS_SURFACE (surface)); if (GDK_SURFACE_DESTROYED (surface)) return; if (cairo_region_equal (surface->input_region, region)) return; if (surface->input_region) cairo_region_destroy (surface->input_region); if (region) surface->input_region = cairo_region_copy (region); else surface->input_region = NULL; GDK_SURFACE_GET_CLASS (surface)->set_input_region (surface, surface->input_region); } static void update_cursor (GdkDisplay *display, GdkDevice *device) { GdkSurface *cursor_surface; GdkSurface *pointer_surface; GdkPointerSurfaceInfo *pointer_info; GdkDeviceGrabInfo *grab; GdkCursor *cursor; pointer_info = _gdk_display_get_pointer_info (display, device); pointer_surface = pointer_info->surface_under_pointer; /* We ignore the serials here and just pick the last grab we've sent, as that would shortly be used anyway. */ grab = _gdk_display_get_last_device_grab (display, device); if (grab != NULL) { /* use the cursor from the grab surface */ cursor_surface = grab->surface; } else { /* otherwise use the cursor from the pointer surface */ cursor_surface = pointer_surface; } cursor = g_hash_table_lookup (cursor_surface->device_cursor, device); if (!cursor) cursor = cursor_surface->cursor; GDK_DEVICE_GET_CLASS (device)->set_surface_cursor (device, pointer_surface, cursor); } /** * gdk_surface_beep: * @surface: a toplevel #GdkSurface * * Emits a short beep associated to @surface in the appropriate * display, if supported. Otherwise, emits a short beep on * the display just as gdk_display_beep(). **/ void gdk_surface_beep (GdkSurface *surface) { g_return_if_fail (GDK_IS_SURFACE (surface)); if (GDK_SURFACE_DESTROYED (surface)) return; if (GDK_SURFACE_GET_CLASS (surface)->beep (surface)) return; gdk_display_beep (surface->display); } void _gdk_display_set_surface_under_pointer (GdkDisplay *display, GdkDevice *device, GdkSurface *surface) { GdkPointerSurfaceInfo *device_info; device_info = _gdk_display_get_pointer_info (display, device); if (device_info->surface_under_pointer) g_object_unref (device_info->surface_under_pointer); device_info->surface_under_pointer = surface; if (surface) { g_object_ref (surface); update_cursor (display, device); } } #define GDK_ANY_BUTTON_MASK (GDK_BUTTON1_MASK | \ GDK_BUTTON2_MASK | \ GDK_BUTTON3_MASK | \ GDK_BUTTON4_MASK | \ GDK_BUTTON5_MASK) void _gdk_windowing_got_event (GdkDisplay *display, GList *event_link, GdkEvent *event, gulong serial) { GdkSurface *event_surface; gboolean unlink_event = FALSE; GdkDeviceGrabInfo *button_release_grab; GdkPointerSurfaceInfo *pointer_info = NULL; GdkDevice *device; GdkEventType type; _gdk_display_update_last_event (display, event); device = gdk_event_get_device (event); if (device) { if (gdk_device_get_source (device) != GDK_SOURCE_KEYBOARD && gdk_device_get_source (device) != GDK_SOURCE_TABLET_PAD) { pointer_info = _gdk_display_get_pointer_info (display, device); pointer_info->last_physical_device = device; } _gdk_display_device_grab_update (display, device, serial); } event_surface = gdk_event_get_surface (event); if (!event_surface) goto out; type = gdk_event_get_event_type (event); if (type == GDK_ENTER_NOTIFY) _gdk_display_set_surface_under_pointer (display, device, event_surface); else if (type == GDK_LEAVE_NOTIFY) _gdk_display_set_surface_under_pointer (display, device, NULL); if (type == GDK_BUTTON_PRESS) { GdkSurface *grab_surface; gboolean owner_events; if (!gdk_device_grab_info (display, device, &grab_surface, &owner_events)) { _gdk_display_add_device_grab (display, device, event_surface, FALSE, GDK_ALL_EVENTS_MASK, serial, gdk_event_get_time (event), TRUE); _gdk_display_device_grab_update (display, device, serial); } } else if (type == GDK_BUTTON_RELEASE || type == GDK_TOUCH_CANCEL || type == GDK_TOUCH_END) { if (type == GDK_BUTTON_RELEASE || gdk_event_get_pointer_emulated (event)) { button_release_grab = _gdk_display_has_device_grab (display, device, serial); if (button_release_grab && button_release_grab->implicit && (gdk_event_get_modifier_state (event) & GDK_ANY_BUTTON_MASK & ~(GDK_BUTTON1_MASK << (gdk_button_event_get_button (event) - 1))) == 0) { button_release_grab->serial_end = serial; button_release_grab->implicit_ungrab = FALSE; _gdk_display_device_grab_update (display, device, serial); } } } out: if (unlink_event) { _gdk_event_queue_remove_link (display, event_link); g_list_free_1 (event_link); gdk_event_unref (event); } /* This does two things - first it sees if there are motions at the * end of the queue that can be compressed. Second, if there is just * a single motion that won't be dispatched because it is a compression * candidate it queues up flushing the event queue. */ _gdk_event_queue_handle_motion_compression (display); gdk_event_queue_handle_scroll_compression (display); } /** * gdk_surface_create_similar_surface: * @surface: surface to make new surface similar to * @content: the content for the new surface * @width: width of the new surface * @height: height of the new surface * * Create a new surface that is as compatible as possible with the * given @surface. For example the new surface will have the same * fallback resolution and font options as @surface. Generally, the new * surface will also use the same backend as @surface, unless that is * not possible for some reason. The type of the returned surface may * be examined with cairo_surface_get_type(). * * Initially the surface contents are all 0 (transparent if contents * have transparency, black otherwise.) * * Returns: a pointer to the newly allocated surface. The caller * owns the surface and should call cairo_surface_destroy() when done * with it. * * This function always returns a valid pointer, but it will return a * pointer to a “nil” surface if @other is already in an error state * or any other error occurs. **/ cairo_surface_t * gdk_surface_create_similar_surface (GdkSurface * surface, cairo_content_t content, int width, int height) { cairo_surface_t *similar_surface; int scale; g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); scale = gdk_surface_get_scale_factor (surface); similar_surface = cairo_image_surface_create (content == CAIRO_CONTENT_COLOR ? CAIRO_FORMAT_RGB24 : content == CAIRO_CONTENT_ALPHA ? CAIRO_FORMAT_A8 : CAIRO_FORMAT_ARGB32, width * scale, height * scale); cairo_surface_set_device_scale (similar_surface, scale, scale); return similar_surface; } /* This function is called when the XWindow is really gone. */ void gdk_surface_destroy_notify (GdkSurface *surface) { GDK_SURFACE_GET_CLASS (surface)->destroy_notify (surface); } /** * gdk_drag_begin: * @surface: the source surface for this drag * @device: the device that controls this drag * @content: (transfer none): the offered content * @actions: the actions supported by this drag * @dx: the x offset to @device's position where the drag nominally started * @dy: the y offset to @device's position where the drag nominally started * * Starts a drag and creates a new drag context for it. * * This function is called by the drag source. After this call, you * probably want to set up the drag icon using the surface returned * by gdk_drag_get_drag_surface(). * * This function returns a reference to the GdkDrag object, but GTK * keeps its own reference as well, as long as the DND operation is * going on. * * Note: if @actions include %GDK_ACTION_MOVE, you need to listen for * the #GdkDrag::dnd-finished signal and delete the data at the source * if gdk_drag_get_selected_action() returns %GDK_ACTION_MOVE. * * Returns: (transfer full) (nullable): a newly created #GdkDrag or * %NULL on error. */ GdkDrag * gdk_drag_begin (GdkSurface *surface, GdkDevice *device, GdkContentProvider *content, GdkDragAction actions, double dx, double dy) { g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); g_return_val_if_fail (GDK_IS_DEVICE (device), NULL); g_return_val_if_fail (surface->display == gdk_device_get_display (device), NULL); g_return_val_if_fail (GDK_IS_CONTENT_PROVIDER (content), NULL); return GDK_SURFACE_GET_CLASS (surface)->drag_begin (surface, device, content, actions, dx, dy); } static void gdk_surface_ensure_motion (GdkSurface *surface) { GdkDisplay *display; GdkSeat *seat; GdkDevice *device; GdkEvent *event; double x, y; GdkModifierType state; if (!surface->request_motion) return; surface->request_motion = FALSE; display = gdk_surface_get_display (surface); seat = gdk_display_get_default_seat (display); if (!seat) return; device = gdk_seat_get_pointer (seat); if (!gdk_surface_get_device_position (surface, device, &x, &y, &state)) return; event = gdk_motion_event_new (surface, device, NULL, GDK_CURRENT_TIME, state, x, y, NULL); gdk_surface_handle_event (event); gdk_event_unref (event); } static void gdk_surface_flush_events (GdkFrameClock *clock, void *data) { GdkSurface *surface = GDK_SURFACE (data); _gdk_event_queue_flush (surface->display); gdk_surface_ensure_motion (surface); _gdk_display_pause_events (surface->display); gdk_frame_clock_request_phase (clock, GDK_FRAME_CLOCK_PHASE_RESUME_EVENTS); surface->frame_clock_events_paused = TRUE; } static void gdk_surface_resume_events (GdkFrameClock *clock, void *data) { GdkSurface *surface = GDK_SURFACE (data); if (surface->frame_clock_events_paused) { _gdk_display_unpause_events (surface->display); surface->frame_clock_events_paused = FALSE; } } static void gdk_surface_set_frame_clock (GdkSurface *surface, GdkFrameClock *clock) { g_return_if_fail (GDK_IS_SURFACE (surface)); g_return_if_fail (clock == NULL || GDK_IS_FRAME_CLOCK (clock)); if (clock == surface->frame_clock) return; if (clock) { g_object_ref (clock); g_signal_connect (G_OBJECT (clock), "flush-events", G_CALLBACK (gdk_surface_flush_events), surface); g_signal_connect (G_OBJECT (clock), "resume-events", G_CALLBACK (gdk_surface_resume_events), surface); g_signal_connect (G_OBJECT (clock), "paint", G_CALLBACK (gdk_surface_paint_on_clock), surface); if (surface->update_freeze_count == 0) _gdk_frame_clock_inhibit_freeze (clock); } if (surface->frame_clock) { if (surface->frame_clock_events_paused) gdk_surface_resume_events (surface->frame_clock, G_OBJECT (surface)); g_signal_handlers_disconnect_by_func (G_OBJECT (surface->frame_clock), G_CALLBACK (gdk_surface_flush_events), surface); g_signal_handlers_disconnect_by_func (G_OBJECT (surface->frame_clock), G_CALLBACK (gdk_surface_resume_events), surface); g_signal_handlers_disconnect_by_func (G_OBJECT (surface->frame_clock), G_CALLBACK (gdk_surface_paint_on_clock), surface); if (surface->update_freeze_count == 0) _gdk_frame_clock_uninhibit_freeze (surface->frame_clock); g_object_unref (surface->frame_clock); } surface->frame_clock = clock; } /** * gdk_surface_get_frame_clock: * @surface: surface to get frame clock for * * Gets the frame clock for the surface. The frame clock for a surface * never changes unless the surface is reparented to a new toplevel * surface. * * Returns: (transfer none): the frame clock */ GdkFrameClock* gdk_surface_get_frame_clock (GdkSurface *surface) { g_return_val_if_fail (GDK_IS_SURFACE (surface), NULL); return surface->frame_clock; } /** * gdk_surface_get_scale_factor: * @surface: surface to get scale factor for * * Returns the internal scale factor that maps from surface coordinates * to the actual device