Window

A GdkWindow is a (usually) rectangular region on the screen. It's a low-level object, used to implement high-level objects such as GtkWidget and GtkWindow on the GTK+ level. A GtkWindow is a toplevel window, the thing a user might think of as a "window" with a titlebar and so on; a GtkWindow may contain many GdkWindows. For example, each GtkButton has a GdkWindow associated with it.

Composited Windows

Normally, the windowing system takes care of rendering the contents of a child window onto its parent window. This mechanism can be intercepted by calling gdk_window_set_composited() on the child window. For a composited window it is the responsibility of the application to render the window contents at the right spot.

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Offscreen Windows

Offscreen windows are more general than composited windows, since they allow not only to modify the rendering of the child window onto its parent, but also to apply coordinate transformations.

To integrate an offscreen window into a window hierarchy, one has to call gdk_offscreen_window_set_embedder() and handle a number of signals. The "pick-embedded-child" signal on the embedder window is used to select an offscreen child at given coordinates, and the "to-embedder" and "from-embedder" signals on the offscreen window are used to translate coordinates between the embedder and the offscreen window.

For rendering an offscreen window onto its embedder, the contents of the offscreen window are available as a surface, via gdk_offscreen_window_get_surface().

class Window : ObjectG {}

Constructors

this
this(GdkWindow* gdkWindow)

Sets our main struct and passes it to the parent class

this
this(Window parent, GdkWindowAttr* attributes, int attributesMask)

Creates a new GdkWindow using the attributes from attributes. See GdkWindowAttr and GdkWindowAttributesType for more details. Note: to use this on displays other than the default display, parent must be specified.

Members

Functions

addFilter
void addFilter(GdkFilterFunc funct, void* data)

Adds an event filter to window, allowing you to intercept events before they reach GDK. This is a low-level operation and makes it easy to break GDK and/or GTK+, so you have to know what you're doing. Pass NULL for window to get all events for all windows, instead of events for a specific window. If you are interested in X GenericEvents, bear in mind that XGetEventData() has been already called on the event, and XFreeEventData() must not be called within function.

addOnCreateSurface
void addOnCreateSurface(Surface delegate(gint, gint, Window) dlg, ConnectFlags connectFlags)

The ::create-surface signal is emitted when an offscreen window needs its surface (re)created, which happens either when the the window is first drawn to, or when the window is being resized. The first signal handler that returns a non-NULL surface will stop any further signal emission, and its surface will be used. Note that it is not possible to access the window's previous surface from within any callback of this signal. Calling gdk_offscreen_window_get_surface() will lead to a crash. Since 3.0

addOnFromEmbedder
void addOnFromEmbedder(void delegate(gdouble, gdouble, void*, void*, Window) dlg, ConnectFlags connectFlags)

The ::from-embedder signal is emitted to translate coordinates in the embedder of an offscreen window to the offscreen window. See also "to-embedder". Since 2.18

addOnPickEmbeddedChild
void addOnPickEmbeddedChild(Window delegate(gdouble, gdouble, Window) dlg, ConnectFlags connectFlags)

The ::pick-embedded-child signal is emitted to find an embedded child at the given position. Since 2.18

addOnToEmbedder
void addOnToEmbedder(void delegate(gdouble, gdouble, void*, void*, Window) dlg, ConnectFlags connectFlags)

The ::to-embedder signal is emitted to translate coordinates in an offscreen window to its embedder. See also "from-embedder". Since 2.18

beep
void beep()

Emits a short beep associated to window in the appropriate display, if supported. Otherwise, emits a short beep on the display just as gdk_display_beep(). Since 2.12

beginMoveDrag
void beginMoveDrag(int button, int rootX, int rootY, uint timestamp)

Begins a window move operation (for a toplevel window). This function assumes that the drag is controlled by the client pointer device, use gdk_window_begin_move_drag_for_device() to begin a drag with a different device.

beginMoveDragForDevice
void beginMoveDragForDevice(Device device, int button, int rootX, int rootY, uint timestamp)

Begins a window move operation (for a toplevel window). You might use this function to implement a "window move grip," for example. The function works best with window managers that support the Extended Window Manager Hints, but has a fallback implementation for other window managers.

beginPaintRect
void beginPaintRect(Rectangle rectangle)

A convenience wrapper around gdk_window_begin_paint_region() which creates a rectangular region for you. See gdk_window_begin_paint_region() for details.

beginPaintRegion
void beginPaintRegion(Region region)

Indicates that you are beginning the process of redrawing region. A backing store (offscreen buffer) large enough to contain region will be created. The backing store will be initialized with the background color or background surface for window. Then, all drawing operations performed on window will be diverted to the backing store. When you call gdk_window_end_paint(), the backing store will be copied to window, making it visible onscreen. Only the part of window contained in region will be modified; that is, drawing operations are clipped to region. The net result of all this is to remove flicker, because the user sees the finished product appear all at once when you call gdk_window_end_paint(). If you draw to window directly without calling gdk_window_begin_paint_region(), the user may see flicker as individual drawing operations are performed in sequence. The clipping and background-initializing features of gdk_window_begin_paint_region() are conveniences for the programmer, so you can avoid doing that work yourself. When using GTK+, the widget system automatically places calls to gdk_window_begin_paint_region() and gdk_window_end_paint() around emissions of the expose_event signal. That is, if you're writing an expose event handler, you can assume that the exposed area in GdkEventExpose has already been cleared to the window background, is already set as the clip region, and already has a backing store. Therefore in most cases, application code need not call gdk_window_begin_paint_region(). (You can disable the automatic calls around expose events on a widget-by-widget basis by calling gtk_widget_set_double_buffered().) If you call this function multiple times before calling the matching gdk_window_end_paint(), the backing stores are pushed onto a stack. gdk_window_end_paint() copies the topmost backing store onscreen, subtracts the topmost region from all other regions in the stack, and pops the stack. All drawing operations affect only the topmost backing store in the stack. One matching call to gdk_window_end_paint() is required for each call to gdk_window_begin_paint_region().

beginResizeDrag
void beginResizeDrag(GdkWindowEdge edge, int button, int rootX, int rootY, uint timestamp)

Begins a window resize operation (for a toplevel window). This function assumes that the drag is controlled by the client pointer device, use gdk_window_begin_resize_drag_for_device() to begin a drag with a different device.

beginResizeDragForDevice
void beginResizeDragForDevice(GdkWindowEdge edge, Device device, int button, int rootX, int rootY, uint timestamp)

Begins a window resize operation (for a toplevel window). You might use this function to implement a "window resize grip," for example; in fact GtkStatusbar uses it. The function works best with window managers that support the Extended Window Manager Hints, but has a fallback implementation for other window managers.

configureFinished
void configureFinished()

Warning gdk_window_configure_finished has been deprecated since version 3.8 and should not be used in newly-written code. this function is no longer needed Does nothing, present only for compatiblity. Since 2.6

coordsFromParent
void coordsFromParent(double parentX, double parentY, double x, double y)

Transforms window coordinates from a parent window to a child window, where the parent window is the normal parent as returned by gdk_window_get_parent() for normal windows, and the window's embedder as returned by gdk_offscreen_window_get_embedder() for offscreen windows. For normal windows, calling this function is equivalent to subtracting the return values of gdk_window_get_position() from the parent coordinates. For offscreen windows however (which can be arbitrarily transformed), this function calls the GdkWindow::from-embedder: signal to translate the coordinates. You should always use this function when writing generic code that walks down a window hierarchy. See also: gdk_window_coords_to_parent() Since 2.22

coordsToParent
void coordsToParent(double x, double y, double parentX, double parentY)

Transforms window coordinates from a child window to its parent window, where the parent window is the normal parent as returned by gdk_window_get_parent() for normal windows, and the window's embedder as returned by gdk_offscreen_window_get_embedder() for offscreen windows. For normal windows, calling this function is equivalent to adding the return values of gdk_window_get_position() to the child coordinates. For offscreen windows however (which can be arbitrarily transformed), this function calls the GdkWindow::to-embedder: signal to translate the coordinates. You should always use this function when writing generic code that walks up a window hierarchy. See also: gdk_window_coords_from_parent() Since 2.22

createSimilarSurface
Surface createSimilarSurface(CairoContent content, int width, int height)

