Gtk.Widget

class — extends GObject.InitiallyUnowned, Accessible, Buildable, ConstraintTarget

The base class for all widgets.

It manages the widget lifecycle, layout, states and style.

Height-for-width Geometry Management

GTK uses a height-for-width (and width-for-height) geometry management system. Height-for-width means that a widget can change how much vertical space it needs, depending on the amount of horizontal space that it is given (and similar for width-for-height). The most common example is a label that reflows to fill up the available width, wraps to fewer lines, and therefore needs less height.

Height-for-width geometry management is implemented in GTK by way of two virtual methods:

• Widget.get_request_mode
• Widget.measure

There are some important things to keep in mind when implementing height-for-width and when using it in widget implementations.

If you implement a direct GtkWidget subclass that supports height-for-width or width-for-height geometry management for itself or its child widgets, the Widget.get_request_mode virtual function must be implemented as well and return the widget's preferred request mode. The default implementation of this virtual function returns SizeRequestMode.CONSTANT_SIZE, which means that the widget will only ever get -1 passed as the for_size value to its Widget.measure implementation.

The geometry management system will query a widget hierarchy in only one orientation at a time. When widgets are initially queried for their minimum sizes it is generally done in two initial passes in the SizeRequestMode chosen by the toplevel.

For example, when queried in the normal SizeRequestMode.HEIGHT_FOR_WIDTH mode:

First, the default minimum and natural width for each widget in the interface will be computed using Widget.measure with an orientation of Orientation.HORIZONTAL and a for_size of -1. Because the preferred widths for each widget depend on the preferred widths of their children, this information propagates up the hierarchy, and finally a minimum and natural width is determined for the entire toplevel. Next, the toplevel will use the minimum width to query for the minimum height contextual to that width using Widget.measure with an orientation of Orientation.VERTICAL and a for_size of the just computed width. This will also be a highly recursive operation. The minimum height for the minimum width is normally used to set the minimum size constraint on the toplevel.

After the toplevel window has initially requested its size in both dimensions it can go on to allocate itself a reasonable size (or a size previously specified with Window.set_default_size). During the recursive allocation process it’s important to note that request cycles will be recursively executed while widgets allocate their children. Each widget, once allocated a size, will go on to first share the space in one orientation among its children and then request each child's height for its target allocated width or its width for allocated height, depending. In this way a widget will typically be requested its size a number of times before actually being allocated a size. The size a widget is finally allocated can of course differ from the size it has requested. For this reason, GtkWidget caches a small number of results to avoid re-querying for the same sizes in one allocation cycle.

If a widget does move content around to intelligently use up the allocated size then it must support the request in both GtkSizeRequestModes even if the widget in question only trades sizes in a single orientation.

For instance, a Label that does height-for-width word wrapping will not expect to have Widget.measure with an orientation of Orientation.VERTICAL called because that call is specific to a width-for-height request. In this case the label must return the height required for its own minimum possible width. By following this rule any widget that handles height-for-width or width-for-height requests will always be allocated at least enough space to fit its own content.

Here are some examples of how a SizeRequestMode.HEIGHT_FOR_WIDTH widget generally deals with width-for-height requests:

static void
foo_widget_measure (GtkWidget      *widget,
                    GtkOrientation  orientation,
                    int             for_size,
                    int            *minimum_size,
                    int            *natural_size,
                    int            *minimum_baseline,
                    int            *natural_baseline)
{
  if (orientation == GTK_ORIENTATION_HORIZONTAL)
    {
      // Calculate minimum and natural width
    }
  else // VERTICAL
    {
      if (i_am_in_height_for_width_mode)
        {
          int min_width, dummy;

          // First, get the minimum width of our widget
          GTK_WIDGET_GET_CLASS (widget)->measure (widget, GTK_ORIENTATION_HORIZONTAL, -1,
                                                  &min_width, &dummy, &dummy, &dummy);

          // Now use the minimum width to retrieve the minimum and natural height to display
          // that width.
          GTK_WIDGET_GET_CLASS (widget)->measure (widget, GTK_ORIENTATION_VERTICAL, min_width,
                                                  minimum_size, natural_size, &dummy, &dummy);
        }
      else
        {
          // ... some widgets do both.
        }
    }
}

Often a widget needs to get its own request during size request or allocation. For example, when computing height it may need to also compute width. Or when deciding how to use an allocation, the widget may need to know its natural size. In these cases, the widget should be careful to call its virtual methods directly, like in the code example above.

It will not work to use the wrapper function Widget.measure inside your own Widget.size_allocate implementation. These return a request adjusted by SizeGroup, the widget's align and expand flags, as well as its CSS style.

If a widget used the wrappers inside its virtual method implementations, then the adjustments (such as widget margins) would be applied twice. GTK therefore does not allow this and will warn if you try to do it.

Of course if you are getting the size request for another widget, such as a child widget, you must use Widget.measure; otherwise, you would not properly consider widget margins, SizeGroup, and so forth.

GTK also supports baseline vertical alignment of widgets. This means that widgets are positioned such that the typographical baseline of widgets in the same row are aligned. This happens if a widget supports baselines, has a vertical alignment using baselines, and is inside a widget that supports baselines and has a natural “row” that it aligns to the baseline, or a baseline assigned to it by the grandparent.

Baseline alignment support for a widget is also done by the Widget.measure virtual function. It allows you to report both a minimum and natural size.

If a widget ends up baseline aligned it will be allocated all the space in the parent as if it was Align.FILL, but the selected baseline can be found via Widget.get_baseline. If the baseline has a value other than -1 you need to align the widget such that the baseline appears at the position.

GtkWidget as GtkBuildable

The GtkWidget implementation of the GtkBuildable interface supports various custom elements to specify additional aspects of widgets that are not directly expressed as properties.

If the widget uses a LayoutManager, GtkWidget supports a custom <layout> element, used to define layout properties:

<object class="GtkGrid" id="my_grid">
  <child>
    <object class="GtkLabel" id="label1">
      <property name="label">Description</property>
      <layout>
        <property name="column">0</property>
        <property name="row">0</property>
        <property name="row-span">1</property>
        <property name="column-span">1</property>
      </layout>
    </object>
  </child>
  <child>
    <object class="GtkEntry" id="description_entry">
      <layout>
        <property name="column">1</property>
        <property name="row">0</property>
        <property name="row-span">1</property>
        <property name="column-span">1</property>
      </layout>
    </object>
  </child>
</object>

GtkWidget allows style information such as style classes to be associated with widgets, using the custom <style> element:

<object class="GtkButton" id="button1">
  <style>
    <class name="my-special-button-class"/>
    <class name="dark-button"/>
  </style>
</object>

GtkWidget allows defining accessibility information, such as properties, relations, and states, using the custom <accessibility> element:

<object class="GtkButton" id="button1">
  <accessibility>
    <property name="label">Download</property>
    <relation name="labelled-by">label1</relation>
  </accessibility>
</object>

Building composite widgets from template XML

GtkWidgetexposes some facilities to automate the procedure of creating composite widgets using "templates".

To create composite widgets with GtkBuilder XML, one must associate the interface description with the widget class at class initialization time using WidgetClass.set_template.

The interface description semantics expected in composite template descriptions is slightly different from regular Builder XML.

Unlike regular interface descriptions, WidgetClass.set_template will expect a <template> tag as a direct child of the toplevel <interface> tag. The <template> tag must specify the “class” attribute which must be the type name of the widget. Optionally, the “parent” attribute may be specified to specify the direct parent type of the widget type; this is ignored by GtkBuilder but can be used by UI design tools to introspect what kind of properties and internal children exist for a given type when the actual type does not exist.

The XML which is contained inside the <template> tag behaves as if it were added to the <object> tag defining the widget itself. You may set properties on a widget by inserting <property> tags into the <template> tag, and also add <child> tags to add children and extend a widget in the normal way you would with <object> tags.

Additionally, <object> tags can also be added before and after the initial <template> tag in the normal way, allowing one to define auxiliary objects which might be referenced by other widgets declared as children of the <template> tag.

Since, unlike the <object> tag, the <template> tag does not contain an “id” attribute, if you need to refer to the instance of the object itself that the template will create, simply refer to the template class name in an applicable element content.

Here is an example of a template definition, which includes an example of this in the <signal> tag:

<interface>
  <template class="FooWidget" parent="GtkBox">
    <property name="orientation">horizontal</property>
    <property name="spacing">4</property>
    <child>
      <object class="GtkButton" id="hello_button">
        <property name="label">Hello World</property>
        <signal name="clicked" handler="hello_button_clicked" object="FooWidget" swapped="yes"/>
      </object>
    </child>
    <child>
      <object class="GtkButton" id="goodbye_button">
        <property name="label">Goodbye World</property>
      </object>
    </child>
  </template>
</interface>

Typically, you'll place the template fragment into a file that is bundled with your project, using GResource. In order to load the template, you need to call WidgetClass.set_template_from_resource from the class initialization of your GtkWidget type:

static void
foo_widget_class_init (FooWidgetClass *klass)
{
  // ...

  gtk_widget_class_set_template_from_resource (GTK_WIDGET_CLASS (klass),
                                               "/com/example/ui/foowidget.ui");
}

You will also need to call Widget.init_template from the instance initialization function:

static void
foo_widget_init (FooWidget *self)
{
  gtk_widget_init_template (GTK_WIDGET (self));

  // Initialize the rest of the widget...
}

as well as calling Widget.dispose_template from the dispose function:

static void
foo_widget_dispose (GObject *gobject)
{
  FooWidget *self = FOO_WIDGET (gobject);

  // Dispose objects for which you have a reference...

