// This file was generated by gir (https://github.com/gtk-rs/gir)
// from gir-files (https://github.com/gtk-rs/gir-files.git)
// DO NOT EDIT

use crate::Accessible;
use crate::Align;
use crate::Allocation;
use crate::Buildable;
use crate::ConstraintTarget;
use crate::DirectionType;
use crate::EventController;
use crate::LayoutManager;
use crate::Native;
use crate::Orientation;
use crate::Overflow;
use crate::PickFlags;
use crate::Requisition;
use crate::Root;
use crate::Settings;
use crate::SizeRequestMode;
use crate::Snapshot;
use crate::StateFlags;
use crate::StyleContext;
use crate::TextDirection;
use crate::Tooltip;
use glib::object::Cast;
use glib::object::IsA;
use glib::object::ObjectExt;
use glib::signal::connect_raw;
use glib::signal::SignalHandlerId;
use glib::translate::*;
use glib::StaticType;
use glib::ToValue;
use std::boxed::Box as Box_;
use std::fmt;
use std::mem;
use std::mem::transmute;

glib::wrapper! {
    /// The base class for all widgets.
    ///
    /// [`Widget`][crate::Widget] is the base class all widgets in GTK derive from. 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:
    ///
    /// - `vfunc::Gtk::Widget::get_request_mode`
    /// - `vfunc::Gtk::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 [`Widget`][crate::Widget] subclass that supports
    /// height-for-width or width-for-height geometry management for itself
    /// or its child widgets, the `vfunc::Gtk::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::ConstantSize`][crate::SizeRequestMode::ConstantSize], which means that the widget will
    /// only ever get -1 passed as the for_size value to its
    /// `vfunc::Gtk::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`][crate::SizeRequestMode] chosen by the toplevel.
    ///
    /// For example, when queried in the normal [`SizeRequestMode::HeightForWidth`][crate::SizeRequestMode::HeightForWidth] mode:
    ///
    /// First, the default minimum and natural width for each widget
    /// in the interface will be computed using [`prelude::WidgetExt::measure`][crate::prelude::WidgetExt::measure] with an
    /// orientation of [`Orientation::Horizontal`][crate::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 [`prelude::WidgetExt::measure`][crate::prelude::WidgetExt::measure] with an
    /// orientation of [`Orientation::Vertical`][crate::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 [``GtkWindowExt::set_default_size()``][crate::prelude::`GtkWindowExt::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`][crate::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, [`Widget`][crate::Widget] 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
    /// [`SizeRequestMode`][crate::SizeRequestMode]s even if the widget in question only
    /// trades sizes in a single orientation.
    ///
    /// For instance, a [`Label`][crate::Label] that does height-for-width word wrapping
    /// will not expect to have `vfunc::Gtk::Widget::measure` with an orientation of
    /// [`Orientation::Vertical`][crate::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::HeightForWidth`][crate::SizeRequestMode::HeightForWidth] widget
    /// generally deals with width-for-height requests:
    ///
    /// **⚠️ The following code is in c ⚠️**
    ///
    /// ```c
    /// 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 [``WidgetExt::measure()``][crate::prelude::`WidgetExt::measure()`]
    /// inside your own `vfunc::Gtk::Widget::size_allocate` implementation.
    /// These return a request adjusted by [`SizeGroup`][crate::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 [`prelude::WidgetExt::measure`][crate::prelude::WidgetExt::measure]; otherwise, you
    /// would not properly consider widget margins, [`SizeGroup`][crate::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 of [`Align::Baseline`][crate::Align::Baseline], 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
    /// `vfunc::Gtk::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`][crate::Align::Fill], but the selected baseline can be
    /// found via [`prelude::WidgetExt::get_allocated_baseline`][crate::prelude::WidgetExt::get_allocated_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 [`Widget`][crate::Widget] implementation of the [`Buildable`][crate::Buildable] interface
    /// supports various custom elements to specify additional aspects of widgets
    /// that are not directly expressed as properties.
    ///
    /// If the widget uses a [`LayoutManager`][crate::LayoutManager], [`Widget`][crate::Widget] supports
    /// a custom ``<layout>`` element, used to define layout properties:
    ///
    /// ```xml
    /// <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>
    /// ```
    ///
    /// [`Widget`][crate::Widget] allows style information such as style classes to
    /// be associated with widgets, using the custom ``<style>`` element:
    ///
    /// ```xml
    /// <object class="GtkButton" id="button1">
    ///   <style>
    ///     <class name="my-special-button-class"/>
    ///     <class name="dark-button"/>
    ///   </style>
    /// </object>
    /// ```
    ///
    /// [`Widget`][crate::Widget] allows defining accessibility information, such as properties,
    /// relations, and states, using the custom ``<accessibility>`` element:
    ///
    /// ```xml
    /// <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
    ///
    /// `GtkWidget `exposes some facilities to automate the procedure
    /// of creating composite widgets using "templates".
    ///
    /// To create composite widgets with [`Builder`][crate::Builder] XML, one must associate
    /// the interface description with the widget class at class initialization
    /// time using `Gtk::`WidgetClass::set_template()``.
    ///
    /// The interface description semantics expected in composite template descriptions
    /// is slightly different from regular [`Builder`][crate::Builder] XML.
    ///
    /// Unlike regular interface descriptions, `Gtk::`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 [`Builder`][crate::Builder] but required for UI design tools like
    /// [Glade](https://glade.gnome.org/) 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.
    ///
    /// An example of a template definition:
    ///
    /// ```xml
    /// <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 `Gtk::`WidgetClass::set_template_from_resource()``
    /// from the class initialization of your [`Widget`][crate::Widget] type:
    ///
    /// **⚠️ The following code is in c ⚠️**
    ///
    /// ```c
    /// 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 [``WidgetExt::init_template()``][crate::prelude::`WidgetExt::init_template()`] from the
    /// instance initialization function:
    ///
    /// **⚠️ The following code is in c ⚠️**
    ///
    /// ```c
    /// static void
    /// foo_widget_init (FooWidget *self)
    /// {
    ///   // ...
    ///   gtk_widget_init_template (GTK_WIDGET (self));
    /// }
    /// ```
    ///
    /// You can access widgets defined in the template using the
    /// [`prelude::WidgetExt::get_template_child`][crate::prelude::WidgetExt::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
    /// `Gtk::`WidgetClass::bind_template_child_full()`` (or one of its wrapper macros
    /// ``widget_class_bind_template_child()`` and ``widget_class_bind_template_child_private()``)
    /// with that name, e.g.
    ///
    /// **⚠️ The following code is in c ⚠️**
    ///
    /// ```c
    /// typedef struct {
    ///   GtkWidget *hello_button;
    ///   GtkWidget *goodbye_button;
    /// } FooWidgetPrivate;
    ///
    /// G_DEFINE_TYPE_WITH_PRIVATE (FooWidget, foo_widget, GTK_TYPE_BOX)
    ///
    /// 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_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)
    /// {
    ///
    /// }
    /// ```
    ///
    /// You can also use `Gtk::`WidgetClass::bind_template_callback_full()`` (or
    /// is wrapper macro ``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 following code is in c ⚠️**
    ///
    /// ```c
    /// // 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);
    /// }
    /// ```
    ///
    /// This is an Abstract Base Class, you cannot instantiate it.
    ///
    /// # Implements
    ///
    /// [`WidgetExt`][trait@crate::prelude::WidgetExt], [`trait@glib::ObjectExt`], [`AccessibleExt`][trait@crate::prelude::AccessibleExt], [`BuildableExt`][trait@crate::prelude::BuildableExt], [`ConstraintTargetExt`][trait@crate::prelude::ConstraintTargetExt], [`WidgetExtManual`][trait@crate::prelude::WidgetExtManual], [`AccessibleExtManual`][trait@crate::prelude::AccessibleExtManual]
    #[doc(alias = "GtkWidget")]
    pub struct Widget(Object<ffi::GtkWidget, ffi::GtkWidgetClass>) @implements Accessible, Buildable, ConstraintTarget;

    match fn {
        type_ => || ffi::gtk_widget_get_type(),
    }
}

impl Widget {
    /// Obtains the current default reading direction.
    ///
    /// See [``set_default_direction()``][`Self::set_default_direction()`].
    ///
    /// # Returns
    ///
    /// the current default direction.
    #[doc(alias = "gtk_widget_get_default_direction")]
    #[doc(alias = "get_default_direction")]
    pub fn default_direction() -> TextDirection {
        assert_initialized_main_thread!();
        unsafe { from_glib(ffi::gtk_widget_get_default_direction()) }
    }

    /// Sets the default reading direction for widgets.
    ///
    /// See [``WidgetExt::set_direction()``][crate::prelude::`WidgetExt::set_direction()`].
    /// ## `dir`
    /// the new default direction. This cannot be [`TextDirection::None`][crate::TextDirection::None].
    #[doc(alias = "gtk_widget_set_default_direction")]
    pub fn set_default_direction(dir: TextDirection) {
        assert_initialized_main_thread!();
        unsafe {
            ffi::gtk_widget_set_default_direction(dir.into_glib());
        }
    }
}

impl fmt::Display for Widget {
    #[inline]
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        f.write_str(&WidgetExt::widget_name(self))
    }
}

pub const NONE_WIDGET: Option<&Widget> = None;