Create a new surface that is as compatible as possible with the given window. For example the new surface will have the same fallback resolution and font options as window. Generally, the new surface will also use the same backend as window, 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.) Since 2.22

deiconify
void deiconify()

Attempt to deiconify (unminimize) window. On X11 the window manager may choose to ignore the request to deiconify. When using GTK+, use gtk_window_deiconify() instead of the GdkWindow variant. Or better yet, you probably want to use gtk_window_present(), which raises the window, focuses it, unminimizes it, and puts it on the current desktop.

destroy
void destroy()

Destroys the window system resources associated with window and decrements window's reference count. The window system resources for all children of window are also destroyed, but the children's reference counts are not decremented. Note that a window will not be destroyed automatically when its reference count reaches zero. You must call this function yourself before that happens.

enableSynchronizedConfigure
void enableSynchronizedConfigure()

Warning gdk_window_enable_synchronized_configure has been deprecated since version 3.8 and should not be used in newly-written code. this function is no longer needed Does nothing, present only for compatiblity. Since 2.6

endPaint
void endPaint()

Indicates that the backing store created by the most recent call to gdk_window_begin_paint_region() should be copied onscreen and deleted, leaving the next-most-recent backing store or no backing store at all as the active paint region. See gdk_window_begin_paint_region() for full details. It is an error to call this function without a matching gdk_window_begin_paint_region() first.

ensureNative
int ensureNative()

Tries to ensure that there is a window-system native window for this GdkWindow. This may fail in some situations, returning FALSE. Offscreen window and children of them can never have native windows. Some backends may not support native child windows. Since 2.18

flush
void flush()

Flush all outstanding cached operations on a window, leaving the window in a state which reflects all that has been drawn before. Gdk uses multiple kinds of caching to get better performance and nicer drawing. For instance, during exposes all paints to a window using double buffered rendering are keep on a surface until the last window has been exposed. Normally this should be completely invisible to applications, as we automatically flush the windows when required, but this might be needed if you for instance mix direct native drawing with gdk drawing. For Gtk widgets that don't use double buffering this will be called automatically before sending the expose event. Since 2.18

focus
void focus(uint timestamp)

Sets keyboard focus to window. In most cases, gtk_window_present() should be used on a GtkWindow, rather than calling this function.

freezeUpdates
void freezeUpdates()

Temporarily freezes a window such that it won't receive expose events. The window will begin receiving expose events again when gdk_window_thaw_updates() is called. If gdk_window_freeze_updates() has been called more than once, gdk_window_thaw_updates() must be called an equal number of times to begin processing exposes.

fullscreen
void fullscreen()

Moves the window into fullscreen mode. This means the window covers the entire screen and is above any panels or task bars. If the window was already fullscreen, then this function does nothing. On X11, asks the window manager to put window in a fullscreen state, if the window manager supports this operation. Not all window managers support this, and some deliberately ignore it or don't have a concept of "fullscreen"; so you can't rely on the fullscreenification actually happening. But it will happen with most standard window managers, and GDK makes a best effort to get it to happen. Since 2.2

geometryChanged
void geometryChanged()

This function informs GDK that the geometry of an embedded offscreen window has changed. This is necessary for GDK to keep track of which offscreen window the pointer is in. Since 2.18

getAcceptFocus
int getAcceptFocus()

Determines whether or not the desktop environment shuld be hinted that the window does not want to receive input focus. Since 2.22

getBackgroundPattern
Pattern getBackgroundPattern()

Gets the pattern used to clear the background on window. If window does not have its own background and reuses the parent's, NULL is returned and you'll have to query it yourself. Since 2.22

getChildren
ListG getChildren()

Gets the list of children of window known to GDK. This function only returns children created via GDK, so for example it's useless when used with the root window; it only returns windows an application created itself. The returned list must be freed, but the elements in the list need not be.

getChildrenWithUserData
ListG getChildrenWithUserData(void* userData)

Gets the list of children of window known to GDK with a particular user_data set on it. The returned list must be freed, but the elements in the list need not be. The list is returned in (relative) stacking order, i.e. the lowest window is first.

getClipRegion
Region getClipRegion()

Computes the region of a window that potentially can be written to by drawing primitives. This region may not take into account other factors such as if the window is obscured by other windows, but no area outside of this region will be affected by drawing primitives.

getComposited
int getComposited()

Determines whether window is composited. See gdk_window_set_composited(). Since 2.22

getCursor
Cursor getCursor()

Retrieves a GdkCursor pointer for the cursor currently set on the specified GdkWindow, or NULL. If the return value is NULL then there is no custom cursor set on the specified window, and it is using the cursor for its parent window. Since 2.18

getDecorations
int getDecorations(GdkWMDecoration decorations)

Returns the decorations set on the GdkWindow with gdk_window_set_decorations().

getDeviceCursor
Cursor getDeviceCursor(Device device)

Retrieves a GdkCursor pointer for the device currently set on the specified GdkWindow, or NULL. If the return value is NULL then there is no custom cursor set on the specified window, and it is using the cursor for its parent window.

getDeviceEvents
GdkEventMask getDeviceEvents(Device device)

Returns the event mask for window corresponding to an specific device.

getDevicePosition
Window getDevicePosition(Device device, int x, int y, GdkModifierType mask)

Obtains the current device position and modifier state. The position is given in coordinates relative to the upper left corner of window. Use gdk_window_get_device_position_double() if you need subpixel precision.

getDevicePositionDouble
Window getDevicePositionDouble(Device device, double x, double y, GdkModifierType mask)

Obtains the current device position in doubles and modifier state. The position is given in coordinates relative to the upper left corner of window.

getDisplay
Display getDisplay()

Gets the GdkDisplay associated with a GdkWindow. Since 2.24

getEffectiveParent
Window getEffectiveParent()

Obtains the parent of window, as known to GDK. Works like gdk_window_get_parent() for normal windows, but returns the window's embedder for offscreen windows. See also: gdk_offscreen_window_get_embedder() Since 2.22

getEffectiveToplevel
Window getEffectiveToplevel()

Gets the toplevel window that's an ancestor of window. Works like gdk_window_get_toplevel(), but treats an offscreen window's embedder as its parent, using gdk_window_get_effective_parent(). See also: gdk_offscreen_window_get_embedder() Since 2.22

getEvents
GdkEventMask getEvents()

Gets the event mask for window for all master input devices. See gdk_window_set_events().

getFocusOnMap
int getFocusOnMap()

Determines whether or not the desktop environment should be hinted that the window does not want to receive input focus when it is mapped. Since 2.22

getFrameClock
FrameClock getFrameClock()

Gets the frame clock for the window. The frame clock for a window never changes unless the window is reparented to a new toplevel window.

getFrameExtents
void getFrameExtents(Rectangle rect)

Obtains the bounding box of the window, including window manager titlebar/borders if any. The frame position is given in root window coordinates. To get the position of the window itself (rather than the frame) in root window coordinates, use gdk_window_get_origin().

getFullscreenMode
GdkFullscreenMode getFullscreenMode()

Obtains the GdkFullscreenMode of the window.

getGeometry
void getGeometry(int x, int y, int width, int height)

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 window of window, which for toplevels usually means relative to the window 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 window; this may be out-of-sync with the position of window delivered in the most-recently-processed GdkEventConfigure. gdk_window_get_position() in contrast gets the position from the most recent configure event. Note If window is not a toplevel, it is much better to call gdk_window_get_position(), gdk_window_get_width() and gdk_window_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_window_get_geometry() is restricted to the 16-bit coordinates of X11.

getGroup
Window getGroup()

Returns the group leader window for window. See gdk_window_set_group(). Since 2.4

getHeight
int getHeight()

Returns the height of the given window. On the X11 platform the returned size is the size reported in the most-recently-processed configure event, rather than the current size on the X server. Since 2.24

getModalHint
int getModalHint()