  // Clear the template children for this widget type
  gtk_widget_dispose_template (GTK_WIDGET (self), FOO_TYPE_WIDGET);

  G_OBJECT_CLASS (foo_widget_parent_class)->dispose (gobject);
}

You can access widgets defined in the template using the Widget.get_template_child function, but you will typically declare a pointer in the instance private data structure of your type using the same name as the widget in the template definition, and call WidgetClass.bind_template_child_full (or one of its wrapper macros Gtk.widget_class_bind_template_child and Gtk.widget_class_bind_template_child_private) with that name, e.g.

typedef struct {
  GtkWidget *hello_button;
  GtkWidget *goodbye_button;
} FooWidgetPrivate;

G_DEFINE_TYPE_WITH_PRIVATE (FooWidget, foo_widget, GTK_TYPE_BOX)

static void
foo_widget_dispose (GObject *gobject)
{
  gtk_widget_dispose_template (GTK_WIDGET (gobject), FOO_TYPE_WIDGET);

  G_OBJECT_CLASS (foo_widget_parent_class)->dispose (gobject);
}

static void
foo_widget_class_init (FooWidgetClass *klass)
{
  // ...
  G_OBJECT_CLASS (klass)->dispose = foo_widget_dispose;

  gtk_widget_class_set_template_from_resource (GTK_WIDGET_CLASS (klass),
                                               "/com/example/ui/foowidget.ui");
  gtk_widget_class_bind_template_child_private (GTK_WIDGET_CLASS (klass),
                                                FooWidget, hello_button);
  gtk_widget_class_bind_template_child_private (GTK_WIDGET_CLASS (klass),
                                                FooWidget, goodbye_button);
}

static void
foo_widget_init (FooWidget *widget)
{
  gtk_widget_init_template (GTK_WIDGET (widget));
}

You can also use WidgetClass.bind_template_callback_full (or is wrapper macro Gtk.widget_class_bind_template_callback) to connect a signal callback defined in the template with a function visible in the scope of the class, e.g.

// the signal handler has the instance and user data swapped
// because of the swapped="yes" attribute in the template XML
static void
hello_button_clicked (FooWidget *self,
                      GtkButton *button)
{
  g_print ("Hello, world!\n");
}

static void
foo_widget_class_init (FooWidgetClass *klass)
{
  // ...
  gtk_widget_class_set_template_from_resource (GTK_WIDGET_CLASS (klass),
                                               "/com/example/ui/foowidget.ui");
  gtk_widget_class_bind_template_callback (GTK_WIDGET_CLASS (klass), hello_button_clicked);
}

Methods

action_set_enabled

def action_set_enabled(self, action_name: str, enabled: bool) -> None

Enables or disables an action installed with WidgetClass.install_action.

Parameters:

• action_name — action name, such as "clipboard.paste"
• enabled — whether the action is now enabled

activate

def activate(self) -> bool

Activates the widget.

The activation will emit the signal set using WidgetClass.set_activate_signal during class initialization.

Activation is what happens when you press <kbd>Enter</kbd> on a widget.

If you wish to handle the activation keybinding yourself, it is recommended to use WidgetClass.add_shortcut with an action created with SignalAction.new.

If widget is not activatable, the function returns false.

activate_action

def activate_action(self, name: str, args: GLib.Variant | None = ...) -> bool

Activates an action for the widget.

The action is looked up in the action groups associated with widget and its ancestors.

If the action is in an action group added with Widget.insert_action_group, the name is expected to be prefixed with the prefix that was used when the group was inserted.

The arguments must match the actions expected parameter type, as returned by Gio.Action.get_parameter_type.

Parameters:

• name — the name of the action to activate
• args — parameters to use

activate_default

def activate_default(self) -> None

Activates the default.activate action for the widget.

The action is looked up in the same was as for Widget.activate_action.

add_controller

def add_controller(self, controller: EventController) -> None

Adds an event controller to the widget.

The event controllers of a widget handle the events that are propagated to the widget.

You will usually want to call this function right after creating any kind of EventController.

Parameters:

• controller — an event controller that hasn't been added to a widget yet

add_css_class

def add_css_class(self, css_class: str) -> None

Adds a style class to the widget.

After calling this function, the widget’s style will match for css_class, according to CSS matching rules.

Use Widget.remove_css_class to remove the style again.

Parameters:

• css_class — style class to add to widget, without the leading period

add_mnemonic_label

def add_mnemonic_label(self, label: Widget) -> None

Adds a widget to the list of mnemonic labels for this widget.

See Widget.list_mnemonic_labels.

Note that the list of mnemonic labels for the widget is cleared when the widget is destroyed, so the caller must make sure to update its internal state at this point as well.

Parameters:

• label — a widget that acts as a mnemonic label for widget

add_tick_callback

def add_tick_callback(self, callback: TickCallback) -> int

Queues an animation frame update and adds a callback to be called before each frame.

Until the tick callback is removed, it will be called frequently (usually at the frame rate of the output device or as quickly as the application can be repainted, whichever is slower). For this reason, is most suitable for handling graphics that change every frame or every few frames.

The tick callback does not automatically imply a relayout or repaint. If you want a repaint or relayout, and aren’t changing widget properties that would trigger that (for example, changing the text of a label), then you will have to call Widget.queue_resize or Widget.queue_draw yourself.

Gdk.FrameClock.get_frame_time should generally be used for timing continuous animations and Gdk.FrameTimings.get_predicted_presentation_time should be used if you are trying to display isolated frames at particular times.

This is a more convenient alternative to connecting directly to the Gdk.FrameClock.update signal of the frame clock, since you don't have to worry about when a frame clock is assigned to a widget.

To remove a tick callback, pass the ID that is returned by this function to Widget.remove_tick_callback.

Parameters:

• callback — function to call for updating animations

allocate

def allocate(self, width: int, height: int, baseline: int, transform: Gsk.Transform | None = ...) -> None

Assigns size, position, (optionally) a baseline and transform to a child widget.

In this function, the allocation and baseline may be adjusted. The given allocation will be forced to be bigger than the widget's minimum size, as well as at least 0×0 in size.

This function is only used by widget implementations.

For a version that does not take a transform, see Widget.size_allocate.

Parameters:

• width — new width
• height — new height
• baseline — new baseline, or -1
• transform — transformation to be applied

child_focus

def child_focus(self, direction: DirectionType | int) -> bool

Called by widgets as the user moves around the window using keyboard shortcuts.

The direction argument indicates what kind of motion is taking place (up, down, left, right, tab forward, tab backward).

This function calls the Widget.focus virtual function; widgets can override the virtual function in order to implement appropriate focus behavior.

The default focus() virtual function for a widget should return true if moving in direction left the focus on a focusable location inside that widget, and false if moving in direction moved the focus outside the widget. When returning true, widgets normally call Widget.grab_focus to place the focus accordingly; when returning false, they don’t modify the current focus location.

This function is used by custom widget implementations; if you're writing an app, you’d use Widget.grab_focus to move the focus to a particular widget.

Parameters:

• direction — direction of focus movement

compute_bounds

def compute_bounds(self, target: Widget) -> tuple[bool, Graphene.Rect]

Computes the bounds for widget in the coordinate space of target.

The bounds of widget are (the bounding box of) the region that it is expected to draw in. See the coordinate system overview to learn more.

If the operation is successful, true is returned. If widget has no bounds or the bounds cannot be expressed in target's coordinate space (for example if both widgets are in different windows), false is returned and bounds is set to the zero rectangle.

It is valid for widget and target to be the same widget.

Parameters:

• target — the target widget

compute_expand

def compute_expand(self, orientation: Orientation | int) -> bool

Computes whether a parent widget should give this widget extra space when possible.

Widgets with children should check this, rather than looking at Widget.get_hexpand or Widget.get_vexpand.

This function already checks whether the widget is visible, so visibility does not need to be checked separately. Non-visible widgets are not expanded.

The computed expand value uses either the expand setting explicitly set on the widget itself, or, if none has been explicitly set, the widget may expand if some of its children do.

Parameters:

• orientation — expand direction

compute_point

def compute_point(self, target: Widget, point: Graphene.Point) -> tuple[bool, Graphene.Point]

Translates the given point in widget's coordinates to coordinates in target’s coordinate system.

In order to perform this operation, both widgets must share a a common ancestor. If that is not the case, out_point is set to (0, 0) and false is returned.

Parameters:

• target — the widget to transform into
• point — a point in widget's coordinate system

compute_transform

def compute_transform(self, target: Widget) -> tuple[bool, Graphene.Matrix]

Computes a matrix suitable to describe a transformation from widget's coordinate system into target's coordinate system.

The transform can not be computed in certain cases, for example when widget and target do not share a common ancestor. In that case out_transform gets set to the identity matrix.

To learn more about widget coordinate systems, see the coordinate system overview.

Parameters:

• target — the target widget that the matrix will transform to

contains

def contains(self, x: float, y: float) -> bool

Tests if a given point is contained in the widget.

The coordinates for (x, y) must be in widget coordinates, so (0, 0) is assumed to be the top left of widget's content area.

Parameters:

• x — X coordinate to test, relative to widget's origin
• y — Y coordinate to test, relative to widget's origin

create_pango_context

def create_pango_context(self) -> Pango.Context

Creates a new PangoContext that is configured for the widget.

The PangoContext will have the appropriate font map, font options, font description, and base direction set.

See also Widget.get_pango_context.

create_pango_layout

def create_pango_layout(self, text: str | None = ...) -> Pango.Layout

Creates a new PangoLayout that is configured for the widget.

The PangoLayout will have the appropriate font map, font description, and base direction set.

If you keep a PangoLayout created in this way around, you need to re-create it when the widgets PangoContext is replaced. This can be tracked by listening to changes of the Widget.root property on the widget.

Parameters:

• text — text to set on the layout

dispose_template

def dispose_template(self, widget_type: type | GObject.Type) -> None

Clears the template children for the widget.