/// Trait containing all [`struct@Widget`] methods.
///
/// # Implementors
///
/// [`ActionBar`][struct@crate::ActionBar], [`Actionable`][struct@crate::Actionable], [`AppChooserButton`][struct@crate::AppChooserButton], [`AppChooserWidget`][struct@crate::AppChooserWidget], [`AppChooser`][struct@crate::AppChooser], [`AspectFrame`][struct@crate::AspectFrame], [`Box`][struct@crate::Box], [`Button`][struct@crate::Button], [`Calendar`][struct@crate::Calendar], [`CellEditable`][struct@crate::CellEditable], [`CellView`][struct@crate::CellView], [`CenterBox`][struct@crate::CenterBox], [`CheckButton`][struct@crate::CheckButton], [`ColorButton`][struct@crate::ColorButton], [`ColorChooserWidget`][struct@crate::ColorChooserWidget], [`ColumnView`][struct@crate::ColumnView], [`ComboBox`][struct@crate::ComboBox], [`DragIcon`][struct@crate::DragIcon], [`DrawingArea`][struct@crate::DrawingArea], [`DropDown`][struct@crate::DropDown], [`EditableLabel`][struct@crate::EditableLabel], [`Editable`][struct@crate::Editable], [`Entry`][struct@crate::Entry], [`Expander`][struct@crate::Expander], [`FileChooserWidget`][struct@crate::FileChooserWidget], [`Fixed`][struct@crate::Fixed], [`FlowBoxChild`][struct@crate::FlowBoxChild], [`FlowBox`][struct@crate::FlowBox], [`FontButton`][struct@crate::FontButton], [`FontChooserWidget`][struct@crate::FontChooserWidget], [`Frame`][struct@crate::Frame], [`GLArea`][struct@crate::GLArea], [`Grid`][struct@crate::Grid], [`HeaderBar`][struct@crate::HeaderBar], [`IconView`][struct@crate::IconView], [`Image`][struct@crate::Image], [`InfoBar`][struct@crate::InfoBar], [`Label`][struct@crate::Label], [`LevelBar`][struct@crate::LevelBar], [`ListBase`][struct@crate::ListBase], [`ListBoxRow`][struct@crate::ListBoxRow], [`ListBox`][struct@crate::ListBox], [`MediaControls`][struct@crate::MediaControls], [`MenuButton`][struct@crate::MenuButton], [`Native`][struct@crate::Native], [`Notebook`][struct@crate::Notebook], [`Overlay`][struct@crate::Overlay], [`Paned`][struct@crate::Paned], [`PasswordEntry`][struct@crate::PasswordEntry], [`Picture`][struct@crate::Picture], [`PopoverMenuBar`][struct@crate::PopoverMenuBar], [`Popover`][struct@crate::Popover], [`ProgressBar`][struct@crate::ProgressBar], [`Range`][struct@crate::Range], [`Revealer`][struct@crate::Revealer], [`Root`][struct@crate::Root], [`ScaleButton`][struct@crate::ScaleButton], [`Scrollbar`][struct@crate::Scrollbar], [`ScrolledWindow`][struct@crate::ScrolledWindow], [`SearchBar`][struct@crate::SearchBar], [`SearchEntry`][struct@crate::SearchEntry], [`Separator`][struct@crate::Separator], [`ShortcutLabel`][struct@crate::ShortcutLabel], [`ShortcutsShortcut`][struct@crate::ShortcutsShortcut], [`SpinButton`][struct@crate::SpinButton], [`Spinner`][struct@crate::Spinner], [`StackSidebar`][struct@crate::StackSidebar], [`StackSwitcher`][struct@crate::StackSwitcher], [`Stack`][struct@crate::Stack], [`Statusbar`][struct@crate::Statusbar], [`Switch`][struct@crate::Switch], [`TextView`][struct@crate::TextView], [`Text`][struct@crate::Text], [`TreeExpander`][struct@crate::TreeExpander], [`TreeView`][struct@crate::TreeView], [`Video`][struct@crate::Video], [`Viewport`][struct@crate::Viewport], [`Widget`][struct@crate::Widget], [`WindowControls`][struct@crate::WindowControls], [`WindowHandle`][struct@crate::WindowHandle], [`Window`][struct@crate::Window]
pub trait WidgetExt: 'static {
    /// Enable or disable an action installed with
    /// `gtk_widget_class_install_action()`.
    /// ## `action_name`
    /// action name, such as "clipboard.paste"
    /// ## `enabled`
    /// whether the action is now enabled
    #[doc(alias = "gtk_widget_action_set_enabled")]
    fn action_set_enabled(&self, action_name: &str, enabled: bool);

    /// For widgets that can be “activated” (buttons, menu items, etc.),
    /// this function activates them.
    ///
    /// The activation will emit the signal set using
    /// `Gtk::`WidgetClass::set_activate_signal()`` during class initialization.
    ///
    /// Activation is what happens when you press `<kbd>`Enter`</kbd>`
    /// on a widget during key navigation.
    ///
    /// If you wish to handle the activation keybinding yourself, it is
    /// recommended to use `Gtk::`WidgetClass::add_shortcut()`` with an action
    /// created with [``SignalAction::new()``][crate::`SignalAction::new()`].
    ///
    /// If `self` isn't activatable, the function returns [`false`].
    ///
    /// # Returns
    ///
    /// [`true`] if the widget was activatable
    #[doc(alias = "gtk_widget_activate")]
    fn activate(&self) -> bool;

    /// Looks up the action in the action groups associated
    /// with `self` and its ancestors, and activates it.
    ///
    /// This is a wrapper around [``activate_action()``][`Self::activate_action()`]
    /// that constructs the `args` variant according to `format_string`.
    /// ## `name`
    /// the name of the action to activate
    /// ## `format_string`
    /// GVariant format string for arguments or [`None`]
    ///  for no arguments
    ///
    /// # Returns
    ///
    /// [`true`] if the action was activated, [`false`] if the action
    ///  does not exist
    #[doc(alias = "gtk_widget_activate_action_variant")]
    #[doc(alias = "activate_action_variant")]
    fn activate_action(&self, name: &str, args: Option<&glib::Variant>) -> bool;

    /// Activates the `default.activate` action from `self`.
    #[doc(alias = "gtk_widget_activate_default")]
    fn activate_default(&self);

    /// Adds `controller` to `self` so that it will receive events.
    ///
    /// You will usually want to call this function right after
    /// creating any kind of [`EventController`][crate::EventController].
    /// ## `controller`
    /// a [`EventController`][crate::EventController] that hasn't been
    ///  added to a widget yet
    #[doc(alias = "gtk_widget_add_controller")]
    fn add_controller<P: IsA<EventController>>(&self, controller: &P);

    /// Adds a style class to `self`.
    ///
    /// After calling this function, the widgets style will match
    /// for `css_class`, according to CSS matching rules.
    ///
    /// Use [``remove_css_class()``][`Self::remove_css_class()`] to remove the
    /// style again.
    /// ## `css_class`
    /// The style class to add to `self`, without
    ///  the leading '.' used for notation of style classes
    #[doc(alias = "gtk_widget_add_css_class")]
    fn add_css_class(&self, css_class: &str);

    /// Adds a widget to the list of mnemonic labels for this widget.
    ///
    /// See [``list_mnemonic_labels()``][`Self::list_mnemonic_labels()`]. Note 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.
    /// ## `label`
    /// a [`Widget`][crate::Widget] that acts as a mnemonic label for `self`
    #[doc(alias = "gtk_widget_add_mnemonic_label")]
    fn add_mnemonic_label<P: IsA<Widget>>(&self, label: &P);

    /// This function is only used by [`Widget`][crate::Widget] subclasses, to
    /// assign a size, position and (optionally) baseline to their
    /// child widgets.
    ///
    /// 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.
    ///
    /// For a version that does not take a transform, see
    /// [``size_allocate()``][`Self::size_allocate()`].
    /// ## `width`
    /// New width of `self`
    /// ## `height`
    /// New height of `self`
    /// ## `baseline`
    /// New baseline of `self`, or -1
    /// ## `transform`
    /// Transformation to be applied to `self`
    #[doc(alias = "gtk_widget_allocate")]
    fn allocate(&self, width: i32, height: i32, baseline: i32, transform: Option<&gsk::Transform>);

    /// 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 `vfunc::Gtk::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 normallycall [``grab_focus()``][`Self::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 [``grab_focus()``][`Self::grab_focus()`] to move
    /// the focus to a particular widget.
    /// ## `direction`
    /// direction of focus movement
    ///
    /// # Returns
    ///
    /// [`true`] if focus ended up inside `self`
    #[doc(alias = "gtk_widget_child_focus")]
    fn child_focus(&self, direction: DirectionType) -> bool;

    /// Computes the bounds for `self` in the coordinate space of `target`.
    ///
    /// FIXME: Explain what "bounds" are.
    ///
    /// If the operation is successful, [`true`] is returned. If `self` 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 `self` and `target` to be the same widget.
    /// ## `target`
    /// the [`Widget`][crate::Widget]
    ///
    /// # Returns
    ///
    /// [`true`] if the bounds could be computed
    ///
    /// ## `out_bounds`
    /// the rectangle taking the bounds
    #[doc(alias = "gtk_widget_compute_bounds")]
    fn compute_bounds<P: IsA<Widget>>(&self, target: &P) -> Option<graphene::Rect>;

    /// Computes whether a container should give this widget
    /// extra space when possible.
    ///
    /// Containers should check this, rather than looking at
    /// [``hexpands()``][`Self::hexpands()`] or [``vexpands()``][`Self::vexpands()`].
    ///
    /// 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.
    /// ## `orientation`
    /// expand direction
    ///
    /// # Returns
    ///
    /// whether widget tree rooted here should be expanded
    #[doc(alias = "gtk_widget_compute_expand")]
    fn compute_expand(&self, orientation: Orientation) -> bool;

    /// Translates the given `point` in `self`'s coordinates to coordinates
    /// relative to `target`’s coordinate system.
    ///
    /// In order to perform this operation, both widgets must share a
    /// common ancestor.
    /// ## `target`
    /// the [`Widget`][crate::Widget] to transform into
    /// ## `point`
    /// a point in `self`'s coordinate system
    ///
    /// # Returns
    ///
    /// [`true`] if the point could be determined, [`false`] on failure.
    ///  In this case, 0 is stored in `out_point`.
    ///
    /// ## `out_point`
    /// Set to the corresponding coordinates in
    ///  `target`'s coordinate system
    #[doc(alias = "gtk_widget_compute_point")]
    fn compute_point<P: IsA<Widget>>(
        &self,
        target: &P,
        point: &graphene::Point,
    ) -> Option<graphene::Point>;