Determines whether or not the window manager is hinted that window has modal behaviour. Since 2.22

getOrigin
int getOrigin(int x, int y)

Obtains the position of a window in root window coordinates. (Compare with gdk_window_get_position() and gdk_window_get_geometry() which return the position of a window relative to its parent window.)

getParent
Window getParent()

Obtains the parent of window, as known to GDK. Does not query the X server; thus this returns the parent as passed to gdk_window_new(), not the actual parent. This should never matter unless you're using Xlib calls mixed with GDK calls on the X11 platform. It may also matter for toplevel windows, because the window manager may choose to reparent them. Note that you should use gdk_window_get_effective_parent() when writing generic code that walks up a window hierarchy, because gdk_window_get_parent() will most likely not do what you expect if there are offscreen windows in the hierarchy.

getPointer
Window getPointer(int x, int y, GdkModifierType mask)

Warning gdk_window_get_pointer has been deprecated since version 3.0 and should not be used in newly-written code. Use gdk_window_get_device_position() instead. Obtains the current pointer position and modifier state. The position is given in coordinates relative to the upper left corner of window.

getPosition
void getPosition(int x, int y)

Obtains the position of the window as reported in the most-recently-processed GdkEventConfigure. Contrast with gdk_window_get_geometry() which queries the X server for the current window position, regardless of which events have been received or processed. The position coordinates are relative to the window's parent window.

getRootCoords
void getRootCoords(int x, int y, int rootX, int rootY)

Obtains the position of a window position in root window coordinates. This is similar to gdk_window_get_origin() but allows you go pass in any position in the window, not just the origin. Since 2.18

getRootOrigin
void getRootOrigin(int x, int y)

Obtains the top-left corner of the window manager frame in root window coordinates.

getScaleFactor
int getScaleFactor()

Returns the internal scale factor that maps from window coordiantes 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 window may change during runtime, if this happens a configure event will be sent to the toplevel window.

getScreen
Screen getScreen()

Gets the GdkScreen associated with a GdkWindow. Since 2.24

getSourceEvents
GdkEventMask getSourceEvents(GdkInputSource source)

Returns the event mask for window corresponding to the device class specified by source.

getState
GdkWindowState getState()

Gets the bitwise OR of the currently active window state flags, from the GdkWindowState enumeration.

getStruct
void* getStruct()

the main Gtk struct as a void*

getSupportMultidevice
int getSupportMultidevice()

Returns TRUE if the window is aware of the existence of multiple devices.

getToplevel
Window getToplevel()

Gets the toplevel window that's an ancestor of window. Any window type but GDK_WINDOW_CHILD is considered a toplevel window, as is a GDK_WINDOW_CHILD window that has a root window as parent. Note that you should use gdk_window_get_effective_toplevel() when you want to get to a window's toplevel as seen on screen, because gdk_window_get_toplevel() will most likely not do what you expect if there are offscreen windows in the hierarchy.

getTypeHint
GdkWindowTypeHint getTypeHint()

This function returns the type hint set for a window. Since 2.10

getUpdateArea
Region getUpdateArea()

Transfers ownership of the update area from window to the caller of the function. That is, after calling this function, window will no longer have an invalid/dirty region; the update area is removed from window and handed to you. If a window has no update area, gdk_window_get_update_area() returns NULL. You are responsible for calling cairo_region_destroy() on the returned region if it's non-NULL.

getUserData
void getUserData(void** data)

Retrieves the user data for window, which is normally the widget that window belongs to. See gdk_window_set_user_data().

getVisibleRegion
Region getVisibleRegion()

Computes the region of the window that is potentially visible. This does not necessarily take into account if the window is obscured by other windows, but no area outside of this region is visible.

getVisual
Visual getVisual()

Gets the GdkVisual describing the pixel format of window. Since 2.24

getWidth
int getWidth()

Returns the width of the given window. On the X11 platform the returned size is the size reported in the most-recently-processed configure event, rather than the current size on the X server. Since 2.24

getWindowStruct
GdkWindow* getWindowStruct()
Undocumented in source. Be warned that the author may not have intended to support it.
getWindowType
GdkWindowType getWindowType()

Gets the type of the window. See GdkWindowType.

hasNative
int hasNative()

Checks whether the window has a native window or not. Note that you can use gdk_window_ensure_native() if a native window is needed. Since 2.22

hide
void hide()

For toplevel windows, withdraws them, so they will no longer be known to the window manager; for all windows, unmaps them, so they won't be displayed. Normally done automatically as part of gtk_widget_hide().

iconify
void iconify()

Asks to iconify (minimize) window. The window manager may choose to ignore the request, but normally will honor it. Using gtk_window_iconify() is preferred, if you have a GtkWindow widget. This function only makes sense when window is a toplevel window.

inputShapeCombineRegion
void inputShapeCombineRegion(Region shapeRegion, int offsetX, int offsetY)

Like gdk_window_shape_combine_region(), but the shape applies only to event handling. Mouse events which happen while the pointer position corresponds to an unset bit in the mask will be passed on the window below window. An input shape is typically used with RGBA windows. The alpha channel of the window defines which pixels are invisible and allows for nicely antialiased borders, and the input shape controls where the window is "clickable". On the X11 platform, this requires version 1.1 of the shape extension. On the Win32 platform, this functionality is not present and the function does nothing. Since 2.10

invalidateMaybeRecurse
void invalidateMaybeRecurse(Region region, GdkWindowChildFunc childFunc, void* userData)

Adds region to the update area for window. The update area is the region that needs to be redrawn, or "dirty region." The call gdk_window_process_updates() sends one or more expose events to the window, which together cover the entire update area. An application would normally redraw the contents of window in response to those expose events. GDK will call gdk_window_process_all_updates() on your behalf whenever your program returns to the main loop and becomes idle, so normally there's no need to do that manually, you just need to invalidate regions that you know should be redrawn. The child_func parameter controls whether the region of each child window that intersects region will also be invalidated. Only children for which child_func returns TRUE will have the area invalidated.

invalidateRect
void invalidateRect(Rectangle* rect, int invalidateChildren)

A convenience wrapper around gdk_window_invalidate_region() which invalidates a rectangular region. See gdk_window_invalidate_region() for details.

invalidateRegion
void invalidateRegion(Region region, int invalidateChildren)

Adds region to the update area for window. The update area is the region that needs to be redrawn, or "dirty region." The call gdk_window_process_updates() sends one or more expose events to the window, which together cover the entire update area. An application would normally redraw the contents of window in response to those expose events. GDK will call gdk_window_process_all_updates() on your behalf whenever your program returns to the main loop and becomes idle, so normally there's no need to do that manually, you just need to invalidate regions that you know should be redrawn. The invalidate_children parameter controls whether the region of each child window that intersects region will also be invalidated. If FALSE, then the update area for child windows will remain unaffected. See gdk_window_invalidate_maybe_recurse if you need fine grained control over which children are invalidated.

isDestroyed
int isDestroyed()

Check to see if a window is destroyed.. Since 2.18

isInputOnly
int isInputOnly()

Determines whether or not the window is an input only window. Since 2.22

isShaped
int isShaped()

Determines whether or not the window is shaped. Since 2.22

isViewable
int isViewable()

Check if the window and all ancestors of the window are mapped. (This is not necessarily "viewable" in the X sense, since we only check as far as we have GDK window parents, not to the root window.)

isVisible
int isVisible()

Checks whether the window has been mapped (with gdk_window_show() or gdk_window_show_unraised()).

lower
void lower()

Lowers window to the bottom of the Z-order (stacking order), so that other windows with the same parent window appear above window. This is true whether or not the other windows are visible. If window is a toplevel, the window manager may choose to deny the request to move the window in the Z-order, gdk_window_lower() only requests the restack, does not guarantee it. Note that gdk_window_show() raises the window again, so don't call this function before gdk_window_show(). (Try gdk_window_show_unraised().)

maximize
void maximize()

Maximizes the window. If the window was already maximized, then this function does nothing. On X11, asks the window manager to maximize window, if the window manager supports this operation. Not all window managers support this, and some deliberately ignore it or don't have a concept of "maximized"; so you can't rely on the maximization actually happening. But it will happen with most standard window managers, and GDK makes a best effort to get it to happen. On Windows, reliably maximizes the window.