This function is the opposite of Widget.init_template, and it is used to clear all the template children from a widget instance. If you bound a template child to a field in the instance structure, or in the instance private data structure, the field will be set to NULL after this function returns.

You should call this function inside the GObjectClass.dispose() implementation of any widget that called Widget.init_template. Typically, you will want to call this function last, right before chaining up to the parent type's dispose implementation, e.g.

static void
some_widget_dispose (GObject *gobject)
{
  SomeWidget *self = SOME_WIDGET (gobject);

  // Clear the template data for SomeWidget
  gtk_widget_dispose_template (GTK_WIDGET (self), SOME_TYPE_WIDGET);

  G_OBJECT_CLASS (some_widget_parent_class)->dispose (gobject);
}

Parameters:

• widget_type — the type of the widget to finalize the template for

drag_check_threshold

def drag_check_threshold(self, start_x: int, start_y: int, current_x: int, current_y: int) -> bool

Checks to see if a drag movement has passed the GTK drag threshold.

Parameters:

• start_x — X coordinate of start of drag
• start_y — Y coordinate of start of drag
• current_x — current X coordinate
• current_y — current Y coordinate

error_bell

def error_bell(self) -> None

Notifies the user about an input-related error on the widget.

If the Settings.gtk-error-bell setting is true, it calls Gdk.Surface.beep, otherwise it does nothing.

Note that the effect of Gdk.Surface.beep can be configured in many ways, depending on the windowing backend and the desktop environment or window manager that is used.

get_allocated_baseline

def get_allocated_baseline(self) -> int

:::warning Deprecated since 4.12 This API is deprecated. :::

Returns the baseline that has currently been allocated to the widget.

This function is intended to be used when implementing handlers for the GtkWidgetClass.snapshot() function, and when allocating child widgets in GtkWidgetClass.size_allocate().

get_allocated_height

def get_allocated_height(self) -> int

:::warning Deprecated since 4.12 This API is deprecated. :::

Returns the height that has currently been allocated to the widget.

To learn more about widget sizes, see the coordinate system overview.

get_allocated_width

def get_allocated_width(self) -> int

:::warning Deprecated since 4.12 This API is deprecated. :::

Returns the width that has currently been allocated to the widget.

To learn more about widget sizes, see the coordinate system overview.

get_allocation

def get_allocation(self) -> Allocation

:::warning Deprecated since 4.12 This API is deprecated. :::

Retrieves the widget’s allocation.

Note, when implementing a layout widget: a widget’s allocation will be its “adjusted” allocation, that is, the widget’s parent typically calls Widget.size_allocate with an allocation, and that allocation is then adjusted (to handle margin and alignment for example) before assignment to the widget. Widget.get_allocation returns the adjusted allocation that was actually assigned to the widget. The adjusted allocation is guaranteed to be completely contained within the Widget.size_allocate allocation, however.

So a layout widget is guaranteed that its children stay inside the assigned bounds, but not that they have exactly the bounds the widget assigned.

get_ancestor

def get_ancestor(self, widget_type: type | GObject.Type) -> Widget | None

Gets the first ancestor of the widget with type widget_type.

For example, gtk_widget_get_ancestor (widget, GTK_TYPE_BOX) gets the first GtkBox that’s an ancestor of widget. No reference will be added to the returned widget; it should not be unreferenced.

Note that unlike Widget.is_ancestor, this function considers widget to be an ancestor of itself.

Parameters:

• widget_type — ancestor type

get_baseline

def get_baseline(self) -> int

Returns the baseline that has currently been allocated to the widget.

This function is intended to be used when implementing handlers for the GtkWidgetClass.snapshot() function, and when allocating child widgets in GtkWidgetClass.size_allocate().

get_can_focus

def get_can_focus(self) -> bool

Determines whether the input focus can enter the widget or any of its children.

See Widget.set_can_focus.

get_can_target

def get_can_target(self) -> bool

Queries whether the widget can be the target of pointer events.

get_child_visible

def get_child_visible(self) -> bool

Gets the value set with Widget.set_child_visible.

If you feel a need to use this function, your code probably needs reorganization.

This function is only useful for widget implementations and should never be called by an application.

get_clipboard

def get_clipboard(self) -> Gdk.Clipboard

Gets the clipboard object for the widget.

This is a utility function to get the clipboard object for the display that widget is using.

Note that this function always works, even when widget is not realized yet.

get_color

def get_color(self) -> Gdk.RGBA

Gets the current foreground color for the widget’s style.

This function should only be used in snapshot implementations that need to do custom drawing with the foreground color.

get_css_classes

def get_css_classes(self) -> list[str]

Returns the list of style classes applied to the widget.

get_css_name

def get_css_name(self) -> str

Returns the CSS name of the widget.

get_cursor

def get_cursor(self) -> Gdk.Cursor | None

Gets the cursor set on the widget.

See Widget.set_cursor for details.

get_direction

def get_direction(self) -> TextDirection

Gets the reading direction for the widget.

See Widget.set_direction.

get_display

def get_display(self) -> Gdk.Display

Get the display for the window that the widget belongs to.

This function can only be called after the widget has been added to a widget hierarchy with a GtkRoot at the top.

In general, you should only create display-specific resources when a widget has been realized, and you should free those resources when the widget is unrealized.

get_first_child

def get_first_child(self) -> Widget | None

Returns the widget’s first child.

This function is primarily meant for widget implementations.

get_focus_child

def get_focus_child(self) -> Widget | None

Returns the focus child of the widget.

get_focus_on_click

def get_focus_on_click(self) -> bool

Returns whether the widget should grab focus when it is clicked with the mouse.

See Widget.set_focus_on_click.

get_focusable

def get_focusable(self) -> bool

Determines whether the widget can own the input focus.

See Widget.set_focusable.

get_font_map

def get_font_map(self) -> Pango.FontMap | None

Gets the font map of the widget.

See Widget.set_font_map.

get_font_options

def get_font_options(self) -> cairo.FontOptions | None

:::warning Deprecated since 4.16 This API is deprecated. :::

Returns the cairo_font_options_t of the widget.

Seee Widget.set_font_options.

get_frame_clock

def get_frame_clock(self) -> Gdk.FrameClock | None

Obtains the frame clock for a widget.

The frame clock is a global “ticker” that can be used to drive animations and repaints. The most common reason to get the frame clock is to call Gdk.FrameClock.get_frame_time, in order to get a time to use for animating. For example you might record the start of the animation with an initial value from Gdk.FrameClock.get_frame_time, and then update the animation by calling Gdk.FrameClock.get_frame_time again during each repaint.

Gdk.FrameClock.request_phase will result in a new frame on the clock, but won’t necessarily repaint any widgets. To repaint a widget, you have to use Widget.queue_draw which invalidates the widget (thus scheduling it to receive a draw on the next frame). Widget.queue_draw will also end up requesting a frame on the appropriate frame clock.

A widget’s frame clock will not change while the widget is mapped. Reparenting a widget (which implies a temporary unmap) can change the widget’s frame clock.

Unrealized widgets do not have a frame clock.

get_halign

def get_halign(self) -> Align

Gets the horizontal alignment of the widget.

For backwards compatibility reasons this method will never return one of the baseline alignments, but instead it will convert it to Align.fill or Align.center.

Baselines are not supported for horizontal alignment.

get_has_tooltip

def get_has_tooltip(self) -> bool

Returns the current value of the has-tooltip property.

get_height

def get_height(self) -> int

Returns the content height of the widget.

This function returns the height passed to its size-allocate implementation, which is the height you should be using in Widget.snapshot.

For pointer events, see Widget.contains.

To learn more about widget sizes, see the coordinate system overview.

get_hexpand

def get_hexpand(self) -> bool

Gets whether the widget would like any available extra horizontal space.

When a user resizes a window, widgets with expand set to true generally receive the extra space. For example, a list or scrollable area or document in your window would often be set to expand.

Widgets with children should use Widget.compute_expand rather than this function, to see whether any of its children, has the expand flag set. If any child of a widget wants to expand, the parent may ask to expand also.

This function only looks at the widget’s own hexpand flag, rather than computing whether the entire widget tree rooted at this widget wants to expand.

get_hexpand_set

def get_hexpand_set(self) -> bool

Gets whether the hexpand flag has been explicitly set.

If Widget.hexpand property is set, then it overrides any computed expand value based on child widgets. If hexpand is not set, then the expand value depends on whether any children of the widget would like to expand.

There are few reasons to use this function, but it’s here for completeness and consistency.

get_last_child

def get_last_child(self) -> Widget | None

Returns the widget’s last child.

This function is primarily meant for widget implementations.

get_layout_manager

def get_layout_manager(self) -> LayoutManager | None

Retrieves the layout manager of the widget.

See Widget.set_layout_manager.

get_limit_events

def get_limit_events(self) -> bool

Gets the value of the Widget.limit-events property.

get_mapped

def get_mapped(self) -> bool

Returns whether the widget is mapped.

get_margin_bottom

def get_margin_bottom(self) -> int

Gets the bottom margin of the widget.

get_margin_end

def get_margin_end(self) -> int

Gets the end margin of the widget.

get_margin_start

def get_margin_start(self) -> int

Gets the start margin of the widget.

get_margin_top

def get_margin_top(self) -> int

Gets the top margin of the widget.

get_name

def get_name(self) -> str

Retrieves the name of a widget.

See Widget.set_name for the significance of widget names.

get_native

def get_native(self) -> Native | None

Returns the nearest GtkNative ancestor of the widget.

This function will return NULL if the widget is not contained inside a widget tree with a native ancestor.

GtkNative widgets will return themselves here.

get_next_sibling

def get_next_sibling(self) -> Widget | None

Returns the widget’s next sibling.