    /// Computes a matrix suitable to describe a transformation from
    /// `self`'s coordinate system into `target`'s coordinate system.
    ///
    /// The transform can not be computed in certain cases, for example
    /// when `self` and `target` do not share a common ancestor. In that
    /// case `out_transform` gets set to the identity matrix.
    /// ## `target`
    /// the target widget that the matrix will transform to
    ///
    /// # Returns
    ///
    /// [`true`] if the transform could be computed, [`false`] otherwise
    ///
    /// ## `out_transform`
    /// location to
    ///  store the final transformation
    #[doc(alias = "gtk_widget_compute_transform")]
    fn compute_transform<P: IsA<Widget>>(&self, target: &P) -> Option<graphene::Matrix>;

    /// Tests if the point at (`x`, `y`) is contained in `self`.
    ///
    /// The coordinates for (`x`, `y`) must be in widget coordinates, so
    /// (0, 0) is assumed to be the top left of `self`'s content area.
    /// ## `x`
    /// X coordinate to test, relative to `self`'s origin
    /// ## `y`
    /// Y coordinate to test, relative to `self`'s origin
    ///
    /// # Returns
    ///
    /// [`true`] if `self` contains (`x`, `y`).
    #[doc(alias = "gtk_widget_contains")]
    fn contains(&self, x: f64, y: f64) -> bool;

    /// Creates a new [`pango::Context`][crate::pango::Context] with the appropriate font map,
    /// font options, font description, and base direction for drawing
    /// text for this widget.
    ///
    /// See also [``pango_context()``][`Self::pango_context()`].
    ///
    /// # Returns
    ///
    /// the new [`pango::Context`][crate::pango::Context]
    #[doc(alias = "gtk_widget_create_pango_context")]
    fn create_pango_context(&self) -> pango::Context;

    /// Creates a new [`pango::Layout`][crate::pango::Layout] with the appropriate font map,
    /// font description, and base direction for drawing text for
    /// this widget.
    ///
    /// If you keep a [`pango::Layout`][crate::pango::Layout] created in this way around,
    /// you need to re-create it when the widget [`pango::Context`][crate::pango::Context]
    /// is replaced. This can be tracked by listening to changes
    /// of the `property::Widget::root` property on the widget.
    /// ## `text`
    /// text to set on the layout
    ///
    /// # Returns
    ///
    /// the new [`pango::Layout`][crate::pango::Layout]
    #[doc(alias = "gtk_widget_create_pango_layout")]
    fn create_pango_layout(&self, text: Option<&str>) -> pango::Layout;

    /// Checks to see if a drag movement has passed the GTK drag threshold.
    /// ## `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
    ///
    /// # Returns
    ///
    /// [`true`] if the drag threshold has been passed.
    #[doc(alias = "gtk_drag_check_threshold")]
    fn drag_check_threshold(
        &self,
        start_x: i32,
        start_y: i32,
        current_x: i32,
        current_y: i32,
    ) -> bool;

    /// Notifies the user about an input-related error on this widget.
    ///
    /// If the `property::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.
    #[doc(alias = "gtk_widget_error_bell")]
    fn error_bell(&self);

    /// Returns the baseline that has currently been allocated to `self`.
    ///
    /// This function is intended to be used when implementing handlers
    /// for the [`Widget`][crate::Widget]`Class.snapshot()` function, and when allocating
    /// child widgets in [`Widget`][crate::Widget]`Class.size_allocate()`.
    ///
    /// # Returns
    ///
    /// the baseline of the `self`, or -1 if none
    #[doc(alias = "gtk_widget_get_allocated_baseline")]
    #[doc(alias = "get_allocated_baseline")]
    fn allocated_baseline(&self) -> i32;

    /// Returns the height that has currently been allocated to `self`.
    ///
    /// # Returns
    ///
    /// the height of the `self`
    #[doc(alias = "gtk_widget_get_allocated_height")]
    #[doc(alias = "get_allocated_height")]
    fn allocated_height(&self) -> i32;

    /// Returns the width that has currently been allocated to `self`.
    ///
    /// # Returns
    ///
    /// the width of the `self`
    #[doc(alias = "gtk_widget_get_allocated_width")]
    #[doc(alias = "get_allocated_width")]
    fn allocated_width(&self) -> i32;

    /// Retrieves the widget’s allocation.
    ///
    /// Note, when implementing a layout container: a widget’s allocation
    /// will be its “adjusted” allocation, that is, the widget’s parent
    /// typically calls [``size_allocate()``][`Self::size_allocate()`] with an allocation,
    /// and that allocation is then adjusted (to handle margin
    /// and alignment for example) before assignment to the widget.
    /// [``allocation()``][`Self::allocation()`] returns the adjusted allocation that
    /// was actually assigned to the widget. The adjusted allocation is
    /// guaranteed to be completely contained within the
    /// [``size_allocate()``][`Self::size_allocate()`] allocation, however.
    ///
    /// So a layout container is guaranteed that its children stay inside
    /// the assigned bounds, but not that they have exactly the bounds the
    /// container assigned.
    ///
    /// # Returns
    ///
    ///
    /// ## `allocation`
    /// a pointer to a `GtkAllocation` to copy to
    #[doc(alias = "gtk_widget_get_allocation")]
    #[doc(alias = "get_allocation")]
    fn allocation(&self) -> Allocation;

    /// Gets the first ancestor of `self` with type `widget_type`.
    ///
    /// For example, `gtk_widget_get_ancestor (widget, GTK_TYPE_BOX)`
    /// gets the first [`Box`][crate::Box] that’s an ancestor of `self`. No
    /// reference will be added to the returned widget; it should
    /// not be unreferenced.
    ///
    /// Note that unlike [``is_ancestor()``][`Self::is_ancestor()`], this function
    /// considers `self` to be an ancestor of itself.
    /// ## `widget_type`
    /// ancestor type
    ///
    /// # Returns
    ///
    /// the ancestor widget
    #[doc(alias = "gtk_widget_get_ancestor")]
    #[doc(alias = "get_ancestor")]
    fn ancestor(&self, widget_type: glib::types::Type) -> Option<Widget>;

    /// Determines whether the input focus can enter `self` or any
    /// of its children.
    ///
    /// See [``set_focusable()``][`Self::set_focusable()`].
    ///
    /// # Returns
    ///
    /// [`true`] if the input focus can enter `self`, [`false`] otherwise
    #[doc(alias = "gtk_widget_get_can_focus")]
    #[doc(alias = "get_can_focus")]
    fn can_focus(&self) -> bool;

    /// Queries whether `self` can be the target of pointer events.
    ///
    /// # Returns
    ///
    /// [`true`] if `self` can receive pointer events
    #[doc(alias = "gtk_widget_get_can_target")]
    #[doc(alias = "get_can_target")]
    fn can_target(&self) -> bool;

    /// Gets the value set with [`set_child_visible()`][Self::set_child_visible()].
    ///
    /// If you feel a need to use this function, your code probably
    /// needs reorganization.
    ///
    /// This function is only useful for container implementations
    /// and should never be called by an application.
    ///
    /// # Returns
    ///
    /// [`true`] if the widget is mapped with the parent.
    #[doc(alias = "gtk_widget_get_child_visible")]
    #[doc(alias = "get_child_visible")]
    fn is_child_visible(&self) -> bool;

    /// Gets the clipboard object for `self`.
    ///
    /// This is a utility function to get the clipboard object for the
    /// [`gdk::Display`][crate::gdk::Display] that `self` is using.
    ///
    /// Note that this function always works, even when `self` is not
    /// realized yet.
    ///
    /// # Returns
    ///
    /// the appropriate clipboard object
    #[doc(alias = "gtk_widget_get_clipboard")]
    #[doc(alias = "get_clipboard")]
    fn clipboard(&self) -> gdk::Clipboard;

    /// Returns the list of style classes applied to `self`.
    ///
    /// # Returns
    ///
    /// a [`None`]-terminated list of
    ///  css classes currently applied to `self`. The returned
    ///  list must freed using `g_strfreev()`.
    #[doc(alias = "gtk_widget_get_css_classes")]
    #[doc(alias = "get_css_classes")]
    fn css_classes(&self) -> Vec<glib::GString>;

    /// Returns the CSS name that is used for `self`.
    ///
    /// # Returns
    ///
    /// the CSS name
    #[doc(alias = "gtk_widget_get_css_name")]
    #[doc(alias = "get_css_name")]
    fn css_name(&self) -> glib::GString;

    /// Queries the cursor set on `self`.
    ///
    /// See [``set_cursor()``][`Self::set_cursor()`] for details.
    ///
    /// # Returns
    ///
    /// the cursor
    ///  currently in use or [`None`] if the cursor is inherited
    #[doc(alias = "gtk_widget_get_cursor")]
    #[doc(alias = "get_cursor")]
    fn cursor(&self) -> Option<gdk::Cursor>;

    /// Gets the reading direction for a particular widget.
    ///
    /// See [``set_direction()``][`Self::set_direction()`].
    ///
    /// # Returns
    ///
    /// the reading direction for the widget.
    #[doc(alias = "gtk_widget_get_direction")]
    #[doc(alias = "get_direction")]
    fn direction(&self) -> TextDirection;

    /// Get the [`gdk::Display`][crate::gdk::Display] for the toplevel window associated with
    /// this widget.
    ///
    /// This function can only be called after the widget has been
    /// added to a widget hierarchy with a [`Window`][crate::Window] 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.
    ///
    /// # Returns
    ///
    /// the [`gdk::Display`][crate::gdk::Display] for the toplevel
    ///  for this widget.
    #[doc(alias = "gtk_widget_get_display")]
    #[doc(alias = "get_display")]
    fn display(&self) -> gdk::Display;