mergeChildInputShapes
void mergeChildInputShapes()

Merges the input shape masks for any child windows into the input shape mask for window. i.e. the union of all input masks for window and its children will become the new input mask for window. See gdk_window_input_shape_combine_region(). This function is distinct from gdk_window_set_child_input_shapes() because it includes window's input shape mask in the set of shapes to be merged. Since 2.10

mergeChildShapes
void mergeChildShapes()

Merges the shape masks for any child windows into the shape mask for window. i.e. the union of all masks for window and its children will become the new mask for window. See gdk_window_shape_combine_region(). This function is distinct from gdk_window_set_child_shapes() because it includes window's shape mask in the set of shapes to be merged.

move
void move(int x, int y)

Repositions a window relative to its parent window. For toplevel windows, window managers may ignore or modify the move; you should probably use gtk_window_move() on a GtkWindow widget anyway, instead of using GDK functions. For child windows, the move will reliably succeed. If you're also planning to resize the window, use gdk_window_move_resize() to both move and resize simultaneously, for a nicer visual effect.

moveRegion
void moveRegion(Region region, int dx, int dy)

Move the part of window indicated by region by dy pixels in the Y direction and dx pixels in the X direction. The portions of region that not covered by the new position of region are invalidated. Child windows are not moved. Since 2.8

moveResize
void moveResize(int x, int y, int width, int height)

Equivalent to calling gdk_window_move() and gdk_window_resize(), except that both operations are performed at once, avoiding strange visual effects. (i.e. the user may be able to see the window first move, then resize, if you don't use gdk_window_move_resize().)

offscreenWindowGetEmbedder
Window offscreenWindowGetEmbedder()

Gets the window that window is embedded in. Since 2.18

offscreenWindowGetSurface
Surface offscreenWindowGetSurface()

Gets the offscreen surface that an offscreen window renders into. If you need to keep this around over window resizes, you need to add a reference to it.

offscreenWindowSetEmbedder
void offscreenWindowSetEmbedder(Window embedder)

Sets window to be embedded in embedder. To fully embed an offscreen window, in addition to calling this function, it is also necessary to handle the "pick-embedded-child" signal on the embedder and the "to-embedder" and "from-embedder" signals on window. Since 2.18

peekChildren
ListG peekChildren()

Like gdk_window_get_children(), but does not copy the list of children, so the list does not need to be freed.

processUpdates
void processUpdates(int updateChildren)

Sends one or more expose events to window. The areas in each expose event will cover the entire update area for the window (see gdk_window_invalidate_region() for details). Normally GDK calls gdk_window_process_all_updates() on your behalf, so there's no need to call this function unless you want to force expose events to be delivered immediately and synchronously (vs. the usual case, where GDK delivers them in an idle handler). Occasionally this is useful to produce nicer scrolling behavior, for example.

raise
void raise()

Raises window to the top of the Z-order (stacking order), so that other windows with the same parent window appear below window. This is true whether or not the windows are visible. If window is a toplevel, the window manager may choose to deny the request to move the window in the Z-order, gdk_window_raise() only requests the restack, does not guarantee it.

registerDnd
void registerDnd()

Registers a window as a potential drop destination.

removeFilter
void removeFilter(GdkFilterFunc funct, void* data)

Remove a filter previously added with gdk_window_add_filter().

reparent
void reparent(Window newParent, int x, int y)

Reparents window into the given new_parent. The window being reparented will be unmapped as a side effect.

resize
void resize(int width, int height)

Resizes window; for toplevel windows, asks the window manager to resize the window. The window manager may not allow the resize. When using GTK+, use gtk_window_resize() instead of this low-level GDK function. Windows may not be resized below 1x1. If you're also planning to move the window, use gdk_window_move_resize() to both move and resize simultaneously, for a nicer visual effect.

restack
void restack(Window sibling, int above)

Changes the position of window in the Z-order (stacking order), so that it is above sibling (if above is TRUE) or below sibling (if above is FALSE). If sibling is NULL, then this either raises (if above is TRUE) or lowers the window. If window is a toplevel, the window manager may choose to deny the request to move the window in the Z-order, gdk_window_restack() only requests the restack, does not guarantee it. Since 2.18

scroll
void scroll(int dx, int dy)

Scroll the contents of window, both pixels and children, by the given amount. window itself does not move. Portions of the window that the scroll operation brings in from offscreen areas are invalidated. The invalidated region may be bigger than what would strictly be necessary. For X11, a minimum area will be invalidated if the window has no subwindows, or if the edges of the window's parent do not extend beyond the edges of the window. In other cases, a multi-step process is used to scroll the window which may produce temporary visual artifacts and unnecessary invalidations.

setAcceptFocus
void setAcceptFocus(int acceptFocus)

Setting accept_focus to FALSE hints the desktop environment that the window doesn't want to receive input focus. On X, it is the responsibility of the window manager to interpret this hint. ICCCM-compliant window manager usually respect it. Since 2.4

setBackground
void setBackground(Color color)

Warning gdk_window_set_background has been deprecated since version 3.4 and should not be used in newly-written code. Use gdk_window_set_background_rgba() instead. Sets the background color of window. (However, when using GTK+, set the background of a widget with gtk_widget_modify_bg() - if you're an application - or gtk_style_set_background() - if you're implementing a custom widget.) See also gdk_window_set_background_pattern().

setBackgroundPattern
void setBackgroundPattern(Pattern pattern)

Sets the background of window. A background of NULL means that the window will inherit its background form its parent window. The windowing system will normally fill a window with its background when the window is obscured then exposed.

setBackgroundRgba
void setBackgroundRgba(RGBA rgba)

Sets the background color of window. See also gdk_window_set_background_pattern().

setChildInputShapes
void setChildInputShapes()

Sets the input shape mask of window to the union of input shape masks for all children of window, ignoring the input shape mask of window itself. Contrast with gdk_window_merge_child_input_shapes() which includes the input shape mask of window in the masks to be merged. Since 2.10

setChildShapes
void setChildShapes()

Sets the shape mask of window to the union of shape masks for all children of window, ignoring the shape mask of window itself. Contrast with gdk_window_merge_child_shapes() which includes the shape mask of window in the masks to be merged.

setComposited
void setComposited(int composited)

Sets a GdkWindow as composited, or unsets it. Composited windows do not automatically have their contents drawn to the screen. Drawing is redirected to an offscreen buffer and an expose event is emitted on the parent of the composited window. It is the responsibility of the parent's expose handler to manually merge the off-screen content onto the screen in whatever way it sees fit. See ??? for an example. It only makes sense for child windows to be composited; see gdk_window_set_opacity() if you need translucent toplevel windows. An additional effect of this call is that the area of this window is no longer clipped from regions marked for invalidation on its parent. Draws done on the parent window are also no longer clipped by the child. This call is only supported on some systems (currently, only X11 with new enough Xcomposite and Xdamage extensions). You must call gdk_display_supports_composite() to check if setting a window as composited is supported before attempting to do so. Since 2.12

setCursor
void setCursor(Cursor cursor)

Sets the default mouse pointer for a GdkWindow. Use gdk_cursor_new_for_display() or gdk_cursor_new_from_pixbuf() to create the cursor. To make the cursor invisible, use GDK_BLANK_CURSOR. Passing NULL for the cursor argument to gdk_window_set_cursor() means that window will use the cursor of its parent window. Most windows should use this default.

setDecorations
void setDecorations(GdkWMDecoration decorations)

"Decorations" are the features the window manager adds to a toplevel GdkWindow. This function sets the traditional Motif window manager hints that tell the window manager which decorations you would like your window to have. Usually you should use gtk_window_set_decorated() on a GtkWindow instead of using the GDK function directly. The decorations argument is the logical OR of the fields in the GdkWMDecoration enumeration. If GDK_DECOR_ALL is included in the mask, the other bits indicate which decorations should be turned off. If GDK_DECOR_ALL is not included, then the other bits indicate which decorations should be turned on. Most window managers honor a decorations hint of 0 to disable all decorations, but very few honor all possible combinations of bits.