This function is primarily meant for widget implementations.

get_opacity

def get_opacity(self) -> float

Fetches the requested opacity for the widget.

See Widget.set_opacity.

get_overflow

def get_overflow(self) -> Overflow

Returns the widget’s overflow value.

get_pango_context

def get_pango_context(self) -> Pango.Context

Gets a PangoContext that is configured for the widget.

The PangoContext will have the appropriate font map, font description, and base direction set.

Unlike the context returned by Widget.create_pango_context, this context is owned by the widget (it can be used until the screen for the widget changes or the widget is removed from its toplevel), and will be updated to match any changes to the widget’s attributes. This can be tracked by listening to changes of the Widget.root property on the widget.

get_parent

def get_parent(self) -> Widget | None

Returns the parent widget of the widget.

get_preferred_size

def get_preferred_size(self) -> tuple[Requisition, Requisition]

Retrieves the minimum and natural size of a widget, taking into account the widget’s preference for height-for-width management.

This is used to retrieve a suitable size by container widgets which do not impose any restrictions on the child placement. It can be used to deduce toplevel window and menu sizes as well as child widgets in free-form containers such as GtkFixed.

Handle with care. Note that the natural height of a height-for-width widget will generally be a smaller size than the minimum height, since the required height for the natural width is generally smaller than the required height for the minimum width.

Use Widget.measure if you want to support baseline alignment.

get_prev_sibling

def get_prev_sibling(self) -> Widget | None

Returns the widget’s previous sibling.

This function is primarily meant for widget implementations.

get_primary_clipboard

def get_primary_clipboard(self) -> Gdk.Clipboard

Gets the primary clipboard of the widget.

This is a utility function to get the primary clipboard object for the display that widget is using.

Note that this function always works, even when widget is not realized yet.

get_realized

def get_realized(self) -> bool

Determines whether the widget is realized.

get_receives_default

def get_receives_default(self) -> bool

Determines whether the widget is always treated as the default widget within its toplevel when it has the focus, even if another widget is the default.

See Widget.set_receives_default.

get_request_mode

def get_request_mode(self) -> SizeRequestMode

Gets whether the widget prefers a height-for-width layout or a width-for-height layout.

Single-child widgets generally propagate the preference of their child, more complex widgets need to request something either in context of their children or in context of their allocation capabilities.

get_root

def get_root(self) -> Root | None

Returns the GtkRoot widget of the widget.

This function will return NULL if the widget is not contained inside a widget tree with a root widget.

GtkRoot widgets will return themselves here.

get_scale_factor

def get_scale_factor(self) -> int

Retrieves the internal scale factor that maps from window coordinates to the actual device pixels.

On traditional systems this is 1, on high density outputs, it can be a higher value (typically 2).

See Gdk.Surface.get_scale_factor.

Note that modern systems may support fractional scaling, where the scale factor is not an integer. On such systems, this function will return the next higher integer value, but you probably want to use Gdk.Surface.get_scale to get the fractional scale value.

get_sensitive

def get_sensitive(self) -> bool

Returns the widget’s sensitivity.

This function returns the value that has been set using Widget.set_sensitive).

The effective sensitivity of a widget is however determined by both its own and its parent widget’s sensitivity. See Widget.is_sensitive.

get_settings

def get_settings(self) -> Settings

Gets the settings object holding the settings used for the widget.

Note that this function can only be called when the GtkWidget is attached to a toplevel, since the settings object is specific to a particular display. If you want to monitor the widget for changes in its settings, connect to the notify::display signal.

get_size

def get_size(self, orientation: Orientation | int) -> int

Returns the content width or height of the widget.

Which dimension is returned depends on orientation.

This is equivalent to calling Widget.get_width for Orientation.horizontal or Widget.get_height for Orientation.vertical, but can be used when writing orientation-independent code, such as when implementing Orientable widgets.

To learn more about widget sizes, see the coordinate system overview.

Parameters:

• orientation — the orientation to query

get_size_request

def get_size_request(self) -> tuple[int, int]

Gets the size request that was explicitly set for the widget.

A value of -1 stored in width or height indicates that that dimension has not been set explicitly and the natural requisition of the widget will be used instead.

See Widget.set_size_request.

To get the size a widget will actually request, call Widget.measure instead of this function.

get_state_flags

def get_state_flags(self) -> StateFlags

Returns the widget state as a flag set.

It is worth mentioning that the effective StateFlags.insensitive state will be returned, that is, also based on parent insensitivity, even if widget itself is sensitive.

Also note that if you are looking for a way to obtain the StateFlags to pass to a StyleContext method, you should look at StyleContext.get_state.

get_style_context

def get_style_context(self) -> StyleContext

:::warning Deprecated since 4.10 This API is deprecated. :::

Returns the style context associated to the widget.

The returned object is guaranteed to be the same for the lifetime of widget.

get_template_child

def get_template_child(self, widget_type: type | GObject.Type, name: str) -> GObject.Object

Fetches an object build from the template XML for widget_type in the widget.

This will only report children which were previously declared with WidgetClass.bind_template_child_full or one of its variants.

This function is only meant to be called for code which is private to the widget_type which declared the child and is meant for language bindings which cannot easily make use of the GObject structure offsets.

Parameters:

• widget_type — The type of the widget class that defines the child in the template
• name — ID of the child defined in the template XML

get_tooltip_markup

def get_tooltip_markup(self) -> str | None

Gets the contents of the tooltip for the widget.

If the tooltip has not been set using Widget.set_tooltip_markup, this function returns NULL.

get_tooltip_text

def get_tooltip_text(self) -> str | None

Gets the contents of the tooltip for the widget.

If the widget's tooltip was set using Widget.set_tooltip_markup, this function will return the escaped text.

get_valign

def get_valign(self) -> Align

Gets the vertical alignment of the widget.

get_vexpand

def get_vexpand(self) -> bool

Gets whether the widget would like any available extra vertical space.

See Widget.get_hexpand for more detail.

get_vexpand_set

def get_vexpand_set(self) -> bool

Gets whether the vexpand flag has been explicitly set.

See Widget.get_hexpand_set for more detail.

get_visible

def get_visible(self) -> bool

Determines whether the widget is visible.

If you want to take into account whether the widget’s parent is also marked as visible, use Widget.is_visible instead.

This function does not check if the widget is obscured in any way.

See Widget.set_visible.

get_width

def get_width(self) -> int

Returns the content width of the widget.

This function returns the width passed to its size-allocate implementation, which is the width you should be using in Widget.snapshot.

For pointer events, see Widget.contains.

To learn more about widget sizes, see the coordinate system overview.

grab_focus

def grab_focus(self) -> bool

Causes widget to have the keyboard focus for the window that it belongs to.

If widget is not focusable, or its Widget.grab_focus implementation cannot transfer the focus to a descendant of widget that is focusable, it will not take focus and false will be returned.

Calling Widget.grab_focus on an already focused widget is allowed, should not have an effect, and return true.

has_css_class

def has_css_class(self, css_class: str) -> bool

Returns whether a style class is currently applied to the widget.

Parameters:

• css_class — style class, without the leading period

has_default

def has_default(self) -> bool

Determines whether the widget is the current default widget within its toplevel.

has_focus

def has_focus(self) -> bool

Determines if the widget has the global input focus.

See Widget.is_focus for the difference between having the global input focus, and only having the focus within a toplevel.

has_visible_focus

def has_visible_focus(self) -> bool

Determines if the widget should show a visible indication that it has the global input focus.

This is a convenience function that takes into account whether focus indication should currently be shown in the toplevel window of widget. See Window.get_focus_visible for more information about focus indication.

To find out if the widget has the global input focus, use Widget.has_focus.

hide

def hide(self) -> None

:::warning Deprecated since 4.10 This API is deprecated. :::

Reverses the effects of [method.Gtk.Widget.show].

This is causing the widget to be hidden (invisible to the user).

in_destruction

def in_destruction(self) -> bool

Returns whether the widget is currently being destroyed.

This information can sometimes be used to avoid doing unnecessary work.

init_template

def init_template(self) -> None

Creates and initializes child widgets defined in templates.

This function must be called in the instance initializer for any class which assigned itself a template using WidgetClass.set_template.

It is important to call this function in the instance initializer of a widget subclass and not in GObject.constructed() or GObject.constructor() for two reasons:

• derived widgets will assume that the composite widgets defined by its parent classes have been created in their relative instance initializers
• when calling g_object_new() on a widget with composite templates, it’s important to build the composite widgets before the construct properties are set. Properties passed to g_object_new() should take precedence over properties set in the private template XML

A good rule of thumb is to call this function as the first thing in an instance initialization function.

insert_action_group

def insert_action_group(self, name: str, group: Gio.ActionGroup | None = ...) -> None

Inserts an action group into the widget's actions.

Children of widget that implement Actionable can then be associated with actions in group by setting their “action-name” to prefix.action-name.

Note that inheritance is defined for individual actions. I.e. even if you insert a group with prefix prefix, actions with the same prefix will still be inherited from the parent, unless the group contains an action with the same name.

If group is NULL, a previously inserted group for name is removed from widget.

Parameters:

• name — the prefix for actions in group
• group — an action group

insert_after

def insert_after(self, parent: Widget, previous_sibling: Widget | None = ...) -> None

Sets the parent widget of the widget.

In contrast to Widget.set_parent, this function inserts widget at a specific position into the list of children of the parent widget.

It will be placed after previous_sibling, or at the beginning if previous_sibling is NULL.

After calling this function, gtk_widget_get_prev_sibling (widget) will return previous_sibling.

If parent is already set as the parent widget of widget, this function can also be used to reorder widget in the child widget list of parent.

This function is primarily meant for widget implementations; if you are just using a widget, you must use its own API for adding children.