    /// Returns the widgets first child.
    ///
    /// This API is primarily meant for widget implementations.
    ///
    /// # Returns
    ///
    /// The widget's first child
    #[doc(alias = "gtk_widget_get_first_child")]
    #[doc(alias = "get_first_child")]
    fn first_child(&self) -> Option<Widget>;

    /// Returns the current focus child of `self`.
    ///
    /// # Returns
    ///
    /// The current focus
    ///  child of `self`
    #[doc(alias = "gtk_widget_get_focus_child")]
    #[doc(alias = "get_focus_child")]
    fn focus_child(&self) -> Option<Widget>;

    /// Returns whether the widget should grab focus when it is clicked
    /// with the mouse.
    ///
    /// See [``set_focus_on_click()``][`Self::set_focus_on_click()`].
    ///
    /// # Returns
    ///
    /// [`true`] if the widget should grab focus when it is
    ///  clicked with the mouse
    #[doc(alias = "gtk_widget_get_focus_on_click")]
    #[doc(alias = "get_focus_on_click")]
    fn gets_focus_on_click(&self) -> bool;

    /// Determines whether `self` can own the input focus.
    ///
    /// See [``set_focusable()``][`Self::set_focusable()`].
    ///
    /// # Returns
    ///
    /// [`true`] if `self` can own the input focus, [`false`] otherwise
    #[doc(alias = "gtk_widget_get_focusable")]
    #[doc(alias = "get_focusable")]
    fn is_focusable(&self) -> bool;

    /// Gets the font map of `self`.
    ///
    /// See [``set_font_map()``][`Self::set_font_map()`].
    ///
    /// # Returns
    ///
    /// A [`pango::FontMap`][crate::pango::FontMap]
    #[doc(alias = "gtk_widget_get_font_map")]
    #[doc(alias = "get_font_map")]
    fn font_map(&self) -> Option<pango::FontMap>;

    /// Returns the `cairo_font_options_t` of widget.
    ///
    /// Seee [``set_font_options()``][`Self::set_font_options()`].
    ///
    /// # Returns
    ///
    /// the `cairo_font_options_t`
    ///  of widget
    #[doc(alias = "gtk_widget_get_font_options")]
    #[doc(alias = "get_font_options")]
    fn font_options(&self) -> Option<cairo::FontOptions>;

    /// 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 [``FrameClock::frame_time()``][crate::gdk::`FrameClock::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
    /// [``FrameClock::frame_time()``][crate::gdk::`FrameClock::frame_time()`], and then update the animation
    /// by calling [``FrameClock::frame_time()``][crate::gdk::`FrameClock::frame_time()`] again during each repaint.
    ///
    /// [``FrameClock::request_phase()``][crate::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 [``queue_draw()``][`Self::queue_draw()`] which invalidates
    /// the widget (thus scheduling it to receive a draw on the next
    /// frame). [`queue_draw()`][Self::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.
    ///
    /// # Returns
    ///
    /// a [`gdk::FrameClock`][crate::gdk::FrameClock]
    #[doc(alias = "gtk_widget_get_frame_clock")]
    #[doc(alias = "get_frame_clock")]
    fn frame_clock(&self) -> Option<gdk::FrameClock>;

    /// Gets the horizontal alignment of `self`.
    ///
    /// For backwards compatibility reasons this method will never return
    /// [`Align::Baseline`][crate::Align::Baseline], but instead it will convert it to
    /// [`Align::Fill`][crate::Align::Fill]. Baselines are not supported for horizontal
    /// alignment.
    ///
    /// # Returns
    ///
    /// the horizontal alignment of `self`
    #[doc(alias = "gtk_widget_get_halign")]
    #[doc(alias = "get_halign")]
    fn halign(&self) -> Align;

    /// Returns the current value of the `has-tooltip` property.
    ///
    /// # Returns
    ///
    /// current value of `has-tooltip` on `self`.
    #[doc(alias = "gtk_widget_get_has_tooltip")]
    #[doc(alias = "get_has_tooltip")]
    fn has_tooltip(&self) -> bool;

    /// 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 `vfunc::Gtk::Widget::snapshot`.
    ///
    /// For pointer events, see [``contains()``][`Self::contains()`].
    ///
    /// # Returns
    ///
    /// The height of `self`
    #[doc(alias = "gtk_widget_get_height")]
    #[doc(alias = "get_height")]
    fn height(&self) -> i32;

    /// Gets whether the widget would like any available extra horizontal
    /// space.
    ///
    /// When a user resizes a [`Window`][crate::Window], widgets with expand=TRUE
    /// generally receive the extra space. For example, a list or
    /// scrollable area or document in your window would often be set to
    /// expand.
    ///
    /// Containers should use [``compute_expand()``][`Self::compute_expand()`] rather
    /// than this function, to see whether a widget, or 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.
    ///
    /// # Returns
    ///
    /// whether hexpand flag is set
    #[doc(alias = "gtk_widget_get_hexpand")]
    #[doc(alias = "get_hexpand")]
    fn hexpands(&self) -> bool;

    /// Gets whether [`set_hexpand()`][Self::set_hexpand()] has been used
    /// to explicitly set the expand flag on this widget.
    ///
    /// If `property::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.
    ///
    /// # Returns
    ///
    /// whether hexpand has been explicitly set
    #[doc(alias = "gtk_widget_get_hexpand_set")]
    #[doc(alias = "get_hexpand_set")]
    fn is_hexpand_set(&self) -> bool;

    /// Returns the widgets last child.
    ///
    /// This API is primarily meant for widget implementations.
    ///
    /// # Returns
    ///
    /// The widget's last child
    #[doc(alias = "gtk_widget_get_last_child")]
    #[doc(alias = "get_last_child")]
    fn last_child(&self) -> Option<Widget>;

    /// Retrieves the layout manager used by `self`.
    ///
    /// See [``set_layout_manager()``][`Self::set_layout_manager()`].
    ///
    /// # Returns
    ///
    /// a [`LayoutManager`][crate::LayoutManager]
    #[doc(alias = "gtk_widget_get_layout_manager")]
    #[doc(alias = "get_layout_manager")]
    fn layout_manager(&self) -> Option<LayoutManager>;

    /// Whether the widget is mapped.
    ///
    /// # Returns
    ///
    /// [`true`] if the widget is mapped, [`false`] otherwise.
    #[doc(alias = "gtk_widget_get_mapped")]
    #[doc(alias = "get_mapped")]
    fn is_mapped(&self) -> bool;

    /// Gets the bottom margin of `self`.
    ///
    /// # Returns
    ///
    /// The bottom margin of `self`
    #[doc(alias = "gtk_widget_get_margin_bottom")]
    #[doc(alias = "get_margin_bottom")]
    fn margin_bottom(&self) -> i32;

    /// Gets the end margin of `self`.
    ///
    /// # Returns
    ///
    /// The end margin of `self`
    #[doc(alias = "gtk_widget_get_margin_end")]
    #[doc(alias = "get_margin_end")]
    fn margin_end(&self) -> i32;

    /// Gets the start margin of `self`.
    ///
    /// # Returns
    ///
    /// The start margin of `self`
    #[doc(alias = "gtk_widget_get_margin_start")]
    #[doc(alias = "get_margin_start")]
    fn margin_start(&self) -> i32;

    /// Gets the top margin of `self`.
    ///
    /// # Returns
    ///
    /// The top margin of `self`
    #[doc(alias = "gtk_widget_get_margin_top")]
    #[doc(alias = "get_margin_top")]
    fn margin_top(&self) -> i32;

    /// Retrieves the name of a widget.
    ///
    /// See [``set_widget_name()``][`Self::set_widget_name()`] for the significance of widget names.
    ///
    /// # Returns
    ///
    /// name of the widget. This string is owned by GTK and
    ///  should not be modified or freed
    #[doc(alias = "gtk_widget_get_name")]
    #[doc(alias = "get_name")]
    fn widget_name(&self) -> glib::GString;

    /// Returns the nearest [`Native`][crate::Native] ancestor of `self`.
    ///
    /// This function will return [`None`] if the widget is not
    /// contained inside a widget tree with a native ancestor.
    ///
    /// [`Native`][crate::Native] widgets will return themselves here.
    ///
    /// # Returns
    ///
    /// the [`Native`][crate::Native] ancestor of `self`
    #[doc(alias = "gtk_widget_get_native")]
    #[doc(alias = "get_native")]
    fn native(&self) -> Option<Native>;

    /// Returns the widgets next sibling.
    ///
    /// This API is primarily meant for widget implementations.
    ///
    /// # Returns
    ///
    /// The widget's next sibling
    #[doc(alias = "gtk_widget_get_next_sibling")]
    #[doc(alias = "get_next_sibling")]
    fn next_sibling(&self) -> Option<Widget>;

    /// `Fetches` the requested opacity for this widget.
    ///
    /// See [``set_opacity()``][`Self::set_opacity()`].
    ///
    /// # Returns
    ///
    /// the requested opacity for this widget.
    #[doc(alias = "gtk_widget_get_opacity")]
    #[doc(alias = "get_opacity")]
    fn opacity(&self) -> f64;

    /// Returns the widgets overflow value.
    ///
    /// # Returns
    ///
    /// The widget's overflow.
    #[doc(alias = "gtk_widget_get_overflow")]
    #[doc(alias = "get_overflow")]
    fn overflow(&self) -> Overflow;

    /// Gets a [`pango::Context`][crate::pango::Context] with the appropriate font map, font description,
    /// and base direction for this widget.
    ///
    /// Unlike the context returned by [``create_pango_context()``][`Self::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
    /// `property::Widget::root` property on the widget.
    ///
    /// # Returns
    ///
    /// the [`pango::Context`][crate::pango::Context] for the widget.
    #[doc(alias = "gtk_widget_get_pango_context")]
    #[doc(alias = "get_pango_context")]
    fn pango_context(&self) -> pango::Context;