setDeviceCursor
void setDeviceCursor(Device device, Cursor cursor)

Sets a specific GdkCursor for a given device when it gets inside window. Use gdk_cursor_new_for_display() or gdk_cursor_new_from_pixbuf() to create the cursor. To make the cursor invisible, use GDK_BLANK_CURSOR. Passing NULL for the cursor argument to gdk_window_set_cursor() means that window will use the cursor of its parent window. Most windows should use this default.

setDeviceEvents
void setDeviceEvents(Device device, GdkEventMask eventMask)

Sets the event mask for a given device (Normally a floating device, not attached to any visible pointer) to window. For example, an event mask including GDK_BUTTON_PRESS_MASK means the window should report button press events. The event mask is the bitwise OR of values from the GdkEventMask enumeration.

setEvents
void setEvents(GdkEventMask eventMask)

The event mask for a window determines which events will be reported for that window from all master input devices. For example, an event mask including GDK_BUTTON_PRESS_MASK means the window should report button press events. The event mask is the bitwise OR of values from the GdkEventMask enumeration.

setFocusOnMap
void setFocusOnMap(int focusOnMap)

Setting focus_on_map to FALSE hints the desktop environment that the window doesn't want to receive input focus when it is mapped. focus_on_map should be turned off for windows that aren't triggered interactively (such as popups from network activity). On X, it is the responsibility of the window manager to interpret this hint. Window managers following the freedesktop.org window manager extension specification should respect it. Since 2.6

setFullscreenMode
void setFullscreenMode(GdkFullscreenMode mode)

Specifies whether the window should span over all monitors (in a multi-head setup) or only the current monitor when in fullscreen mode. The mode argument is from the GdkFullscreenMode enumeration. If GDK_FULLSCREEN_ON_ALL_MONITORS is specified, the fullscreen window will span over all monitors from the GdkScreen. On X11, searches through the list of monitors from the GdkScreen the ones which delimit the 4 edges of the entire GdkScreen and will ask the window manager to span the window over these monitors. If the XINERAMA extension is not available or not usable, this function has no effect. Not all window managers support this, so you can't rely on the fullscreen window to span over the multiple monitors when GDK_FULLSCREEN_ON_ALL_MONITORS is specified.

setFunctions
void setFunctions(GdkWMFunction functions)

Sets hints about the window management functions to make available via buttons on the window frame. On the X backend, this function sets the traditional Motif window manager hint for this purpose. However, few window managers do anything reliable or interesting with this hint. Many ignore it entirely. The functions argument is the logical OR of values from the GdkWMFunction enumeration. If the bitmask includes GDK_FUNC_ALL, then the other bits indicate which functions to disable; if it doesn't include GDK_FUNC_ALL, it indicates which functions to enable.

setGeometryHints
void setGeometryHints(GdkGeometry geometry, GdkWindowHints geomMask)

Sets the geometry hints for window. Hints flagged in geom_mask are set, hints not flagged in geom_mask are unset. To unset all hints, use a geom_mask of 0 and a geometry of NULL. This function provides hints to the windowing system about acceptable sizes for a toplevel window. The purpose of this is to constrain user resizing, but the windowing system will typically (but is not required to) also constrain the current size of the window to the provided values and constrain programatic resizing via gdk_window_resize() or gdk_window_move_resize(). Note that on X11, this effect has no effect on windows of type GDK_WINDOW_TEMP or windows where override redirect has been turned on via gdk_window_set_override_redirect() since these windows are not resizable by the user. Since you can't count on the windowing system doing the constraints for programmatic resizes, you should generally call gdk_window_constrain_size() yourself to determine appropriate sizes.

setGroup
void setGroup(Window leader)

Sets the group leader window for window. By default, GDK sets the group leader for all toplevel windows to a global window implicitly created by GDK. With this function you can override this default. The group leader window allows the window manager to distinguish all windows that belong to a single application. It may for example allow users to minimize/unminimize all windows belonging to an application at once. You should only set a non-default group window if your application pretends to be multiple applications.

setIconList
void setIconList(ListG pixbufs)

Sets a list of icons for the window. One of these will be used to represent the window when it has been iconified. The icon is usually shown in an icon box or some sort of task bar. Which icon size is shown depends on the window manager. The window manager can scale the icon but setting several size icons can give better image quality since the window manager may only need to scale the icon by a small amount or not at all.

setIconName
void setIconName(string name)

Windows may have a name used while minimized, distinct from the name they display in their titlebar. Most of the time this is a bad idea from a user interface standpoint. But you can set such a name with this function, if you like. After calling this with a non-NULL name, calls to gdk_window_set_title() will not update the icon title. Using NULL for name unsets the icon title; further calls to gdk_window_set_title() will again update the icon title as well.

setInvalidateHandler
void setInvalidateHandler(GdkWindowInvalidateHandlerFunc handler)

Registers an invalidate handler for a specific window. This will get called whenever a region in the window or its children is invalidated. This can be used to record the invalidated region, which is useful if you are keeping an offscreen copy of some region and want to keep it up to date. You can also modify the invalidated region in case you're doing some effect where e.g. a child widget appears in multiple places.

setKeepAbove
void setKeepAbove(int setting)

Set if window must be kept above other windows. If the window was already above, then this function does nothing. On X11, asks the window manager to keep window above, if the window manager supports this operation. Not all window managers support this, and some deliberately ignore it or don't have a concept of "keep above"; so you can't rely on the window being kept above. But it will happen with most standard window managers, and GDK makes a best effort to get it to happen. Since 2.4

setKeepBelow
void setKeepBelow(int setting)

Set if window must be kept below other windows. If the window was already below, then this function does nothing. On X11, asks the window manager to keep window below, if the window manager supports this operation. Not all window managers support this, and some deliberately ignore it or don't have a concept of "keep below"; so you can't rely on the window being kept below. But it will happen with most standard window managers, and GDK makes a best effort to get it to happen. Since 2.4

setModalHint
void setModalHint(int modal)

The application can use this hint to tell the window manager that a certain window has modal behaviour. The window manager can use this information to handle modal windows in a special way. You should only use this on windows for which you have previously called gdk_window_set_transient_for()

setOpacity
void setOpacity(double opacity)

Set window to render as partially transparent, with opacity 0 being fully transparent and 1 fully opaque. (Values of the opacity parameter are clamped to the [0,1] range.) For toplevel windows this depends on support from the windowing system that may not always be there. For instance, On X11, this works only on X screens with a compositing manager running. For child windows this function only works for non-native windows. For setting up per-pixel alpha topelevels, see gdk_screen_get_rgba_visual(), and for non-toplevels, see gdk_window_set_composited(). Support for non-toplevel windows was added in 3.8. Since 2.12

setOpaqueRegion
void setOpaqueRegion(Region region)

For optimizization purposes, compositing window managers may like to not draw obscured regions of windows, 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 windows. GTK+ will automatically update this property automatically if the window background is opaque, as we know where the opaque regions are. If your window background is not opaque, please update this property in your "style_updated" handler.

setOverrideRedirect
void setOverrideRedirect(int overrideRedirect)

An override redirect window is not under the control of the window manager. This means it won't have a titlebar, won't be minimizable, etc. - it will be entirely under the control of the application. The window manager can't see the override redirect window at all. Override redirect should only be used for short-lived temporary windows, such as popup menus. GtkMenu uses an override redirect window in its implementation, for example.

setRole
void setRole(string role)

When using GTK+, typically you should use gtk_window_set_role() instead of this low-level function. The window manager and session manager use a window's role to distinguish it from other kinds of window in the same application. When an application is restarted after being saved in a previous session, all windows with the same title and role are treated as interchangeable. So if you have two windows with the same title that should be distinguished for session management purposes, you should set the role on those windows. It doesn't matter what string you use for the role, as long as you have a different role for each non-interchangeable kind of window.

setSkipPagerHint
void setSkipPagerHint(int skipsPager)