Parameters:

• parent — the parent widget to insert widget into
• previous_sibling — the new previous sibling of widget

insert_before

def insert_before(self, parent: Widget, next_sibling: Widget | None = ...) -> None

Sets the parent widget of the widget.

In contrast to Widget.set_parent, this function inserts widget at a specific position into the list of children of the parent widget.

It will be placed before next_sibling, or at the end if next_sibling is NULL.

After calling this function, gtk_widget_get_next_sibling (widget) will return next_sibling.

If parent is already set as the parent widget of widget, this function can also be used to reorder widget in the child widget list of parent.

This function is primarily meant for widget implementations; if you are just using a widget, you must use its own API for adding children.

Parameters:

• parent — the parent widget to insert widget into
• next_sibling — the new next sibling of widget

is_ancestor

def is_ancestor(self, ancestor: Widget) -> bool

Determines whether the widget is a descendent of ancestor.

Parameters:

• ancestor — another GtkWidget

is_drawable

def is_drawable(self) -> bool

Determines whether the widget can be drawn to.

A widget can be drawn if it is mapped and visible.

is_focus

def is_focus(self) -> bool

Determines if the widget is the focus widget within its toplevel.

This does not mean that the Widget.has-focus property is necessarily set; Widget.has-focus will only be set if the toplevel widget additionally has the global input focus.

is_sensitive

def is_sensitive(self) -> bool

Returns the widget’s effective sensitivity.

This means it is sensitive itself and also its parent widget is sensitive.

is_visible

def is_visible(self) -> bool

Determines whether the widget and all its parents are marked as visible.

This function does not check if the widget is obscured in any way.

See also Widget.get_visible and Widget.set_visible.

keynav_failed

def keynav_failed(self, direction: DirectionType | int) -> bool

Emits the Widget.keynav-failed signal on the widget.

This function should be called whenever keyboard navigation within a single widget hits a boundary.

The return value of this function should be interpreted in a way similar to the return value of Widget.child_focus. When true is returned, stay in the widget, the failed keyboard navigation is ok and/or there is nowhere we can/should move the focus to. When false is returned, the caller should continue with keyboard navigation outside the widget, e.g. by calling Widget.child_focus on the widget’s toplevel.

The default Widget.keynav-failed handler returns false for DirectionType.tab-forward and DirectionType.tab-backward. For the other values of DirectionType it returns true.

Whenever the default handler returns true, it also calls Widget.error_bell to notify the user of the failed keyboard navigation.

A use case for providing an own implementation of ::keynav-failed (either by connecting to it or by overriding it) would be a row of Entry widgets where the user should be able to navigate the entire row with the cursor keys, as e.g. known from user interfaces that require entering license keys.

Parameters:

• direction — direction of focus movement

list_mnemonic_labels

def list_mnemonic_labels(self) -> list[Widget]

Returns the widgets for which this widget is the target of a mnemonic.

Typically, these widgets will be labels. See, for example, Label.set_mnemonic_widget.

The widgets in the list are not individually referenced. If you want to iterate through the list and perform actions involving callbacks that might destroy the widgets, you must call g_list_foreach (result, (GFunc)g_object_ref, NULL) first, and then unref all the widgets afterwards.

map_

def map_(self) -> None

Causes a widget to be mapped if it isn’t already.

This function is only for use in widget implementations.

measure

def measure(self, orientation: Orientation | int, for_size: int) -> tuple[int, int, int, int]

Measures widget in the orientation orientation and for the given for_size.

As an example, if orientation is Orientation.HORIZONTAL and for_size is 300, this functions will compute the minimum and natural width of widget if it is allocated at a height of 300 pixels.

See GtkWidget’s geometry management section for a more details on implementing GtkWidgetClass.measure().

Parameters:

• orientation — the orientation to measure
• for_size — Size for the opposite of orientation, i.e. if orientation is Orientation.HORIZONTAL, this is the height the widget should be measured with. The Orientation.VERTICAL case is analogous. This way, both height-for-width and width-for-height requests can be implemented. If no size is known, -1 can be passed.

mnemonic_activate

def mnemonic_activate(self, group_cycling: bool) -> bool

Emits the Widget.mnemonic-activate signal.

Parameters:

• group_cycling — true if there are other widgets with the same mnemonic

observe_children

def observe_children(self) -> Gio.ListModel

Returns a list model to track the children of the widget.

Calling this function will enable extra internal bookkeeping to track children and emit signals on the returned listmodel. It may slow down operations a lot.

Applications should try hard to avoid calling this function because of the slowdowns.

observe_controllers

def observe_controllers(self) -> Gio.ListModel

Returns a list model to track the event controllers of the widget.

Calling this function will enable extra internal bookkeeping to track controllers and emit signals on the returned listmodel. It may slow down operations a lot.

Applications should try hard to avoid calling this function because of the slowdowns.

pick

def pick(self, x: float, y: float, flags: PickFlags | int) -> Widget | None

Finds the descendant of the widget closest to a point.

The point (x, y) must be given in widget coordinates, so (0, 0) is assumed to be the top left of widget's content area.

Usually widgets will return NULL if the given coordinate is not contained in widget checked via Widget.contains. Otherwise they will recursively try to find a child that does not return NULL. Widgets are however free to customize their picking algorithm.

This function is used on the toplevel to determine the widget below the mouse cursor for purposes of hover highlighting and delivering events.

Parameters:

• x — x coordinate to test, relative to widget's origin
• y — y coordinate to test, relative to widget's origin
• flags — flags to influence what is picked

queue_allocate

def queue_allocate(self) -> None

Flags the widget for a rerun of the Widget.size_allocate function.

Use this function instead of Widget.queue_resize when the widget's size request didn't change but it wants to reposition its contents.

An example user of this function is Widget.set_halign.

This function is only for use in widget implementations.

queue_draw

def queue_draw(self) -> None

Schedules this widget to be redrawn.

The redraw will happen in the paint phase of the current or the next frame.

This means widget's Widget.snapshot implementation will be called.

queue_resize

def queue_resize(self) -> None

Flags a widget to have its size renegotiated.

This should be called when a widget for some reason has a new size request. For example, when you change the text in a Label, the label queues a resize to ensure there’s enough space for the new text.

Note that you cannot call Widget.queue_resize on a widget from inside its implementation of the Widget.size_allocate virtual method. Calls to Widget.queue_resize from inside Widget.size_allocate will be silently ignored.

This function is only for use in widget implementations.

realize

def realize(self) -> None

Creates the GDK resources associated with a widget.

Normally realization happens implicitly; if you show a widget and all its parent containers, then the widget will be realized and mapped automatically.

Realizing a widget requires all the widget’s parent widgets to be realized; calling this function realizes the widget’s parents in addition to widget itself. If a widget is not yet inside a toplevel window when you realize it, bad things will happen.

This function is primarily used in widget implementations, and isn’t very useful otherwise. Many times when you think you might need it, a better approach is to connect to a signal that will be called after the widget is realized automatically, such as Widget.realize.

remove_controller

def remove_controller(self, controller: EventController) -> None

Removes an event controller from the widget.

The removed event controller will not receive any more events, and should not be used again.

Widgets will remove all event controllers automatically when they are destroyed, there is normally no need to call this function.

Parameters:

• controller — an event controller

remove_css_class

def remove_css_class(self, css_class: str) -> None

Removes a style from the widget.

After this, the style of widget will stop matching for css_class.

Parameters:

• css_class — style class to remove from widget, without the leading period

remove_mnemonic_label

def remove_mnemonic_label(self, label: Widget) -> None

Removes a widget from the list of mnemonic labels for this widget.

See Widget.list_mnemonic_labels.

The widget must have previously been added to the list with Widget.add_mnemonic_label.

Parameters:

• label — a widget that is a mnemonic label for widget

remove_tick_callback

def remove_tick_callback(self, id: int) -> None

Removes a tick callback previously registered with Widget.add_tick_callback.

Parameters:

• id — an ID returned by Widget.add_tick_callback

set_can_focus

def set_can_focus(self, can_focus: bool) -> None

Sets whether the input focus can enter the widget or any of its children.

Applications should set can_focus to false to mark a widget as for pointer/touch use only.

Note that having can_focus be true is only one of the necessary conditions for being focusable. A widget must also be sensitive and focusable and not have an ancestor that is marked as not can-focus in order to receive input focus.

See Widget.grab_focus for actually setting the input focus on a widget.

Parameters:

• can_focus — whether the input focus can enter the widget or any of its children

set_can_target

def set_can_target(self, can_target: bool) -> None

Sets whether the widget can be the target of pointer events.

Parameters:

• can_target — whether this widget should be able to receive pointer events

set_child_visible

def set_child_visible(self, child_visible: bool) -> None

Sets whether the widget should be mapped along with its parent.

The child visibility can be set for widget before it is added to a container with Widget.set_parent, to avoid mapping children unnecessary before immediately unmapping them. However it will be reset to its default state of true when the widget is removed from a container.

Note that changing the child visibility of a widget does not queue a resize on the widget. Most of the time, the size of a widget is computed from all visible children, whether or not they are mapped. If this is not the case, the container can queue a resize itself.

This function is only useful for widget implementations and should never be called by an application.

Parameters:

• child_visible — whether widget should be mapped along with its parent

set_css_classes

def set_css_classes(self, classes: list[str]) -> None

Replaces the current style classes of the widget with classes.

Parameters:

• classes — NULL-terminated list of style classes

set_cursor

def set_cursor(self, cursor: Gdk.Cursor | None = ...) -> None

Sets the cursor to be shown when the pointer hovers over the widget.

If the cursor is NULL, widget will use the cursor inherited from its parent.