    /// Returns the parent widget of `self`.
    ///
    /// # Returns
    ///
    /// the parent widget of `self`
    #[doc(alias = "gtk_widget_get_parent")]
    #[doc(alias = "get_parent")]
    fn parent(&self) -> Option<Widget>;

    /// 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 [`Fixed`][crate::Fixed].
    ///
    /// 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 [`prelude::WidgetExt::measure`][crate::prelude::WidgetExt::measure] if you want to support baseline alignment.
    ///
    /// # Returns
    ///
    ///
    /// ## `minimum_size`
    /// location for storing the minimum size
    ///
    /// ## `natural_size`
    /// location for storing the natural size
    #[doc(alias = "gtk_widget_get_preferred_size")]
    #[doc(alias = "get_preferred_size")]
    fn preferred_size(&self) -> (Requisition, Requisition);

    /// Returns the widgets previous sibling.
    ///
    /// This API is primarily meant for widget implementations.
    ///
    /// # Returns
    ///
    /// The widget's previous sibling
    #[doc(alias = "gtk_widget_get_prev_sibling")]
    #[doc(alias = "get_prev_sibling")]
    fn prev_sibling(&self) -> Option<Widget>;

    /// Gets the primary clipboard of `self`.
    ///
    /// This is a utility function to get the primary clipboard object
    /// for the [`gdk::Display`][crate::gdk::Display] that `self` is using.
    ///
    /// Note that this function always works, even when `self` is not
    /// realized yet.
    ///
    /// # Returns
    ///
    /// the appropriate clipboard object
    #[doc(alias = "gtk_widget_get_primary_clipboard")]
    #[doc(alias = "get_primary_clipboard")]
    fn primary_clipboard(&self) -> gdk::Clipboard;

    /// Determines whether `self` is realized.
    ///
    /// # Returns
    ///
    /// [`true`] if `self` is realized, [`false`] otherwise
    #[doc(alias = "gtk_widget_get_realized")]
    #[doc(alias = "get_realized")]
    fn is_realized(&self) -> bool;

    /// Determines whether `self` is always treated as the default widget
    /// within its toplevel when it has the focus, even if another widget
    /// is the default.
    ///
    /// See [``set_receives_default()``][`Self::set_receives_default()`].
    ///
    /// # Returns
    ///
    /// [`true`] if `self` acts as the default widget when focused,
    ///  [`false`] otherwise
    #[doc(alias = "gtk_widget_get_receives_default")]
    #[doc(alias = "get_receives_default")]
    fn receives_default(&self) -> bool;

    /// 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.
    ///
    /// # Returns
    ///
    /// The [`SizeRequestMode`][crate::SizeRequestMode] preferred by `self`.
    #[doc(alias = "gtk_widget_get_request_mode")]
    #[doc(alias = "get_request_mode")]
    fn request_mode(&self) -> SizeRequestMode;

    /// Returns the [`Root`][crate::Root] widget of `self`.
    ///
    /// This function will return [`None`] if the widget is not contained
    /// inside a widget tree with a root widget.
    ///
    /// [`Root`][crate::Root] widgets will return themselves here.
    ///
    /// # Returns
    ///
    /// the root widget of `self`
    #[doc(alias = "gtk_widget_get_root")]
    #[doc(alias = "get_root")]
    fn root(&self) -> Option<Root>;

    /// 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()``.
    ///
    /// # Returns
    ///
    /// the scale factor for `self`
    #[doc(alias = "gtk_widget_get_scale_factor")]
    #[doc(alias = "get_scale_factor")]
    fn scale_factor(&self) -> i32;

    /// Returns the widget’s sensitivity.
    ///
    /// This function returns the value that has been set using
    /// [``set_sensitive()``][`Self::set_sensitive()`]).
    ///
    /// The effective sensitivity of a widget is however determined
    /// by both its own and its parent widget’s sensitivity.
    /// See [``is_sensitive()``][`Self::is_sensitive()`].
    ///
    /// # Returns
    ///
    /// [`true`] if the widget is sensitive
    #[doc(alias = "gtk_widget_get_sensitive")]
    fn get_sensitive(&self) -> bool;

    /// Gets the settings object holding the settings used for this widget.
    ///
    /// Note that this function can only be called when the [`Widget`][crate::Widget]
    /// is attached to a toplevel, since the settings object is specific
    /// to a particular [`gdk::Display`][crate::gdk::Display]. If you want to monitor the widget for
    /// changes in its settings, connect to the `notify::display` signal.
    ///
    /// # Returns
    ///
    /// the relevant [`Settings`][crate::Settings] object
    #[doc(alias = "gtk_widget_get_settings")]
    #[doc(alias = "get_settings")]
    fn settings(&self) -> Settings;

    /// Returns the content width or height of the widget.
    ///
    /// Which dimension is returned depends on `orientation`.
    ///
    /// This is equivalent to calling [``width()``][`Self::width()`]
    /// for [`Orientation::Horizontal`][crate::Orientation::Horizontal] or [``height()``][`Self::height()`]
    /// for [`Orientation::Vertical`][crate::Orientation::Vertical], but can be used when
    /// writing orientation-independent code, such as when
    /// implementing [`Orientable`][crate::Orientable] widgets.
    /// ## `orientation`
    /// the orientation to query
    ///
    /// # Returns
    ///
    /// The size of `self` in `orientation`.
    #[doc(alias = "gtk_widget_get_size")]
    #[doc(alias = "get_size")]
    fn size(&self, orientation: Orientation) -> i32;

    /// Gets the size request that was explicitly set for the widget using
    /// [`set_size_request()`][Self::set_size_request()].
    ///
    /// 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
    /// [``set_size_request()``][`Self::set_size_request()`]. To get the size a widget will
    /// actually request, call [``measure()``][`Self::measure()`] instead of
    /// this function.
    ///
    /// # Returns
    ///
    ///
    /// ## `width`
    /// return location for width
    ///
    /// ## `height`
    /// return location for height
    #[doc(alias = "gtk_widget_get_size_request")]
    #[doc(alias = "get_size_request")]
    fn size_request(&self) -> (i32, i32);

    /// Returns the widget state as a flag set.
    ///
    /// It is worth mentioning that the effective [`StateFlags::INSENSITIVE`][crate::StateFlags::INSENSITIVE]
    /// state will be returned, that is, also based on parent insensitivity,
    /// even if `self` itself is sensitive.
    ///
    /// Also note that if you are looking for a way to obtain the
    /// [`StateFlags`][crate::StateFlags] to pass to a [`StyleContext`][crate::StyleContext]
    /// method, you should look at [``StyleContextExt::state()``][crate::prelude::`StyleContextExt::state()`].
    ///
    /// # Returns
    ///
    /// The state flags for widget
    #[doc(alias = "gtk_widget_get_state_flags")]
    #[doc(alias = "get_state_flags")]
    fn state_flags(&self) -> StateFlags;

    /// Returns the style context associated to `self`.
    ///
    /// The returned object is guaranteed to be the same
    /// for the lifetime of `self`.
    ///
    /// # Returns
    ///
    /// the widgets [`StyleContext`][crate::StyleContext]
    #[doc(alias = "gtk_widget_get_style_context")]
    #[doc(alias = "get_style_context")]
    fn style_context(&self) -> StyleContext;

    /// Fetch an object build from the template XML for `widget_type` in
    /// this `self` instance.
    ///
    /// This will only report children which were previously declared
    /// with `Gtk::`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.
    /// ## `widget_type`
    /// The `GType` to get a template child for
    /// ## `name`
    /// The “id” of the child defined in the template XML
    ///
    /// # Returns
    ///
    /// The object built in the template XML with
    ///  the id `name`
    #[doc(alias = "gtk_widget_get_template_child")]
    #[doc(alias = "get_template_child")]
    fn template_child(&self, widget_type: glib::types::Type, name: &str) -> Option<glib::Object>;

    /// Gets the contents of the tooltip for `self`.
    ///
    /// If the tooltip has not been set using
    /// [``set_tooltip_markup()``][`Self::set_tooltip_markup()`], this
    /// function returns [`None`].
    ///
    /// # Returns
    ///
    /// the tooltip text
    #[doc(alias = "gtk_widget_get_tooltip_markup")]
    #[doc(alias = "get_tooltip_markup")]
    fn tooltip_markup(&self) -> Option<glib::GString>;

    /// Gets the contents of the tooltip for `self`.
    ///
    /// If the `self`'s tooltip was set using
    /// [``set_tooltip_markup()``][`Self::set_tooltip_markup()`],
    /// this function will return the escaped text.
    ///
    /// # Returns
    ///
    /// the tooltip text
    #[doc(alias = "gtk_widget_get_tooltip_text")]
    #[doc(alias = "get_tooltip_text")]
    fn tooltip_text(&self) -> Option<glib::GString>;

    /// Gets the vertical alignment of `self`.
    ///
    /// # Returns
    ///
    /// the vertical alignment of `self`
    #[doc(alias = "gtk_widget_get_valign")]
    #[doc(alias = "get_valign")]
    fn valign(&self) -> Align;

    /// Gets whether the widget would like any available extra vertical
    /// space.
    ///
    /// See [``hexpands()``][`Self::hexpands()`] for more detail.
    ///
    /// # Returns
    ///
    /// whether vexpand flag is set
    #[doc(alias = "gtk_widget_get_vexpand")]
    #[doc(alias = "get_vexpand")]
    fn vexpands(&self) -> bool;