Toggles whether a window should appear in a pager (workspace switcher, or other desktop utility program that displays a small thumbnail representation of the windows on the desktop). If a window's semantic type as specified with gdk_window_set_type_hint() already fully describes the window, this function should not be called in addition, instead you should allow the window to be treated according to standard policy for its semantic type. Since 2.2

setSkipTaskbarHint
void setSkipTaskbarHint(int skipsTaskbar)

Toggles whether a window should appear in a task list or window list. If a window's semantic type as specified with gdk_window_set_type_hint() already fully describes the window, this function should not be called in addition, instead you should allow the window to be treated according to standard policy for its semantic type. Since 2.2

setSourceEvents
void setSourceEvents(GdkInputSource source, GdkEventMask eventMask)

Sets the event mask for any floating device (i.e. not attached to any visible pointer) that has the source defined as source. This event mask will be applied both to currently existing, newly added devices after this call, and devices being attached/detached.

setStartupId
void setStartupId(string startupId)

When using GTK+, typically you should use gtk_window_set_startup_id() instead of this low-level function. Since 2.12

setStaticGravities
int setStaticGravities(int useStatic)

Set the bit gravity of the given window to static, and flag it so all children get static subwindow gravity. This is used if you are implementing scary features that involve deep knowledge of the windowing system. Don't worry about it unless you have to.

setStruct
void setStruct(GObject* obj)
Undocumented in source. Be warned that the author may not have intended to support it.
setSupportMultidevice
void setSupportMultidevice(int supportMultidevice)

This function will enable multidevice features in window. Multidevice aware windows will need to handle properly multiple, per device enter/leave events, device grabs and grab ownerships.

setTitle
void setTitle(string title)

Sets the title of a toplevel window, to be displayed in the titlebar. If you haven't explicitly set the icon name for the window (using gdk_window_set_icon_name()), the icon name will be set to title as well. title must be in UTF-8 encoding (as with all user-readable strings in GDK/GTK+). title may not be NULL.

setTransientFor
void setTransientFor(Window parent)

Indicates to the window manager that window is a transient dialog associated with the application window parent. This allows the window manager to do things like center window on parent and keep window above parent. See gtk_window_set_transient_for() if you're using GtkWindow or GtkDialog.

setTypeHint
void setTypeHint(GdkWindowTypeHint hint)

The application can use this call to provide a hint to the window manager about the functionality of a window. The window manager can use this information when determining the decoration and behaviour of the window. The hint must be set before the window is mapped.

setUrgencyHint
void setUrgencyHint(int urgent)

Toggles whether a window needs the user's urgent attention. Since 2.8

setUserData
void setUserData(void* userData)

For most purposes this function is deprecated in favor of g_object_set_data(). However, for historical reasons GTK+ stores the GtkWidget that owns a GdkWindow as user data on the GdkWindow. So, custom widget implementations should use this function for that. If GTK+ receives an event for a GdkWindow, and the user data for the window is non-NULL, GTK+ will assume the user data is a GtkWidget, and forward the event to that widget.

shapeCombineRegion
void shapeCombineRegion(Region shapeRegion, int offsetX, int offsetY)

Makes pixels in window outside shape_region be transparent, so that the window may be nonrectangular. If shape_region is NULL, the shape will be unset, so the whole window will be opaque again. offset_x and offset_y are ignored if shape_region is NULL. On the X11 platform, this uses an X server extension which is widely available on most common platforms, but not available on very old X servers, and occasionally the implementation will be buggy. On servers without the shape extension, this function will do nothing. This function works on both toplevel and child windows.

show
void show()

Like gdk_window_show_unraised(), but also raises the window to the top of the window stack (moves the window to the front of the Z-order). This function maps a window so it's visible onscreen. Its opposite is gdk_window_hide(). When implementing a GtkWidget, you should call this function on the widget's GdkWindow as part of the "map" method.

showUnraised
void showUnraised()

Shows a GdkWindow onscreen, but does not modify its stacking order. In contrast, gdk_window_show() will raise the window to the top of the window stack. On the X11 platform, in Xlib terms, this function calls XMapWindow() (it also updates some internal GDK state, which means that you can't really use XMapWindow() directly on a GDK window).

stick
void stick()

"Pins" a window such that it's on all workspaces and does not scroll with viewports, for window managers that have scrollable viewports. (When using GtkWindow, gtk_window_stick() may be more useful.) On the X11 platform, this function depends on window manager support, so may have no effect with many window managers. However, GDK will do the best it can to convince the window manager to stick the window. For window managers that don't support this operation, there's nothing you can do to force it to happen.

thawUpdates
void thawUpdates()

Thaws a window frozen with gdk_window_freeze_updates().

unfullscreen
void unfullscreen()

Moves the window out of fullscreen mode. If the window was not fullscreen, does nothing. On X11, asks the window manager to move window out of the fullscreen state, if the window manager supports this operation. Not all window managers support this, and some deliberately ignore it or don't have a concept of "fullscreen"; so you can't rely on the unfullscreenification actually happening. But it will happen with most standard window managers, and GDK makes a best effort to get it to happen. Since 2.2

unmaximize
void unmaximize()

Unmaximizes the window. If the window wasn't maximized, then this function does nothing. On X11, asks the window manager to unmaximize window, if the window manager supports this operation. Not all window managers support this, and some deliberately ignore it or don't have a concept of "maximized"; so you can't rely on the unmaximization actually happening. But it will happen with most standard window managers, and GDK makes a best effort to get it to happen. On Windows, reliably unmaximizes the window.

unstick
void unstick()

Reverse operation for gdk_window_stick(); see gdk_window_stick(), and gtk_window_unstick().

withdraw
void withdraw()

Withdraws a window (unmaps it and asks the window manager to forget about it). This function is not really useful as gdk_window_hide() automatically withdraws toplevel windows before hiding them.

Static functions

atPointer
Window atPointer(int winX, int winY)

Warning gdk_window_at_pointer has been deprecated since version 3.0 and should not be used in newly-written code. Use gdk_device_get_window_at_position() instead. Obtains the window underneath the mouse pointer, returning the location of that window in win_x, win_y. Returns NULL if the window under the mouse pointer is not known to GDK (if the window belongs to another application and a GdkWindow hasn't been created for it with gdk_window_foreign_new()) NOTE: For multihead-aware widgets or applications use gdk_display_get_window_at_pointer() instead.

callBackCreateSurface
void callBackCreateSurface(GdkWindow* windowStruct, gint width, gint height, Window _window)
Undocumented in source. Be warned that the author may not have intended to support it.
callBackFromEmbedder
void callBackFromEmbedder(GdkWindow* windowStruct, gdouble embedderX, gdouble embedderY, void* offscreenX, void* offscreenY, Window _window)
Undocumented in source. Be warned that the author may not have intended to support it.
callBackPickEmbeddedChild
void callBackPickEmbeddedChild(GdkWindow* windowStruct, gdouble x, gdouble y, Window _window)
Undocumented in source. Be warned that the author may not have intended to support it.
callBackToEmbedder
void callBackToEmbedder(GdkWindow* windowStruct, gdouble offscreenX, gdouble offscreenY, void* embedderX, void* embedderY, Window _window)
Undocumented in source. Be warned that the author may not have intended to support it.
constrainSize
void constrainSize(GdkGeometry geometry, uint flags, int width, int height, int newWidth, int newHeight)

Constrains a desired width and height according to a set of geometry hints (such as minimum and maximum size).

getDefaultRootWindow
Window getDefaultRootWindow()

Obtains the root window (parent all other windows are inside) for the default display and screen.

processAllUpdates
void processAllUpdates()

Calls gdk_window_process_updates() for all windows (see GdkWindow) in the application.

setDebugUpdates
void setDebugUpdates(int setting)

With update debugging enabled, calls to gdk_window_invalidate_region() clear the invalidated region of the screen to a noticeable color, and GDK pauses for a short time before sending exposes to windows during gdk_window_process_updates(). The net effect is that you can see the invalid region for each window and watch redraws as they occur. This allows you to diagnose inefficiencies in your application. In essence, because the GDK rendering model prevents all flicker, if you are redrawing the same region 400 times you may never notice, aside from noticing a speed problem. Enabling update debugging causes GTK to flicker slowly and noticeably, so you can see exactly what's being redrawn when, in what order. The --gtk-debug=updates command line option passed to GTK+ programs enables this debug option at application startup time. That's usually more useful than calling gdk_window_set_debug_updates() yourself, though you might want to use this function to enable updates sometime after application startup time.