Parameters:

• cursor — the new cursor

set_cursor_from_name

def set_cursor_from_name(self, name: str | None = ...) -> None

Sets the cursor to be shown when the pointer hovers over the widget.

This is a utility function that creates a cursor via Gdk.Cursor.new_from_name and then sets it on widget with Widget.set_cursor. See those functions for details.

On top of that, this function allows name to be NULL, which will do the same as calling Widget.set_cursor with a NULL cursor.

Parameters:

• name — the name of the cursor

set_direction

def set_direction(self, dir: TextDirection | int) -> None

Sets the reading direction on the widget.

This direction controls the primary direction for widgets containing text, and also the direction in which the children of a container are packed. The ability to set the direction is present in order so that correct localization into languages with right-to-left reading directions can be done.

Generally, applications will let the default reading direction prevail, except for widgets where the children are arranged in an order that is explicitly visual rather than logical (such as buttons for text justification).

If the direction is set to TextDirection.none, then the value set by Widget.set_default_direction will be used.

Parameters:

• dir — the new direction

set_focus_child

def set_focus_child(self, child: Widget | None = ...) -> None

Set the focus child of the widget.

This function is only suitable for widget implementations. If you want a certain widget to get the input focus, call Widget.grab_focus on it.

Parameters:

• child — a direct child widget of widget or NULL to unset the focus child

set_focus_on_click

def set_focus_on_click(self, focus_on_click: bool) -> None

Sets whether the widget should grab focus when it is clicked with the mouse.

Making mouse clicks not grab focus is useful in places like toolbars where you don’t want the keyboard focus removed from the main area of the application.

Parameters:

• focus_on_click — whether the widget should grab focus when clicked with the mouse

set_focusable

def set_focusable(self, focusable: bool) -> None

Sets whether the widget can own the input focus.

Widget implementations should set focusable to true in their init() function if they want to receive keyboard input.

Note that having focusable be true is only one of the necessary conditions for being focusable. A widget must also be sensitive and can-focus and not have an ancestor that is marked as not can-focus in order to receive input focus.

See Widget.grab_focus for actually setting the input focus on a widget.

Parameters:

• focusable — whether or not widget can own the input focus

set_font_map

def set_font_map(self, font_map: Pango.FontMap | None = ...) -> None

Sets the font map to use for text rendering in the widget.

The font map is the object that is used to look up fonts. Setting a custom font map can be useful in special situations, e.g. when you need to add application-specific fonts to the set of available fonts.

When not set, the widget will inherit the font map from its parent.

Parameters:

• font_map — a PangoFontMap

set_font_options

def set_font_options(self, options: cairo.FontOptions | None = ...) -> None

:::warning Deprecated since 4.16 This API is deprecated. :::

Sets the cairo_font_options_t used for text rendering in the widget.

When not set, the default font options for the GdkDisplay will be used.

Parameters:

• options — a cairo_font_options_t struct to unset any previously set default font options

set_halign

def set_halign(self, align: Align | int) -> None

Sets the horizontal alignment of the widget.

Parameters:

• align — the horizontal alignment

set_has_tooltip

def set_has_tooltip(self, has_tooltip: bool) -> None

Sets the has-tooltip property on the widget.

Parameters:

• has_tooltip — whether or not widget has a tooltip

set_hexpand

def set_hexpand(self, expand: bool) -> None

Sets whether the widget would like any available extra horizontal space.

When a user resizes a window, widgets with expand set to true generally receive the extra space. For example, a list or scrollable area or document in your window would often be set to expand.

Call this function to set the expand flag if you would like your widget to become larger horizontally when the window has extra room.

By default, widgets automatically expand if any of their children want to expand. (To see if a widget will automatically expand given its current children and state, call Widget.compute_expand. A widget can decide how the expandability of children affects its own expansion by overriding the compute_expand virtual method on GtkWidget.).

Setting hexpand explicitly with this function will override the automatic expand behavior.

This function forces the widget to expand or not to expand, regardless of children. The override occurs because Widget.set_hexpand sets the hexpand-set property (see Widget.set_hexpand_set) which causes the widget’s hexpand value to be used, rather than looking at children and widget state.

Parameters:

• expand — whether to expand

set_hexpand_set

def set_hexpand_set(self, set: bool) -> None

Sets whether the hexpand flag will be used.

The Widget.hexpand-set property will be set automatically when you call Widget.set_hexpand to set hexpand, so the most likely reason to use this function would be to unset an explicit expand flag.

If hexpand is set, then it overrides any computed expand value based on child widgets. If hexpand is not set, then the expand value depends on whether any children of the widget would like to expand.

There are few reasons to use this function, but it’s here for completeness and consistency.

Parameters:

• set — value for hexpand-set property

set_layout_manager

def set_layout_manager(self, layout_manager: LayoutManager | None = ...) -> None

Sets the layout manager to use for measuring and allocating children of the widget.

Parameters:

• layout_manager — a layout manager

set_limit_events

def set_limit_events(self, limit_events: bool) -> None

Sets whether the widget acts like a modal dialog, with respect to event delivery.

Parameters:

• limit_events — whether to limit events

set_margin_bottom

def set_margin_bottom(self, margin: int) -> None

Sets the bottom margin of the widget.

Parameters:

• margin — the bottom margin

set_margin_end

def set_margin_end(self, margin: int) -> None

Sets the end margin of the widget.

Parameters:

• margin — the end margin

set_margin_start

def set_margin_start(self, margin: int) -> None

Sets the start margin of the widget.

Parameters:

• margin — the start margin

set_margin_top

def set_margin_top(self, margin: int) -> None

Sets the top margin of the widget.

Parameters:

• margin — the top margin

set_name

def set_name(self, name: str) -> None

Sets a widgets name.

Setting a name allows you to refer to the widget from a CSS file. You can apply a style to widgets with a particular name in the CSS file. See the documentation for the CSS syntax (on the same page as the docs for StyleContext.

Note that the CSS syntax has certain special characters to delimit and represent elements in a selector (period, #, >, *...), so using these will make your widget impossible to match by name. Any combination of alphanumeric symbols, dashes and underscores will suffice.

Parameters:

• name — name for the widget

set_opacity

def set_opacity(self, opacity: float) -> None

Requests the widget to be rendered partially transparent.

An opacity of 0 is fully transparent and an opacity of 1 is fully opaque.

Opacity works on both toplevel widgets and child widgets, although there are some limitations: For toplevel widgets, applying opacity depends on the capabilities of the windowing system. On X11, this has any effect only on X displays with a compositing manager, see Gdk.Display.is_composited. On Windows and Wayland it will always work, although setting a window’s opacity after the window has been shown may cause some flicker.

Note that the opacity is inherited through inclusion — if you set a toplevel to be partially translucent, all of its content will appear translucent, since it is ultimatively rendered on that toplevel. The opacity value itself is not inherited by child widgets (since that would make widgets deeper in the hierarchy progressively more translucent). As a consequence, Popover instances and other Native widgets with their own surface will use their own opacity value, and thus by default appear non-translucent, even if they are attached to a toplevel that is translucent.

Parameters:

• opacity — desired opacity, between 0 and 1

set_overflow

def set_overflow(self, overflow: Overflow | int) -> None

Sets how the widget treats content that is drawn outside the it's content area.

See the definition of Overflow for details.

This setting is provided for widget implementations and should not be used by application code.

The default value is Overflow.visible.

Parameters:

• overflow — desired overflow value

set_parent

def set_parent(self, parent: Widget) -> None

Sets the parent widget of the widget.

This takes care of details such as updating the state and style of the child to reflect its new location and resizing the parent. The opposite function is Widget.unparent.

This function is useful only when implementing subclasses of GtkWidget.

Parameters:

• parent — parent widget

set_receives_default

def set_receives_default(self, receives_default: bool) -> None

Sets whether the widget will be treated as the default widget within its toplevel when it has the focus, even if another widget is the default.

Parameters:

• receives_default — whether or not widget can be a default widget

set_sensitive

def set_sensitive(self, sensitive: bool) -> None

Sets the sensitivity of the widget.

A widget is sensitive if the user can interact with it. Insensitive widgets are “grayed out” and the user can’t interact with them. Insensitive widgets are known as “inactive”, “disabled”, or “ghosted” in some other toolkits.

Parameters:

• sensitive — true to make the widget sensitive

set_size_request

def set_size_request(self, width: int, height: int) -> None

Sets the minimum size of the widget.

That is, the widget’s size request will be at least width by height. You can use this function to force a widget to be larger than it normally would be.

In most cases, Window.set_default_size is a better choice for toplevel windows than this function; setting the default size will still allow users to shrink the window. Setting the size request will force them to leave the window at least as large as the size request.

Note the inherent danger of setting any fixed size - themes, translations into other languages, different fonts, and user action can all change the appropriate size for a given widget. So, it is basically impossible to hardcode a size that will always work.

The size request of a widget is the smallest size a widget can accept while still functioning well and drawing itself correctly. However in some strange cases a widget may be allocated less than its requested size, and in many cases a widget may be allocated more space than it requested.

If the size request in a given direction is -1 (unset), then the “natural” size request of the widget will be used instead.

The size request set here does not include any margin from the properties Widget.margin-start, Widget.margin-end, Widget.margin-top, and Widget.margin-bottom, but it does include pretty much all other padding or border properties set by any subclass of GtkWidget.

Parameters:

• width — width widget should request, or -1 to unset
• height — height widget should request, or -1 to unset

set_state_flags

def set_state_flags(self, flags: StateFlags | int, clear: bool) -> None

Turns on flag values in the current widget state.

Typical widget states are insensitive, prelighted, etc.

This function accepts the values StateFlags.dir-ltr and StateFlags.dir-rtl but ignores them. If you want to set the widget's direction, use Widget.set_direction.

This function is for use in widget implementations.