    /// Gets whether [`set_vexpand()`][Self::set_vexpand()] has been used to
    /// explicitly set the expand flag on this widget.
    ///
    /// See [``is_hexpand_set()``][`Self::is_hexpand_set()`] for more detail.
    ///
    /// # Returns
    ///
    /// whether vexpand has been explicitly set
    #[doc(alias = "gtk_widget_get_vexpand_set")]
    #[doc(alias = "get_vexpand_set")]
    fn is_vexpand_set(&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
    /// [``is_visible()``][`Self::is_visible()`] instead.
    ///
    /// This function does not check if the widget is
    /// obscured in any way.
    ///
    /// See [``set_visible()``][`Self::set_visible()`].
    ///
    /// # Returns
    ///
    /// [`true`] if the widget is visible
    #[doc(alias = "gtk_widget_get_visible")]
    fn get_visible(&self) -> bool;

    /// 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 `vfunc::Gtk::Widget::snapshot`.
    ///
    /// For pointer events, see [``contains()``][`Self::contains()`].
    ///
    /// # Returns
    ///
    /// The width of `self`
    #[doc(alias = "gtk_widget_get_width")]
    #[doc(alias = "get_width")]
    fn width(&self) -> i32;

    /// Causes `self` to have the keyboard focus for the [`Window`][crate::Window] it's inside.
    ///
    /// If `self` is not focusable, or its `vfunc::Gtk::Widget::grab_focus`
    /// implementation cannot transfer the focus to a descendant of `self`
    /// that is focusable, it will not take focus and [`false`] will be returned.
    ///
    /// Calling [``grab_focus()``][`Self::grab_focus()`] on an already focused widget
    /// is allowed, should not have an effect, and return [`true`].
    ///
    /// # Returns
    ///
    /// [`true`] if focus is now inside `self`.
    #[doc(alias = "gtk_widget_grab_focus")]
    fn grab_focus(&self) -> bool;

    /// Returns whether `css_class` is currently applied to `self`.
    /// ## `css_class`
    /// A style class, without the leading '.'
    ///  used for notation of style classes
    ///
    /// # Returns
    ///
    /// [`true`] if `css_class` is currently applied to `self`,
    ///  [`false`] otherwise.
    #[doc(alias = "gtk_widget_has_css_class")]
    fn has_css_class(&self, css_class: &str) -> bool;

    /// Determines whether `self` is the current default widget
    /// within its toplevel.
    ///
    /// # Returns
    ///
    /// [`true`] if `self` is the current default widget
    ///  within its toplevel, [`false`] otherwise
    #[doc(alias = "gtk_widget_has_default")]
    fn has_default(&self) -> bool;

    /// Determines if the widget has the global input focus.
    ///
    /// See [``is_focus()``][`Self::is_focus()`] for the difference between
    /// having the global input focus, and only having the focus
    /// within a toplevel.
    ///
    /// # Returns
    ///
    /// [`true`] if the widget has the global input focus.
    #[doc(alias = "gtk_widget_has_focus")]
    fn has_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 `self`. See [``GtkWindowExt::gets_focus_visible()``][crate::prelude::`GtkWindowExt::gets_focus_visible()`] for more
    /// information about focus indication.
    ///
    /// To find out if the widget has the global input focus, use
    /// [``has_focus()``][`Self::has_focus()`].
    ///
    /// # Returns
    ///
    /// [`true`] if the widget should display a “focus rectangle”
    #[doc(alias = "gtk_widget_has_visible_focus")]
    fn has_visible_focus(&self) -> bool;

    /// Reverses the effects of [`show()`][Self::show()].
    ///
    /// This is causing the widget to be hidden (invisible to the user).
    #[doc(alias = "gtk_widget_hide")]
    fn hide(&self);

    /// Returns whether the widget is currently being destroyed.
    ///
    /// This information can sometimes be used to avoid doing
    /// unnecessary work.
    ///
    /// # Returns
    ///
    /// [`true`] if `self` is being destroyed
    #[doc(alias = "gtk_widget_in_destruction")]
    fn in_destruction(&self) -> bool;

    /// 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
    /// `Gtk::`WidgetClass::set_template()``.
    ///
    /// It is important to call this function in the instance initializer
    /// of a [`Widget`][crate::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 `[`glib::Object::new()`][crate::glib::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 `[`glib::Object::new()`][crate::glib::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.
    #[doc(alias = "gtk_widget_init_template")]
    fn init_template(&self);

    /// Inserts `group` into `self`.
    ///
    /// Children of `self` that implement [`Actionable`][crate::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 [`None`], a previously inserted group for `name` is
    /// removed from `self`.
    /// ## `name`
    /// the prefix for actions in `group`
    /// ## `group`
    /// a `GActionGroup`, or [`None`] to remove
    ///  the previously inserted group for `name`
    #[doc(alias = "gtk_widget_insert_action_group")]
    fn insert_action_group<P: IsA<gio::ActionGroup>>(&self, name: &str, group: Option<&P>);

    /// Inserts `self` into the child widget list of `parent`.
    ///
    /// It will be placed after `previous_sibling`, or at the beginning if
    /// `previous_sibling` is [`None`].
    ///
    /// After calling this function, `gtk_widget_get_prev_sibling(widget)`
    /// will return `previous_sibling`.
    ///
    /// If `parent` is already set as the parent widget of `self`, this
    /// function can also be used to reorder `self` in the child widget
    /// list of `parent`.
    ///
    /// This API is primarily meant for widget implementations; if you are
    /// just using a widget, you *must* use its own API for adding children.
    /// ## `parent`
    /// the parent [`Widget`][crate::Widget] to insert `self` into
    /// ## `previous_sibling`
    /// the new previous sibling of `self`
    #[doc(alias = "gtk_widget_insert_after")]
    fn insert_after<P: IsA<Widget>, Q: IsA<Widget>>(
        &self,
        parent: &P,
        previous_sibling: Option<&Q>,
    );

    /// Inserts `self` into the child widget list of `parent`.
    ///
    /// It will be placed before `next_sibling`, or at the end if
    /// `next_sibling` is [`None`].
    ///
    /// After calling this function, `gtk_widget_get_next_sibling(widget)`
    /// will return `next_sibling`.
    ///
    /// If `parent` is already set as the parent widget of `self`, this function
    /// can also be used to reorder `self` in the child widget list of `parent`.
    ///
    /// This API is primarily meant for widget implementations; if you are
    /// just using a widget, you *must* use its own API for adding children.
    /// ## `parent`
    /// the parent [`Widget`][crate::Widget] to insert `self` into
    /// ## `next_sibling`
    /// the new next sibling of `self`
    #[doc(alias = "gtk_widget_insert_before")]
    fn insert_before<P: IsA<Widget>, Q: IsA<Widget>>(&self, parent: &P, next_sibling: Option<&Q>);

    /// Determines whether `self` is somewhere inside `ancestor`,
    /// possibly with intermediate containers.
    /// ## `ancestor`
    /// another [`Widget`][crate::Widget]
    ///
    /// # Returns
    ///
    /// [`true`] if `ancestor` contains `self` as a child,
    ///  grandchild, great grandchild, etc.
    #[doc(alias = "gtk_widget_is_ancestor")]
    fn is_ancestor<P: IsA<Widget>>(&self, ancestor: &P) -> bool;

    /// Determines whether `self` can be drawn to.
    ///
    /// A widget can be drawn if it is mapped and visible.
    ///
    /// # Returns
    ///
    /// [`true`] if `self` is drawable, [`false`] otherwise
    #[doc(alias = "gtk_widget_is_drawable")]
    fn is_drawable(&self) -> bool;

    /// Determines if the widget is the focus widget within its
    /// toplevel.
    ///
    /// This does not mean that the `property::Widget::has-focus`
    /// property is necessarily set; `property::Widget::has-focus`
    /// will only be set if the toplevel widget additionally has the
    /// global input focus.
    ///
    /// # Returns
    ///
    /// [`true`] if the widget is the focus widget.
    #[doc(alias = "gtk_widget_is_focus")]
    fn is_focus(&self) -> bool;

    /// Returns the widget’s effective sensitivity.
    ///
    /// This means it is sensitive itself and also its
    /// parent widget is sensitive.
    ///
    /// # Returns
    ///
    /// [`true`] if the widget is effectively sensitive
    #[doc(alias = "gtk_widget_is_sensitive")]
    fn is_sensitive(&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 [``get_visible()``][`Self::get_visible()`] and
    /// [``set_visible()``][`Self::set_visible()`].
    ///
    /// # Returns
    ///
    /// [`true`] if the widget and all its parents are visible
    #[doc(alias = "gtk_widget_is_visible")]
    fn is_visible(&self) -> bool;

    /// Emits the `::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
    /// [``child_focus()``][`Self::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
    /// [``child_focus()``][`Self::child_focus()`] on the widget’s toplevel.
    ///
    /// The default `signal::Widget::keynav-failed` handler returns
    /// [`false`] for [`DirectionType::TabForward`][crate::DirectionType::TabForward] and [`DirectionType::TabBackward`][crate::DirectionType::TabBackward].
    /// For the other values of [`DirectionType`][crate::DirectionType] it returns [`true`].
    ///
    /// Whenever the default handler returns [`true`], it also calls
    /// [``error_bell()``][`Self::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`][crate::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.
    /// ## `direction`
    /// direction of focus movement
    ///
    /// # Returns
    ///
    /// [`true`] if stopping keyboard navigation is fine, [`false`]
    ///  if the emitting widget should try to handle the keyboard
    ///  navigation attempt in its parent container(s).
    #[doc(alias = "gtk_widget_keynav_failed")]
    fn keynav_failed(&self, direction: DirectionType) -> bool;

    /// 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()``][crate::`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.
    ///
    /// # Returns
    ///
    /// the list
    ///  of mnemonic labels; free this list with `g_list_free()` when you
    ///  are done with it.
    #[doc(alias = "gtk_widget_list_mnemonic_labels")]
    fn list_mnemonic_labels(&self) -> Vec<Widget>;