pixels. On traditional systems this is 1, but * on very high density outputs this can be a higher value (often 2). * * A higher value means that drawing is automatically scaled up to * a higher resolution, so any code doing drawing will automatically look * nicer. However, if you are supplying pixel-based data the scale * value can be used to determine whether to use a pixel resource * with higher resolution data. * * The scale of a surface may change during runtime, if this happens * a configure event will be sent to the toplevel surface. * * Returns: the scale factor */ int gdk_surface_get_scale_factor (GdkSurface *surface) { GdkSurfaceClass *class; g_return_val_if_fail (GDK_IS_SURFACE (surface), 1); if (GDK_SURFACE_DESTROYED (surface)) return 1; class = GDK_SURFACE_GET_CLASS (surface); if (class->get_scale_factor) return class->get_scale_factor (surface); return 1; } /* Returns the *real* unscaled size, which may be a fractional size in surface scale coordinates. We need this to properly handle GL coordinates which are y-flipped in the real coordinates. */ void gdk_surface_get_unscaled_size (GdkSurface *surface, int *unscaled_width, int *unscaled_height) { GdkSurfaceClass *class; int scale; g_return_if_fail (GDK_IS_SURFACE (surface)); class = GDK_SURFACE_GET_CLASS (surface); if (class->get_unscaled_size) { class->get_unscaled_size (surface, unscaled_width, unscaled_height); return; } scale = gdk_surface_get_scale_factor (surface); if (unscaled_width) *unscaled_width = surface->width * scale; if (unscaled_height) *unscaled_height = surface->height * scale; } /** * gdk_surface_set_opaque_region: * @surface: a top-level or non-native #GdkSurface * @region: (allow-none): a region, or %NULL * * For optimisation purposes, compositing window managers may * like to not draw obscured regions of surfaces, or turn off blending * during for these regions. With RGB windows with no transparency, * this is just the shape of the window, but with ARGB32 windows, the * compositor does not know what regions of the window are transparent * or not. * * This function only works for toplevel surfaces. * * GTK will update this property automatically if * the @surface background is opaque, as we know where the opaque regions * are. If your surface background is not opaque, please update this * property in your #GtkWidgetClass.css_changed() handler. */ void gdk_surface_set_opaque_region (GdkSurface *surface, cairo_region_t *region) { GdkSurfaceClass *class; g_return_if_fail (GDK_IS_SURFACE (surface)); g_return_if_fail (!GDK_SURFACE_DESTROYED (surface)); if (cairo_region_equal (surface->opaque_region, region)) return; g_clear_pointer (&surface->opaque_region, cairo_region_destroy); if (region != NULL) surface->opaque_region = cairo_region_reference (region); class = GDK_SURFACE_GET_CLASS (surface); if (class->set_opaque_region) class->set_opaque_region (surface, region); } /** * gdk_surface_set_shadow_width: * @surface: a #GdkSurface * @left: The left extent * @right: The right extent * @top: The top extent * @bottom: The bottom extent * * Newer GTK windows using client-side decorations use extra geometry * around their frames for effects like shadows and invisible borders. * Window managers that want to maximize windows or snap to edges need * to know where the extents of the actual frame lie, so that users * don’t feel like windows are snapping against random invisible edges. * * Note that this property is automatically updated by GTK, so this * function should only be used by applications which do not use GTK * to create toplevel surfaces. */ void gdk_surface_set_shadow_width (GdkSurface *surface, int left, int right, int top, int bottom) { GdkSurfaceClass *class; g_return_if_fail (GDK_IS_SURFACE (surface)); g_return_if_fail (!GDK_SURFACE_DESTROYED (surface)); g_return_if_fail (left >= 0 && right >= 0 && top >= 0 && bottom >= 0); if (surface->shadow_left == left && surface->shadow_right == right && surface->shadow_top == top && surface->shadow_bottom == bottom) return; surface->shadow_top = top; surface->shadow_left = left; surface->shadow_right = right; surface->shadow_bottom = bottom; class = GDK_SURFACE_GET_CLASS (surface); if (class->set_shadow_width) class->set_shadow_width (surface, left, right, top, bottom); } void gdk_surface_set_state (GdkSurface *surface, GdkToplevelState new_state) { gboolean was_mapped, mapped; gboolean was_sticky, sticky; g_return_if_fail (GDK_IS_SURFACE (surface)); if (new_state == surface->state) return; /* No actual work to do, nothing changed. */ /* Actually update the field in GdkSurface, this is sort of an odd * place to do it, but seems like the safest since it ensures we expose no * inconsistent state to the user. */ was_mapped = GDK_SURFACE_IS_MAPPED (surface); was_sticky = GDK_SURFACE_IS_STICKY (surface); surface->state = new_state; mapped = GDK_SURFACE_IS_MAPPED (surface); sticky = GDK_SURFACE_IS_STICKY (surface); if (GDK_IS_TOPLEVEL (surface)) g_object_notify (G_OBJECT (surface), "state"); if (was_mapped != mapped) g_object_notify_by_pspec (G_OBJECT (surface), properties[PROP_MAPPED]); if (was_sticky != sticky) g_object_notify (G_OBJECT (surface), "sticky"); } void gdk_synthesize_surface_state (GdkSurface *surface, GdkToplevelState unset_flags, GdkToplevelState set_flags) { gdk_surface_set_state (surface, (surface->state | set_flags) & ~unset_flags); } static void hide_popup_chain (GdkSurface *surface) { GdkSurface *parent; gdk_surface_hide (surface); parent = surface->parent; if (parent->autohide) hide_popup_chain (parent); } static gboolean check_autohide (GdkEvent *event) { GdkDisplay *display; GdkDevice *device; GdkSurface *grab_surface; switch ((guint) gdk_event_get_event_type (event)) { case GDK_BUTTON_PRESS: #if 0 // FIXME: we need to ignore the release that is paired // with the press starting the grab - due to implicit // grabs, it will be delivered to the same place as the // press, and will cause the auto dismissal to be triggered. case GDK_BUTTON_RELEASE: #endif case GDK_TOUCH_BEGIN: case GDK_TOUCH_END: case GDK_TOUCH_CANCEL: case GDK_TOUCHPAD_SWIPE: case GDK_TOUCHPAD_PINCH: display = gdk_event_get_display (event); device = gdk_event_get_device (event); if (gdk_device_grab_info (display, device, &grab_surface, NULL)) { if (grab_surface != gdk_event_get_surface (event) && grab_surface->autohide) { hide_popup_chain (grab_surface); return TRUE; } } break; default:; } return FALSE; } static inline void add_event_mark (GdkEvent *event, gint64 time, gint64 end_time) { #ifdef HAVE_SYSPROF char *message = NULL; const char *kind; GEnumClass *class; GEnumValue *value; GdkEventType event_type; event_type = gdk_event_get_event_type (event); class = g_type_class_ref (GDK_TYPE_EVENT_TYPE); value = g_enum_get_value (class, event_type); g_type_class_unref (class); kind = value ? value->value_nick : "event"; switch ((int) event_type) { case GDK_MOTION_NOTIFY: { double x, y; gdk_event_get_position (event, &x, &y); message = g_strdup_printf ("%s {x=%lf, y=%lf, state=0x%x}", kind, x, y, gdk_event_get_modifier_state (event)); break; } case GDK_BUTTON_PRESS: case GDK_BUTTON_RELEASE: { double x, y; gdk_event_get_position (event, &x, &y); message = g_strdup_printf ("%s {button=%u, x=%lf, y=%lf, state=0x%x}", kind, gdk_button_event_get_button (event), x, y, gdk_event_get_modifier_state (event)); break; } case GDK_KEY_PRESS: case GDK_KEY_RELEASE: { message = g_strdup_printf ("%s {keyval=%u, state=0x%x, keycode=%u layout=%u