Parameters:

• flags — state flags to turn on
• clear — whether to clear state before turning on flags

set_tooltip_markup

def set_tooltip_markup(self, markup: str | None = ...) -> None

Sets the contents of the tooltip for widget.

markup must contain Pango markup.

This function will take care of setting the Widget.has-tooltip as a side effect, and of the default handler for the Widget.query-tooltip signal.

See also Tooltip.set_markup.

Parameters:

• markup — the contents of the tooltip for widget

set_tooltip_text

def set_tooltip_text(self, text: str | None = ...) -> None

Sets the contents of the tooltip for the widget.

If text contains any markup, it will be escaped.

This function will take care of setting Widget.has-tooltip as a side effect, and of the default handler for the Widget.query-tooltip signal.

See also Tooltip.set_text.

Parameters:

• text — the contents of the tooltip for widget

set_valign

def set_valign(self, align: Align | int) -> None

Sets the vertical alignment of the widget.

Parameters:

• align — the vertical alignment

set_vexpand

def set_vexpand(self, expand: bool) -> None

Sets whether the widget would like any available extra vertical space.

See Widget.set_hexpand for more detail.

Parameters:

• expand — whether to expand

set_vexpand_set

def set_vexpand_set(self, set: bool) -> None

Sets whether the vexpand flag will be used.

See Widget.set_hexpand_set for more detail.

Parameters:

• set — value for vexpand-set property

set_visible

def set_visible(self, visible: bool) -> None

Sets the visibility state of widget.

Note that setting this to true doesn’t mean the widget is actually viewable, see Widget.get_visible.

Parameters:

• visible — whether the widget should be shown or not

should_layout

def should_layout(self) -> bool

Returns whether the widget should contribute to the measuring and allocation of its parent.

This is false for invisible children, but also for children that have their own surface, such as Popover instances.

show

def show(self) -> None

:::warning Deprecated since 4.10 This API is deprecated. :::

Flags a widget to be displayed.

Any widget that isn’t shown will not appear on the screen.

Remember that you have to show the containers containing a widget, in addition to the widget itself, before it will appear onscreen.

When a toplevel widget is shown, it is immediately realized and mapped; other shown widgets are realized and mapped when their toplevel widget is realized and mapped.

size_allocate

def size_allocate(self, allocation: Allocation, baseline: int) -> None

Allocates widget with a transformation that translates the origin to the position in allocation.

This is a simple form of Widget.allocate.

Parameters:

• allocation — position and size to be allocated to widget
• baseline — the baseline of the child, or -1

snapshot_child

def snapshot_child(self, child: Widget, snapshot: Snapshot) -> None

Snapshots a child of the widget.

When a widget receives a call to the snapshot function, it must send synthetic Widget.snapshot calls to all children. This function provides a convenient way of doing this. A widget, when it receives a call to its Widget.snapshot function, calls Widget.snapshot_child once for each child, passing in the snapshot the widget received.

This function takes care of translating the origin of snapshot, and deciding whether the child needs to be snapshot.

It does nothing for children that implement GtkNative.

Parameters:

• child — a child of widget
• snapshot — snapshot as passed to the widget. In particular, no calls to Snapshot.translate or other transform calls should have been made

translate_coordinates

def translate_coordinates(self, dest_widget: Widget, src_x: float, src_y: float) -> tuple[bool, float, float]

:::warning Deprecated since 4.12 This API is deprecated. :::

Translates coordinates relative to src_widget’s allocation to coordinates relative to dest_widget’s allocations.

In order to perform this operation, both widget must share a common ancestor. If that is not the case, dest_x and dest_y are set to 0 and false is returned.

Parameters:

• dest_widget — another widget
• src_x — X position in widget coordinates of src_widget
• src_y — Y position in widget coordinates of src_widget

trigger_tooltip_query

def trigger_tooltip_query(self) -> None

Triggers a tooltip query on the display of the widget.

unmap

def unmap(self) -> None

Causes a widget to be unmapped if it’s currently mapped.

This function is only for use in widget implementations.

unparent

def unparent(self) -> None

Removes widget from its parent.

This function is only for use in widget implementations, typically in dispose.

unrealize

def unrealize(self) -> None

Causes a widget to be unrealized.

This frees all GDK resources associated with the widget.

This function is only useful in widget implementations.

unset_state_flags

def unset_state_flags(self, flags: StateFlags | int) -> None

Turns off flag values for the current widget state.

See Widget.set_state_flags.

This function is for use in widget implementations.

Parameters:

• flags — state flags to turn off

Static functions

get_default_direction

@staticmethod
def get_default_direction() -> TextDirection

Obtains the default reading direction.

See Widget.set_default_direction.

set_default_direction

@staticmethod
def set_default_direction(dir: TextDirection | int) -> None

Sets the default reading direction for widgets.

See Widget.set_direction.

Parameters:

• dir — the new default direction, either TextDirection.ltr or TextDirection.rtl

Virtual methods

do_compute_expand

def do_compute_expand(self, hexpand_p: bool, vexpand_p: bool) -> None

Computes whether a container should give this widget extra space when possible.

do_contains

def do_contains(self, x: float, y: float) -> bool

Tests if a given point is contained in the widget.

The coordinates for (x, y) must be in widget coordinates, so (0, 0) is assumed to be the top left of widget's content area.

Parameters:

• x — X coordinate to test, relative to widget's origin
• y — Y coordinate to test, relative to widget's origin

do_css_changed

def do_css_changed(self, change: CssStyleChange) -> None

Vfunc called when the CSS used by widget was changed. Widgets should then discard their caches that depend on CSS and queue resizes or redraws accordingly. The default implementation will take care of this for all the default CSS properties, so implementations must chain up.

do_direction_changed

def do_direction_changed(self, previous_direction: TextDirection | int) -> None

Signal emitted when the text direction of a widget changes.

do_focus

def do_focus(self, direction: DirectionType | int) -> bool

Vfunc for Widget.child_focus

do_get_request_mode

def do_get_request_mode(self) -> SizeRequestMode

Gets whether the widget prefers a height-for-width layout or a width-for-height layout.

Single-child widgets generally propagate the preference of their child, more complex widgets need to request something either in context of their children or in context of their allocation capabilities.

do_grab_focus

def do_grab_focus(self) -> bool

Causes widget to have the keyboard focus for the window that it belongs to.

If widget is not focusable, or its Widget.grab_focus implementation cannot transfer the focus to a descendant of widget that is focusable, it will not take focus and false will be returned.

Calling Widget.grab_focus on an already focused widget is allowed, should not have an effect, and return true.

do_hide

def do_hide(self) -> None

:::warning Deprecated since 4.10 This API is deprecated. :::

Reverses the effects of [method.Gtk.Widget.show].

This is causing the widget to be hidden (invisible to the user).

do_keynav_failed

def do_keynav_failed(self, direction: DirectionType | int) -> bool

Emits the Widget.keynav-failed signal on the widget.

This function should be called whenever keyboard navigation within a single widget hits a boundary.

The return value of this function should be interpreted in a way similar to the return value of Widget.child_focus. When true is returned, stay in the widget, the failed keyboard navigation is ok and/or there is nowhere we can/should move the focus to. When false is returned, the caller should continue with keyboard navigation outside the widget, e.g. by calling Widget.child_focus on the widget’s toplevel.

The default Widget.keynav-failed handler returns false for DirectionType.tab-forward and DirectionType.tab-backward. For the other values of DirectionType it returns true.

Whenever the default handler returns true, it also calls Widget.error_bell to notify the user of the failed keyboard navigation.

A use case for providing an own implementation of ::keynav-failed (either by connecting to it or by overriding it) would be a row of Entry widgets where the user should be able to navigate the entire row with the cursor keys, as e.g. known from user interfaces that require entering license keys.

Parameters:

• direction — direction of focus movement

do_map_

def do_map_(self) -> None

Causes a widget to be mapped if it isn’t already.

This function is only for use in widget implementations.

do_measure

def do_measure(self, orientation: Orientation | int, for_size: int) -> tuple[int, int, int, int]

Measures widget in the orientation orientation and for the given for_size.

As an example, if orientation is Orientation.HORIZONTAL and for_size is 300, this functions will compute the minimum and natural width of widget if it is allocated at a height of 300 pixels.

See GtkWidget’s geometry management section for a more details on implementing GtkWidgetClass.measure().

Parameters:

• orientation — the orientation to measure
• for_size — Size for the opposite of orientation, i.e. if orientation is Orientation.HORIZONTAL, this is the height the widget should be measured with. The Orientation.VERTICAL case is analogous. This way, both height-for-width and width-for-height requests can be implemented. If no size is known, -1 can be passed.

do_mnemonic_activate

def do_mnemonic_activate(self, group_cycling: bool) -> bool

Emits the Widget.mnemonic-activate signal.

Parameters:

• group_cycling — true if there are other widgets with the same mnemonic

do_move_focus

def do_move_focus(self, direction: DirectionType | int) -> None

Signal emitted when a change of focus is requested

do_query_tooltip

def do_query_tooltip(self, x: int, y: int, keyboard_tooltip: bool, tooltip: Tooltip) -> bool

Signal emitted when “has-tooltip” is True and the hover timeout has expired with the cursor hovering “above” widget; or emitted when widget got focus in keyboard mode.

do_realize

def do_realize(self) -> None

Creates the GDK resources associated with a widget.

Normally realization happens implicitly; if you show a widget and all its parent containers, then the widget will be realized and mapped automatically.

Realizing a widget requires all the widget’s parent widgets to be realized; calling this function realizes the widget’s parents in addition to widget itself. If a widget is not yet inside a toplevel window when you realize it, bad things will happen.