    /// Causes a widget to be mapped if it isn’t already.
    ///
    /// This function is only for use in widget implementations.
    #[doc(alias = "gtk_widget_map")]
    fn map(&self);

    /// Measures `self` in the orientation `orientation` and for the given `for_size`.
    ///
    /// As an example, if `orientation` is [`Orientation::Horizontal`][crate::Orientation::Horizontal] and `for_size`
    /// is 300, this functions will compute the minimum and natural width of `self`
    /// if it is allocated at a height of 300 pixels.
    ///
    /// See [GtkWidget’s geometry management section](class.Widget.html`height`-for-width-geometry-management) for
    /// a more details on implementing ``GtkWidgetClass.measure()``.
    /// ## `orientation`
    /// the orientation to measure
    /// ## `for_size`
    /// Size for the opposite of `orientation`, i.e.
    ///  if `orientation` is [`Orientation::Horizontal`][crate::Orientation::Horizontal], this is
    ///  the height the widget should be measured with. The [`Orientation::Vertical`][crate::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.
    ///
    /// # Returns
    ///
    ///
    /// ## `minimum`
    /// location to store the minimum size
    ///
    /// ## `natural`
    /// location to store the natural size
    ///
    /// ## `minimum_baseline`
    /// location to store the baseline
    ///  position for the minimum size
    ///
    /// ## `natural_baseline`
    /// location to store the baseline
    ///  position for the natural size
    #[doc(alias = "gtk_widget_measure")]
    fn measure(&self, orientation: Orientation, for_size: i32) -> (i32, i32, i32, i32);

    /// Emits the ::mnemonic-activate signal.
    ///
    /// See `signal::Widget::mnemonic-activate`.
    /// ## `group_cycling`
    /// [`true`] if there are other widgets with the same mnemonic
    ///
    /// # Returns
    ///
    /// [`true`] if the signal has been handled
    #[doc(alias = "gtk_widget_mnemonic_activate")]
    fn mnemonic_activate(&self, group_cycling: bool) -> bool;

    /// Returns a `GListModel` to track the children of `self`.
    ///
    /// 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.
    ///
    /// # Returns
    ///
    ///
    ///  a `GListModel` tracking `self`'s children
    #[doc(alias = "gtk_widget_observe_children")]
    fn observe_children(&self) -> gio::ListModel;

    /// Returns a `GListModel` to track the [`EventController`][crate::EventController]s
    /// of `self`.
    ///
    /// 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.
    ///
    /// # Returns
    ///
    ///
    ///  a `GListModel` tracking `self`'s controllers
    #[doc(alias = "gtk_widget_observe_controllers")]
    fn observe_controllers(&self) -> gio::ListModel;

    /// Finds the descendant of `self` closest to the point (`x`, `y`).
    ///
    /// The point must be given in widget coordinates, so (0, 0) is assumed
    /// to be the top left of `self`'s content area.
    ///
    /// Usually widgets will return [`None`] if the given coordinate is not
    /// contained in `self` checked via [``contains()``][`Self::contains()`].
    /// Otherwise they will recursively try to find a child that does
    /// not return [`None`]. 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.
    /// ## `x`
    /// X coordinate to test, relative to `self`'s origin
    /// ## `y`
    /// Y coordinate to test, relative to `self`'s origin
    /// ## `flags`
    /// Flags to influence what is picked
    ///
    /// # Returns
    ///
    /// The widget descendant at
    ///  the given point
    #[doc(alias = "gtk_widget_pick")]
    fn pick(&self, x: f64, y: f64, flags: PickFlags) -> Option<Widget>;

    /// Flags the widget for a rerun of the `vfunc::Gtk::Widget::size_allocate`
    /// function.
    ///
    /// Use this function instead of [``queue_resize()``][`Self::queue_resize()`]
    /// when the `self`'s size request didn't change but it wants to
    /// reposition its contents.
    ///
    /// An example user of this function is [``set_halign()``][`Self::set_halign()`].
    ///
    /// This function is only for use in widget implementations.
    #[doc(alias = "gtk_widget_queue_allocate")]
    fn queue_allocate(&self);

    /// Schedules this widget to be redrawn in the paint phase
    /// of the current or the next frame.
    ///
    /// This means `self`'s `vfunc::Gtk::Widget::snapshot`
    /// implementation will be called.
    #[doc(alias = "gtk_widget_queue_draw")]
    fn queue_draw(&self);

    /// 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`][crate::Label], the label queues a resize to ensure there’s
    /// enough space for the new text.
    ///
    /// Note that you cannot call [`queue_resize()`][Self::queue_resize()] on a widget
    /// from inside its implementation of the `vfunc::Gtk::Widget::size_allocate`
    /// virtual method. Calls to [`queue_resize()`][Self::queue_resize()] from inside
    /// `vfunc::Gtk::Widget::size_allocate` will be silently ignored.
    ///
    /// This function is only for use in widget implementations.
    #[doc(alias = "gtk_widget_queue_resize")]
    fn queue_resize(&self);

    /// 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 `self` 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
    /// `signal::Widget::realize`.
    #[doc(alias = "gtk_widget_realize")]
    fn realize(&self);

    /// Removes `controller` from `self`, so that it doesn't process
    /// events anymore.
    ///
    /// It 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.
    /// ## `controller`
    /// a [`EventController`][crate::EventController]
    #[doc(alias = "gtk_widget_remove_controller")]
    fn remove_controller<P: IsA<EventController>>(&self, controller: &P);

    /// Removes a style from `self`.
    ///
    /// After this, the style of `self` will stop matching for `css_class`.
    /// ## `css_class`
    /// The style class to remove from `self`, without
    ///  the leading '.' used for notation of style classes
    #[doc(alias = "gtk_widget_remove_css_class")]
    fn remove_css_class(&self, css_class: &str);

    /// Removes a widget from the list of mnemonic labels for this widget.
    ///
    /// See [``list_mnemonic_labels()``][`Self::list_mnemonic_labels()`]. The widget must
    /// have previously been added to the list with
    /// [``add_mnemonic_label()``][`Self::add_mnemonic_label()`].
    /// ## `label`
    /// a [`Widget`][crate::Widget] that was previously set as a mnemonic
    ///  label for `self` with [``add_mnemonic_label()``][`Self::add_mnemonic_label()`]
    #[doc(alias = "gtk_widget_remove_mnemonic_label")]
    fn remove_mnemonic_label<P: IsA<Widget>>(&self, label: &P);

    /// Specifies 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 [``grab_focus()``][`Self::grab_focus()`] for actually setting
    /// the input focus on a widget.
    /// ## `can_focus`
    /// whether or not the input focus can enter
    ///  the widget or any of its children
    #[doc(alias = "gtk_widget_set_can_focus")]
    fn set_can_focus(&self, can_focus: bool);

    /// Sets whether `self` can be the target of pointer events.
    /// ## `can_target`
    /// whether this widget should be able to
    ///  receive pointer events
    #[doc(alias = "gtk_widget_set_can_target")]
    fn set_can_target(&self, can_target: bool);

    /// Sets whether `self` should be mapped along with its parent.
    ///
    /// The child visibility can be set for widget before it is added
    /// to a container with [``set_parent()``][`Self::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 container implementations
    /// and should never be called by an application.
    /// ## `child_visible`
    /// if [`true`], `self` should be mapped along
    ///  with its parent.
    #[doc(alias = "gtk_widget_set_child_visible")]
    fn set_child_visible(&self, child_visible: bool);

    /// Clear all style classes applied to `self`
    /// and replace them with `classes`.
    /// ## `classes`
    ///
    ///  [`None`]-terminated list of style classes to apply to `self`.
    #[doc(alias = "gtk_widget_set_css_classes")]
    fn set_css_classes(&self, classes: &[&str]);

    /// Sets the cursor to be shown when pointer devices point
    /// towards `self`.
    ///
    /// If the `cursor` is NULL, `self` will use the cursor
    /// inherited from the parent widget.
    /// ## `cursor`
    /// the new cursor
    #[doc(alias = "gtk_widget_set_cursor")]
    fn set_cursor(&self, cursor: Option<&gdk::Cursor>);

    /// Sets a named cursor to be shown when pointer devices point
    /// towards `self`.
    ///
    /// This is a utility function that creates a cursor via
    /// [`gdk::`Cursor::from_name()``][crate::gdk::`Cursor::from_name()`] and then sets it on `self`
    /// with [``set_cursor()``][`Self::set_cursor()`]. See those functions for
    /// details.
    ///
    /// On top of that, this function allows `name` to be [`None`], which
    /// will do the same as calling [``set_cursor()``][`Self::set_cursor()`]
    /// with a [`None`] cursor.
    /// ## `name`
    /// The name of the cursor
    #[doc(alias = "gtk_widget_set_cursor_from_name")]
    fn set_cursor_from_name(&self, name: Option<&str>);

    /// Sets the reading direction on a particular 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 present, except for containers
    /// where the containers 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`][crate::TextDirection::None], then the value
    /// set by [``Widget::set_default_direction()``][crate::`Widget::set_default_direction()`] will be used.
    /// ## `dir`
    /// the new direction
    #[doc(alias = "gtk_widget_set_direction")]
    fn set_direction(&self, dir: TextDirection);

    /// Set `child` as the current focus child of `self`.
    ///
    /// This function is only suitable for widget implementations.
    /// If you want a certain widget to get the input focus, call
    /// [``grab_focus()``][`Self::grab_focus()`] on it.
    /// ## `child`
    /// a direct child widget of `self` or [`None`]
    ///  to unset the focus child of `self`
    #[doc(alias = "gtk_widget_set_focus_child")]
    fn set_focus_child<P: IsA<Widget>>(&self, child: Option<&P>);

    /// 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.
    /// ## `focus_on_click`
    /// whether the widget should grab focus when clicked
    ///  with the mouse
    #[doc(alias = "gtk_widget_set_focus_on_click")]
    fn set_focus_on_click(&self, focus_on_click: bool);