level=%u is_modifier=%u}", kind, gdk_key_event_get_keyval (event), gdk_event_get_modifier_state (event), gdk_key_event_get_keycode (event), gdk_key_event_get_layout (event), gdk_key_event_get_level (event), gdk_key_event_is_modifier (event)); break; } case GDK_CONFIGURE: { int width, height; gdk_configure_event_get_size (event, &width, &height); message = g_strdup_printf ("%s {width=%d, height=%d}", kind, width, height); break; } case GDK_ENTER_NOTIFY: case GDK_LEAVE_NOTIFY: case GDK_TOUCHPAD_SWIPE: case GDK_TOUCHPAD_PINCH: case GDK_SCROLL: case GDK_DRAG_ENTER: case GDK_DRAG_LEAVE: case GDK_DRAG_MOTION: case GDK_DROP_START: case GDK_TOUCH_BEGIN: case GDK_TOUCH_UPDATE: case GDK_TOUCH_END: case GDK_TOUCH_CANCEL: case GDK_PAD_BUTTON_PRESS: case GDK_PAD_BUTTON_RELEASE: case GDK_PAD_RING: case GDK_PAD_STRIP: case GDK_PAD_GROUP_MODE: case GDK_GRAB_BROKEN: case GDK_DELETE: case GDK_FOCUS_CHANGE: case GDK_PROXIMITY_IN: case GDK_PROXIMITY_OUT: case GDK_EVENT_LAST: default: break; } gdk_profiler_add_mark (time, end_time - time, "event", message ? message : kind); g_free (message); #endif } gboolean gdk_surface_handle_event (GdkEvent *event) { gint64 begin_time = GDK_PROFILER_CURRENT_TIME; gboolean handled = FALSE; if (check_autohide (event)) return TRUE; if (gdk_event_get_event_type (event) == GDK_CONFIGURE) { int width, height; gdk_configure_event_get_size (event, &width, &height); g_signal_emit (gdk_event_get_surface (event), signals[SIZE_CHANGED], 0, width, height); handled = TRUE; } else { GdkSurface *surface = gdk_event_get_surface (event); if (gdk_event_get_event_type (event) == GDK_MOTION_NOTIFY) surface->request_motion = FALSE; g_signal_emit (surface, signals[EVENT], 0, event, &handled); } if (GDK_PROFILER_IS_RUNNING) add_event_mark (event, begin_time, GDK_PROFILER_CURRENT_TIME); return handled; } /* * gdk_surface_request_motion: * @surface: a #GdkSurface * * Request that the next frame cycle should deliver a motion * event for @surface if the pointer is over it, regardless * whether the pointer has moved or not. This is used by GTK * after moving widgets around. */ void gdk_surface_request_motion (GdkSurface *surface) { GdkFrameClock *frame_clock; surface->request_motion = TRUE; frame_clock = gdk_surface_get_frame_clock (surface); if (frame_clock) gdk_frame_clock_request_phase (frame_clock, GDK_FRAME_CLOCK_PHASE_FLUSH_EVENTS); } /** * gdk_surface_translate_coordinates: * @from: the origin surface * @to: the target surface * @x: coordinates to translate * @y: coordinates to translate * * Translates the given coordinates from being * relative to the @from surface to being relative * to the @to surface. * * Note that this only works if @to and @from are * popups or transient-for to the same toplevel * (directly or indirectly). * * Returns: %TRUE if the coordinates were successfully * translated */ gboolean gdk_surface_translate_coordinates (GdkSurface *from, GdkSurface *to, double *x, double *y) { int x1, y1, x2, y2; GdkSurface *f, *t; x1 = 0; y1 = 0; f = from; while (f->parent) { x1 += f->x; y1 += f->y; f = f->parent; } x2 = 0; y2 = 0; t = to; while (t->parent) { x2 += t->x; y2 += t->y; t = t->parent; } if (f != t) return FALSE; *x += x1 - x2; *y += y1 - y2; return TRUE; } GdkSeat * gdk_surface_get_seat_from_event (GdkSurface *surface, GdkEvent *event) { if (event) { GdkSeat *seat = NULL; seat = gdk_event_get_seat (event); if (seat) return seat; } return gdk_display_get_default_seat (surface->display); } void gdk_surface_enter_monitor (GdkSurface *surface, GdkMonitor *monitor) { g_signal_emit (surface, signals[ENTER_MONITOR], 0, monitor); } void gdk_surface_leave_monitor (GdkSurface *surface, GdkMonitor *monitor) { g_signal_emit (surface, signals[LEAVE_MONITOR], 0, monitor); }