This function is primarily used in widget implementations, and isn’t very useful otherwise. Many times when you think you might need it, a better approach is to connect to a signal that will be called after the widget is realized automatically, such as Widget.realize.

do_root

def do_root(self) -> None

Called when the widget gets added to a GtkRoot widget. Must chain up

do_set_focus_child

def do_set_focus_child(self, child: Widget | None = ...) -> None

Set the focus child of the widget.

This function is only suitable for widget implementations. If you want a certain widget to get the input focus, call Widget.grab_focus on it.

Parameters:

• child — a direct child widget of widget or NULL to unset the focus child

do_show

def do_show(self) -> None

:::warning Deprecated since 4.10 This API is deprecated. :::

Flags a widget to be displayed.

Any widget that isn’t shown will not appear on the screen.

Remember that you have to show the containers containing a widget, in addition to the widget itself, before it will appear onscreen.

When a toplevel widget is shown, it is immediately realized and mapped; other shown widgets are realized and mapped when their toplevel widget is realized and mapped.

do_size_allocate

def do_size_allocate(self, width: int, height: int, baseline: int) -> None

Called to set the allocation, if the widget does not have a layout manager.

do_snapshot

def do_snapshot(self, snapshot: Snapshot) -> None

Vfunc called when a new snapshot of the widget has to be taken.

do_state_flags_changed

def do_state_flags_changed(self, previous_state_flags: StateFlags | int) -> None

Signal emitted when the widget state changes, see Widget.get_state_flags.

do_system_setting_changed

def do_system_setting_changed(self, settings: SystemSetting | int) -> None

Emitted when a system setting was changed. Must chain up.

do_unmap

def do_unmap(self) -> None

Causes a widget to be unmapped if it’s currently mapped.

This function is only for use in widget implementations.

do_unrealize

def do_unrealize(self) -> None

Causes a widget to be unrealized.

This frees all GDK resources associated with the widget.

This function is only useful in widget implementations.

do_unroot

def do_unroot(self) -> None

Called when the widget is about to be removed from its GtkRoot widget. Must chain up

Properties

can_focus

can_focus: bool  # read/write

Whether the widget or any of its descendents can accept the input focus.

This property is meant to be set by widget implementations, typically in their instance init function.

can_target

can_target: bool  # read/write

Whether the widget can receive pointer events.

css_classes

css_classes: list[str]  # read/write

A list of css classes applied to this widget.

css_name

css_name: str  # read/write

The name of this widget in the CSS tree.

This property is meant to be set by widget implementations, typically in their instance init function.

cursor

cursor: Gdk.Cursor  # read/write

The cursor used by widget.

focus_on_click

focus_on_click: bool  # read/write

Whether the widget should grab focus when it is clicked with the mouse.

This property is only relevant for widgets that can take focus.

focusable

focusable: bool  # read/write

Whether this widget itself will accept the input focus.

halign

halign: Align | int  # read/write

How to distribute horizontal space if widget gets extra space.

has_default

has_default: bool  # read-only

Whether the widget is the default widget.

has_focus

has_focus: bool  # read-only

Whether the widget has the input focus.

has_tooltip

has_tooltip: bool  # read/write

Enables or disables the emission of the Widget.query-tooltip signal on widget.

A true value indicates that widget can have a tooltip, in this case the widget will be queried using Widget.query-tooltip to determine whether it will provide a tooltip or not.

height_request

height_request: int  # read/write

Overrides for height request of the widget.

If this is -1, the natural request will be used.

hexpand

hexpand: bool  # read/write

Whether to expand horizontally.

hexpand_set

hexpand_set: bool  # read/write

Whether to use the hexpand property.

layout_manager

layout_manager: LayoutManager  # read/write

The LayoutManager instance to use to compute the preferred size of the widget, and allocate its children.

This property is meant to be set by widget implementations, typically in their instance init function.

limit_events

limit_events: bool  # read/write

Makes this widget act like a modal dialog, with respect to event delivery.

Global event controllers will not handle events with targets inside the widget, unless they are set up to ignore propagation limits. See EventController.set_propagation_limit.

margin_bottom

margin_bottom: int  # read/write

Margin on bottom side of widget.

This property adds margin outside of the widget's normal size request, the margin will be added in addition to the size from Widget.set_size_request for example.

margin_end

margin_end: int  # read/write

Margin on end of widget, horizontally.

This property supports left-to-right and right-to-left text directions.

This property adds margin outside of the widget's normal size request, the margin will be added in addition to the size from Widget.set_size_request for example.

margin_start

margin_start: int  # read/write

Margin on start of widget, horizontally.

This property supports left-to-right and right-to-left text directions.

This property adds margin outside of the widget's normal size request, the margin will be added in addition to the size from Widget.set_size_request for example.

margin_top

margin_top: int  # read/write

Margin on top side of widget.

This property adds margin outside of the widget's normal size request, the margin will be added in addition to the size from Widget.set_size_request for example.

name

name: str  # read/write

The name of the widget.

opacity

opacity: float  # read/write

The requested opacity of the widget.

overflow

overflow: Overflow | int  # read/write

How content outside the widget's content area is treated.

This property is meant to be set by widget implementations, typically in their instance init function.

parent

parent: Widget  # read-only

The parent widget of this widget.

receives_default

receives_default: bool  # read/write

Whether the widget will receive the default action when it is focused.

root

root: Root  # read-only

The GtkRoot widget of the widget tree containing this widget.

This will be NULL if the widget is not contained in a root widget.

scale_factor

scale_factor: int  # read-only

The scale factor of the widget.

sensitive

sensitive: bool  # read/write

Whether the widget responds to input.

tooltip_markup

tooltip_markup: str  # read/write

Sets the text of tooltip to be the given string, which is marked up with Pango markup.

Also see Tooltip.set_markup.

This is a convenience property which will take care of getting the tooltip shown if the given string is not NULL: Widget.has-tooltip will automatically be set to true and there will be taken care of Widget.query-tooltip in the default signal handler.

Note that if both Widget.tooltip-text and Widget.tooltip-markup are set, the last one wins.

tooltip_text

tooltip_text: str  # read/write

Sets the text of tooltip to be the given string.

Also see Tooltip.set_text.

This is a convenience property which will take care of getting the tooltip shown if the given string is not NULL: Widget.has-tooltip will automatically be set to true and there will be taken care of Widget.query-tooltip in the default signal handler.

Note that if both Widget.tooltip-text and Widget.tooltip-markup are set, the last one wins.

valign

valign: Align | int  # read/write

How to distribute vertical space if widget gets extra space.

vexpand

vexpand: bool  # read/write

Whether to expand vertically.

vexpand_set

vexpand_set: bool  # read/write

Whether to use the vexpand property.

visible

visible: bool  # read/write

Whether the widget is visible.

width_request

width_request: int  # read/write

Overrides for width request of the widget.

If this is -1, the natural request will be used.

Signals

destroy

def on_destroy(self) -> None: ...

Signals that all holders of a reference to the widget should release the reference that they hold.

May result in finalization of the widget if all references are released.

This signal is not suitable for saving widget state.

direction-changed

def on_direction_changed(self, previous_direction: TextDirection) -> None: ...

Emitted when the text direction of a widget changes.

hide

def on_hide(self) -> None: ...

Emitted when widget is hidden.

keynav-failed

def on_keynav_failed(self, direction: DirectionType) -> bool: ...

Emitted if keyboard navigation fails.

See Widget.keynav_failed for details.

map

def on_map(self) -> None: ...

Emitted when widget is going to be mapped.

A widget is mapped when the widget is visible (which is controlled with Widget.visible) and all its parents up to the toplevel widget are also visible.

The ::map signal can be used to determine whether a widget will be drawn, for instance it can resume an animation that was stopped during the emission of Widget.unmap.

mnemonic-activate

def on_mnemonic_activate(self, group_cycling: bool) -> bool: ...

Emitted when a widget is activated via a mnemonic.

The default handler for this signal activates widget if group_cycling is false, or just makes widget grab focus if group_cycling is true.

move-focus

def on_move_focus(self, direction: DirectionType) -> None: ...

Emitted when the focus is moved.

The ::move-focus signal is a keybinding signal.

The default bindings for this signal are <kbd>Tab</kbd> to move forward, and <kbd>Shift</kbd>+<kbd>Tab</kbd> to move backward.

query-tooltip

def on_query_tooltip(self, x: int, y: int, keyboard_mode: bool, tooltip: Tooltip) -> bool: ...

Emitted when the widget’s tooltip is about to be shown.

This happens when the Widget.has-tooltip property is true and the hover timeout has expired with the cursor hovering above widget; or emitted when widget got focus in keyboard mode.

Using the given coordinates, the signal handler should determine whether a tooltip should be shown for widget. If this is the case true should be returned, false otherwise. Note that if keyboard_mode is true, the values of x and y are undefined and should not be used.

The signal handler is free to manipulate tooltip with the therefore destined function calls.

realize

def on_realize(self) -> None: ...

Emitted when widget is associated with a GdkSurface.

This means that Widget.realize has been called or the widget has been mapped (that is, it is going to be drawn).

show

def on_show(self) -> None: ...

Emitted when widget is shown.

state-flags-changed

def on_state_flags_changed(self, flags: StateFlags) -> None: ...

Emitted when the widget state changes.

See Widget.get_state_flags.

unmap

def on_unmap(self) -> None: ...

Emitted when widget is going to be unmapped.

A widget is unmapped when either it or any of its parents up to the toplevel widget have been set as hidden.

As ::unmap indicates that a widget will not be shown any longer, it can be used to, for example, stop an animation on the widget.

unrealize

def on_unrealize(self) -> None: ...

Emitted when the GdkSurface associated with widget is destroyed.

This means that Widget.unrealize has been called or the widget has been unmapped (that is, it is going to be hidden).