Variables

connectedSignals
int[string] connectedSignals;
gdkWindow
GdkWindow* gdkWindow;

the main Gtk struct

onCreateSurfaceListeners
Surface delegate(gint, gint, Window)[] onCreateSurfaceListeners;
Undocumented in source.
onFromEmbedderListeners
void delegate(gdouble, gdouble, void*, void*, Window)[] onFromEmbedderListeners;
Undocumented in source.
onPickEmbeddedChildListeners
Window delegate(gdouble, gdouble, Window)[] onPickEmbeddedChildListeners;
Undocumented in source.
onToEmbedderListeners
void delegate(gdouble, gdouble, void*, void*, Window)[] onToEmbedderListeners;
Undocumented in source.

Inherited Members

From ObjectG

gObject
GObject* gObject;

the main Gtk struct

getObjectGStruct
GObject* getObjectGStruct()
Undocumented in source. Be warned that the author may not have intended to support it.
getStruct
void* getStruct()

the main Gtk struct as a void*

isGcRoot
bool isGcRoot;
Undocumented in source.
destroyNotify
void destroyNotify(ObjectG obj)
Undocumented in source. Be warned that the author may not have intended to support it.
toggleNotify
void toggleNotify(ObjectG obj, GObject* object, int isLastRef)
Undocumented in source. Be warned that the author may not have intended to support it.
~this
~this()
Undocumented in source.
getDObject
RT getDObject(U obj)

Gets a D Object from the objects table of associations.

setStruct
void setStruct(GObject* obj)
Undocumented in source. Be warned that the author may not have intended to support it.
setProperty
void setProperty(string propertyName, int value)
setProperty
void setProperty(string propertyName, string value)
setProperty
void setProperty(string propertyName, long value)
setProperty
void setProperty(string propertyName, ulong value)
unref
void unref()
Undocumented in source. Be warned that the author may not have intended to support it.
doref
ObjectG doref()
Undocumented in source. Be warned that the author may not have intended to support it.
connectedSignals
int[string] connectedSignals;
Undocumented in source.
onNotifyListeners
void delegate(ParamSpec, ObjectG)[] onNotifyListeners;
Undocumented in source.
addOnNotify
void addOnNotify(void delegate(ParamSpec, ObjectG) dlg, string property, ConnectFlags connectFlags)

The notify signal is emitted on an object when one of its properties has been changed. Note that getting this signal doesn't guarantee that the value of the property has actually changed, it may also be emitted when the setter for the property is called to reinstate the previous value.

callBackNotify
void callBackNotify(GObject* gobjectStruct, GParamSpec* pspec, ObjectG _objectG)
Undocumented in source. Be warned that the author may not have intended to support it.
classInstallProperty
void classInstallProperty(GObjectClass* oclass, uint propertyId, ParamSpec pspec)

Installs a new property. This is usually done in the class initializer. Note that it is possible to redefine a property in a derived class, by installing a property with the same name. This can be useful at times, e.g. to change the range of allowed values or the default value.

classInstallProperties
void classInstallProperties(GObjectClass* oclass, ParamSpec[] pspecs)

Installs new properties from an array of GParamSpecs. This is usually done in the class initializer. The property id of each property is the index of each GParamSpec in the pspecs array. The property id of 0 is treated specially by GObject and it should not be used to store a GParamSpec. This function should be used if you plan to use a static array of GParamSpecs and g_object_notify_by_pspec(). For instance, this Since 2.26

classFindProperty
ParamSpec classFindProperty(GObjectClass* oclass, string propertyName)

Looks up the GParamSpec for a property of a class.

classListProperties
ParamSpec[] classListProperties(GObjectClass* oclass)

Get an array of GParamSpec* for all properties of a class.

classOverrideProperty
void classOverrideProperty(GObjectClass* oclass, uint propertyId, string name)

Registers property_id as referring to a property with the name name in a parent class or in an interface implemented by oclass. This allows this class to override a property implementation in a parent class or to provide the implementation of a property from an interface. Note Internally, overriding is implemented by creating a property of type GParamSpecOverride; generally operations that query the properties of the object class, such as g_object_class_find_property() or g_object_class_list_properties() will return the overridden property. However, in one case, the construct_properties argument of the constructor virtual function, the GParamSpecOverride is passed instead, so that the param_id field of the GParamSpec will be correct. For virtually all uses, this makes no difference. If you need to get the overridden property, you can call g_param_spec_get_redirect_target(). Since 2.4

interfaceInstallProperty
void interfaceInstallProperty(void* iface, ParamSpec pspec)

Add a property to an interface; this is only useful for interfaces that are added to GObject-derived types. Adding a property to an interface forces all objects classes with that interface to have a compatible property. The compatible property could be a newly created GParamSpec, but normally g_object_class_override_property() will be used so that the object class only needs to provide an implementation and inherits the property description, default value, bounds, and so forth from the interface property. This function is meant to be called from the interface's default vtable initialization function (the class_init member of GTypeInfo.) It must not be called after after class_init has been called for any object types implementing this interface. Since 2.4

interfaceFindProperty
ParamSpec interfaceFindProperty(void* iface, string propertyName)

Find the GParamSpec with the given name for an interface. Generally, the interface vtable passed in as g_iface will be the default vtable from g_type_default_interface_ref(), or, if you know the interface has already been loaded, g_type_default_interface_peek(). Since 2.4

interfaceListProperties
ParamSpec[] interfaceListProperties(void* iface)

Lists the properties of an interface.Generally, the interface vtable passed in as g_iface will be the default vtable from g_type_default_interface_ref(), or, if you know the interface has already been loaded, g_type_default_interface_peek(). Since 2.4

doref
void* doref(void* object)

Increases the reference count of object.

unref
void unref(void* object)

Decreases the reference count of object. When its reference count drops to 0, the object is finalized (i.e. its memory is freed).

refSink
void* refSink(void* object)

Increase the reference count of object, and possibly remove the floating reference, if object has a floating reference. In other words, if the object is floating, then this call "assumes ownership" of the floating reference, converting it to a normal reference by clearing the floating flag while leaving the reference count unchanged. If the object is not floating, then this call adds a new normal reference increasing the reference count by one. Since 2.10

clearObject
void clearObject(ObjectG objectPtr)

Clears a reference to a GObject. object_ptr must not be NULL. If the reference is NULL then this function does nothing. Otherwise, the reference count of the object is decreased and the pointer is set to NULL. This function is threadsafe and modifies the pointer atomically, using memory barriers where needed. A macro is also included that allows this function to be used without pointer casts. Since 2.28

isFloating
int isFloating(void* object)

Checks whether object has a floating reference. Since 2.10

forceFloating
void forceFloating()

This function is intended for GObject implementations to re-enforce a floating object reference. Doing this is seldom required: all GInitiallyUnowneds are created with a floating reference which usually just needs to be sunken by calling g_object_ref_sink(). Since 2.10

weakRef
void weakRef(GWeakNotify notify, void* data)

Adds a weak reference callback to an object. Weak references are used for notification when an object is finalized. They are called "weak references" because they allow you to safely hold a pointer to an object without calling g_object_ref() (g_object_ref() adds a strong reference, that is, forces the object to stay alive). Note that the weak references created by this method are not thread-safe: they cannot safely be used in one thread if the object's last g_object_unref() might happen in another thread. Use GWeakRef if thread-safety is required.

weakUnref
void weakUnref(GWeakNotify notify, void* data)

Removes a weak reference callback to an object.

addWeakPointer
void addWeakPointer(void** weakPointerLocation)

Adds a weak reference from weak_pointer to object to indicate that the pointer located at weak_pointer_location is only valid during the lifetime of object. When the object is finalized, weak_pointer will be set to NULL. Note that as with g_object_weak_ref(), the weak references created by this method are not thread-safe: they cannot safely be used in one thread if the object's last g_object_unref() might happen in another thread. Use GWeakRef if thread-safety is required.

removeWeakPointer
void removeWeakPointer(void** weakPointerLocation)

Removes a weak reference from object that was previously added using g_object_add_weak_pointer(). The weak_pointer_location has to match the one used with g_object_add_weak_pointer().

addToggleRef
void addToggleRef(GToggleNotify notify, void* data)

Increases the reference count of the object by one and sets a callback to be called when all other references to the object are dropped, or when this is already the last reference to the object and another reference is established. This functionality is intended for binding object to a proxy object managed by another memory manager. This is done with two paired references: the strong reference added by g_object_add_toggle_ref() and a reverse reference to the proxy object which is either a strong reference or weak reference. The setup is that when there are no other references to object, only a weak reference is held in the reverse direction from object to the proxy object, but when there are other references held to object, a strong reference is held. The notify callback is called when the reference from object to the proxy object should be toggled from strong to weak (is_last_ref true) or weak to strong (is_last_ref false). Since a (normal) reference must be held to the object before calling g_object_add_toggle_ref(), the initial state of the reverse link is always strong. Multiple toggle references may be added to the same gobject, however if there are multiple toggle references to an object, none of them will ever be notified until all but one are removed. For this reason, you should only ever use a toggle reference if there is important state in the proxy object. Since 2.8

removeToggleRef
void removeToggleRef(GToggleNotify notify, void* data)

Removes a reference added with g_object_add_toggle_ref(). The reference count of the object is decreased by one. Since 2.8

notify
void notify(string propertyName)

Emits a "notify" signal for the property property_name on object. When possible, eg. when signaling a property change from within the class that registered the property, you should use g_object_notify_by_pspec() instead.

notifyByPspec
void notifyByPspec(ParamSpec pspec)

Emits a "notify" signal for the property specified by pspec on object. This function omits the property name lookup, hence it is faster than g_object_notify(). One way to avoid using g_object_notify() from within the class that registered the properties, and using g_object_notify_by_pspec() instead, is to store the GParamSpec used with Since 2.26

freezeNotify
void freezeNotify()

Increases the freeze count on object. If the freeze count is non-zero, the emission of "notify" signals on object is stopped. The signals are queued until the freeze count is decreased to zero. Duplicate notifications are squashed so that at most one "notify" signal is emitted for each property modified while the object is frozen. This is necessary for accessors that modify multiple properties to prevent premature notification while the object is still being modified.

thawNotify
void thawNotify()

Reverts the effect of a previous call to g_object_freeze_notify(). The freeze count is decreased on object and when it reaches zero, queued "notify" signals are emitted. Duplicate notifications for each property are squashed so that at most one "notify" signal is emitted for each property. It is an error to call this function when the freeze count is zero.

getData
void* getData(string key)

Gets a named field from the objects table of associations (see g_object_set_data()).

setData
void setData(string key, void* data)

Each object carries around a table of associations from strings to pointers. This function lets you set an association. If the object already had an association with that name, the old association will be destroyed.

setDataFull
void setDataFull(string key, void* data, GDestroyNotify destroy)

Like g_object_set_data() except it adds notification for when the association is destroyed, either by setting it to a different value or when the object is destroyed. Note that the destroy callback is not called if data is NULL.

stealData
void* stealData(string key)

Remove a specified datum from the object's data associations, without invoking the association's destroy handler.

dupData
void* dupData(string key, GDuplicateFunc dupFunc, void* userData)

This is a variant of g_object_get_data() which returns a 'duplicate' of the value. dup_func defines the meaning of 'duplicate' in this context, it could e.g. take a reference on a ref-counted object. If the key is not set on the object then dup_func will be called with a NULL argument. Note that dup_func is called while user data of object is locked. This function can be useful to avoid races when multiple threads are using object data on the same key on the same object. Since 2.34

replaceData
int replaceData(string key, void* oldval, void* newval, GDestroyNotify destroy, GDestroyNotify* oldDestroy)

Compares the user data for the key key on object with oldval, and if they are the same, replaces oldval with newval. This is like a typical atomic compare-and-exchange operation, for user data on an object. If the previous value was replaced then ownership of the old value (oldval) is passed to the caller, including the registered destroy notify for it (passed out in old_destroy). Its up to the caller to free this as he wishes, which may or may not include using old_destroy as sometimes replacement should not destroy the object in the normal way. Return: TRUE if the existing value for key was replaced by newval, FALSE otherwise. Since 2.34

getQdata
void* getQdata(GQuark quark)

This function gets back user data pointers stored via g_object_set_qdata().

setQdata
void setQdata(GQuark quark, void* data)

This sets an opaque, named pointer on an object. The name is specified through a GQuark (retrived e.g. via g_quark_from_static_string()), and the pointer can be gotten back from the object with g_object_get_qdata() until the object is finalized. Setting a previously set user data pointer, overrides (frees) the old pointer set, using NULL as pointer essentially removes the data stored.

setQdataFull
void setQdataFull(GQuark quark, void* data, GDestroyNotify destroy)

This function works like g_object_set_qdata(), but in addition, a void (*destroy) (gpointer) function may be specified which is called with data as argument when the object is finalized, or the data is being overwritten by a call to g_object_set_qdata() with the same quark.

stealQdata
void* stealQdata(GQuark quark)

This function gets back user data pointers stored via g_object_set_qdata() and removes the data from object without invoking its destroy() function (if any was set). Usually, calling this function is only required to update

dupQdata
void* dupQdata(GQuark quark, GDuplicateFunc dupFunc, void* userData)

This is a variant of g_object_get_qdata() which returns a 'duplicate' of the value. dup_func defines the meaning of 'duplicate' in this context, it could e.g. take a reference on a ref-counted object. If the quark is not set on the object then dup_func will be called with a NULL argument. Note that dup_func is called while user data of object is locked. This function can be useful to avoid races when multiple threads are using object data on the same key on the same object. Since 2.34

replaceQdata
int replaceQdata(GQuark quark, void* oldval, void* newval, GDestroyNotify destroy, GDestroyNotify* oldDestroy)

Compares the user data for the key quark on object with oldval, and if they are the same, replaces oldval with newval. This is like a typical atomic compare-and-exchange operation, for user data on an object. If the previous value was replaced then ownership of the old value (oldval) is passed to the caller, including the registered destroy notify for it (passed out in old_destroy). Its up to the caller to free this as he wishes, which may or may not include using old_destroy as sometimes replacement should not destroy the object in the normal way. Return: TRUE if the existing value for quark was replaced by newval, FALSE otherwise. Since 2.34

setProperty
void setProperty(string propertyName, Value value)

Sets a property on an object.

getProperty
void getProperty(string propertyName, Value value)

Gets a property of an object. value must have been initialized to the expected type of the property (or a type to which the expected type can be transformed) using g_value_init(). In general, a copy is made of the property contents and the caller is responsible for freeing the memory by calling g_value_unset(). Note that g_object_get_property() is really intended for language bindings, g_object_get() is much more convenient for C programming.

setValist
void setValist(string firstPropertyName, void* varArgs)

Sets properties on an object.

getValist
void getValist(string firstPropertyName, void* varArgs)

Gets properties of an object. In general, a copy is made of the property contents and the caller is responsible for freeing the memory in the appropriate manner for the type, for instance by calling g_free() or g_object_unref(). See g_object_get().

watchClosure
void watchClosure(Closure closure)

This function essentially limits the life time of the closure to the life time of the object. That is, when the object is finalized, the closure is invalidated by calling g_closure_invalidate() on it, in order to prevent invocations of the closure with a finalized (nonexisting) object. Also, g_object_ref() and g_object_unref() are added as marshal guards to the closure, to ensure that an extra reference count is held on object during invocation of the closure. Usually, this function will be called on closures that use this object as closure data.

runDispose
void runDispose()

Releases all references to other objects. This can be used to break reference cycles. This functions should only be called from object system implementations.

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