    /// Specifies whether `self` 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 [``grab_focus()``][`Self::grab_focus()`] for actually setting
    /// the input focus on a widget.
    /// ## `focusable`
    /// whether or not `self` can own the input focus
    #[doc(alias = "gtk_widget_set_focusable")]
    fn set_focusable(&self, focusable: bool);

    /// Sets the font map to use for Pango rendering.
    ///
    /// 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.
    /// ## `font_map`
    /// a [`pango::FontMap`][crate::pango::FontMap], or [`None`] to unset any
    ///  previously set font map
    #[doc(alias = "gtk_widget_set_font_map")]
    fn set_font_map<P: IsA<pango::FontMap>>(&self, font_map: Option<&P>);

    /// Sets the `cairo_font_options_t` used for Pango rendering
    /// in this widget.
    ///
    /// When not set, the default font options for the [`gdk::Display`][crate::gdk::Display]
    /// will be used.
    /// ## `options`
    /// a `cairo_font_options_t`
    ///  to unset any previously set default font options
    #[doc(alias = "gtk_widget_set_font_options")]
    fn set_font_options(&self, options: Option<&cairo::FontOptions>);

    /// Sets the horizontal alignment of `self`.
    /// ## `align`
    /// the horizontal alignment
    #[doc(alias = "gtk_widget_set_halign")]
    fn set_halign(&self, align: Align);

    /// Sets the `has-tooltip` property on `self` to `has_tooltip`.
    /// ## `has_tooltip`
    /// whether or not `self` has a tooltip.
    #[doc(alias = "gtk_widget_set_has_tooltip")]
    fn set_has_tooltip(&self, has_tooltip: bool);

    /// Sets whether the widget would like any available extra horizontal
    /// space.
    ///
    /// When a user resizes a [`Window`][crate::Window], widgets with expand=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 [``compute_expand()``][`Self::compute_expand()`].
    /// A container can decide how the expandability of children affects the
    /// expansion of the container by overriding the compute_expand virtual
    /// method on [`Widget`][crate::Widget].).
    ///
    /// 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
    /// [``set_hexpand()``][`Self::set_hexpand()`] sets the hexpand-set property (see
    /// [``set_hexpand_set()``][`Self::set_hexpand_set()`]) which causes the widget’s hexpand
    /// value to be used, rather than looking at children and widget state.
    /// ## `expand`
    /// whether to expand
    #[doc(alias = "gtk_widget_set_hexpand")]
    fn set_hexpand(&self, expand: bool);

    /// Sets whether the hexpand flag will be used.
    ///
    /// The `property::Widget::hexpand-set` property will be set
    /// automatically when you call [``set_hexpand()``][`Self::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.
    /// ## `set`
    /// value for hexpand-set property
    #[doc(alias = "gtk_widget_set_hexpand_set")]
    fn set_hexpand_set(&self, set: bool);

    /// Sets the layout manager delegate instance that provides an
    /// implementation for measuring and allocating the children of `self`.
    /// ## `layout_manager`
    /// a [`LayoutManager`][crate::LayoutManager]
    #[doc(alias = "gtk_widget_set_layout_manager")]
    fn set_layout_manager<P: IsA<LayoutManager>>(&self, layout_manager: Option<&P>);

    /// Sets the bottom margin of `self`.
    /// ## `margin`
    /// the bottom margin
    #[doc(alias = "gtk_widget_set_margin_bottom")]
    fn set_margin_bottom(&self, margin: i32);

    /// Sets the end margin of `self`.
    /// ## `margin`
    /// the end margin
    #[doc(alias = "gtk_widget_set_margin_end")]
    fn set_margin_end(&self, margin: i32);

    /// Sets the start margin of `self`.
    /// ## `margin`
    /// the start margin
    #[doc(alias = "gtk_widget_set_margin_start")]
    fn set_margin_start(&self, margin: i32);

    /// Sets the top margin of `self`.
    /// ## `margin`
    /// the top margin
    #[doc(alias = "gtk_widget_set_margin_top")]
    fn set_margin_top(&self, margin: i32);

    /// 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`][crate::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.
    /// ## `name`
    /// name for the widget
    #[doc(alias = "gtk_widget_set_name")]
    #[doc(alias = "set_name")]
    fn set_widget_name(&self, name: &str);

    /// Request the `self` 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 should
    /// 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`][crate::Popover]s
    /// and other [`Native`][crate::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.
    /// ## `opacity`
    /// desired opacity, between 0 and 1
    #[doc(alias = "gtk_widget_set_opacity")]
    fn set_opacity(&self, opacity: f64);

    /// Sets how `self` treats content that is drawn outside the
    /// widget's content area.
    ///
    /// See the definition of [`Overflow`][crate::Overflow] for details.
    ///
    /// This setting is provided for widget implementations and
    /// should not be used by application code.
    ///
    /// The default value is [`Overflow::Visible`][crate::Overflow::Visible].
    /// ## `overflow`
    /// desired overflow
    #[doc(alias = "gtk_widget_set_overflow")]
    fn set_overflow(&self, overflow: Overflow);

    /// Sets `parent` as the parent widget of `self`.
    ///
    /// 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 [``unparent()``][`Self::unparent()`].
    ///
    /// This function is useful only when implementing subclasses of
    /// [`Widget`][crate::Widget].
    /// ## `parent`
    /// parent widget
    #[doc(alias = "gtk_widget_set_parent")]
    fn set_parent<P: IsA<Widget>>(&self, parent: &P);

    /// Specifies whether `self` will be treated as the default
    /// widget within its toplevel when it has the focus, even if
    /// another widget is the default.
    /// ## `receives_default`
    /// whether or not `self` can be a default widget.
    #[doc(alias = "gtk_widget_set_receives_default")]
    fn set_receives_default(&self, receives_default: bool);

    /// Sets the sensitivity of a 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.
    /// ## `sensitive`
    /// [`true`] to make the widget sensitive
    #[doc(alias = "gtk_widget_set_sensitive")]
    fn set_sensitive(&self, sensitive: bool);

    /// Sets the minimum size of a 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, [``GtkWindowExt::set_default_size()``][crate::prelude::`GtkWindowExt::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's
    /// basically impossible to hardcode a size that will always be
    /// correct.
    ///
    /// 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
    /// `property::Widget::margin-start`,
    /// `property::Widget::margin-end`,
    /// `property::Widget::margin-top`, and
    /// `property::Widget::margin-bottom`, but it does include pretty
    /// much all other padding or border properties set by any subclass
    /// of [`Widget`][crate::Widget].
    /// ## `width`
    /// width `self` should request, or -1 to unset
    /// ## `height`
    /// height `self` should request, or -1 to unset
    #[doc(alias = "gtk_widget_set_size_request")]
    fn set_size_request(&self, width: i32, height: i32);

    /// Turns on flag values in the current widget state.
    ///
    /// Typical widget states are insensitive, prelighted, etc.
    ///
    /// This function accepts the values [`StateFlags::DIR_LTR`][crate::StateFlags::DIR_LTR] and
    /// [`StateFlags::DIR_RTL`][crate::StateFlags::DIR_RTL] but ignores them. If you want to set
    /// the widget's direction, use [``set_direction()``][`Self::set_direction()`].
    ///
    /// This function is for use in widget implementations.
    /// ## `flags`
    /// State flags to turn on
    /// ## `clear`
    /// Whether to clear state before turning on `flags`
    #[doc(alias = "gtk_widget_set_state_flags")]
    fn set_state_flags(&self, flags: StateFlags, clear: bool);

    /// Sets `markup` as the contents of the tooltip, which is marked
    /// up with Pango markup.
    ///
    /// This function will take care of setting the
    /// `property::Widget::has-tooltip` as a side effect, and of the
    /// default handler for the `signal::Widget::query-tooltip` signal.
    ///
    /// See also [``Tooltip::set_markup()``][crate::`Tooltip::set_markup()`].
    /// ## `markup`
    /// the contents of the tooltip for `self`
    #[doc(alias = "gtk_widget_set_tooltip_markup")]
    fn set_tooltip_markup(&self, markup: Option<&str>);

    /// Sets `text` as the contents of the tooltip.
    ///
    /// If `text` contains any markup, it will be escaped.
    ///
    /// This function will take care of setting
    /// `property::Widget::has-tooltip` as a side effect,
    /// and of the default handler for the
    /// `signal::Widget::query-tooltip` signal.
    ///
    /// See also [``Tooltip::set_text()``][crate::`Tooltip::set_text()`].
    /// ## `text`
    /// the contents of the tooltip for `self`
    #[doc(alias = "gtk_widget_set_tooltip_text")]
    fn set_tooltip_text(&self, text: Option<&str>);

    /// Sets the vertical alignment of `self`.
    /// ## `align`
    /// the vertical alignment
    #[doc(alias = "gtk_widget_set_valign")]
    fn set_valign(&self, align: Align);

    /// Sets whether the widget would like any available extra vertical
    /// space.
    ///
    /// See [``set_hexpand()``][`Self::set_hexpand()`] for more detail.
    /// ## `expand`
    /// whether to expand
    #[doc(alias = "gtk_widget_set_vexpand")]
    fn set_vexpand(&self, expand: bool);

    /// Sets whether the vexpand flag will be used.
    ///
    /// See [``set_hexpand_set()``][`Self::set_hexpand_set()`] for more detail.
    /// ## `set`
    /// value for vexpand-set property
    #[doc(alias = "gtk_widget_set_vexpand_set")]
    fn set_vexpand_set(&self, set: bool);

    /// Sets the visibility state of `self`.
    ///
    /// Note that setting this to [`true`] doesn’t mean the widget is
    /// actually viewable, see [``get_visible()``][`Self::get_visible()`].
    ///
    /// This function simply calls [``show()``][`Self::show()`] or
    /// [``hide()``][`Self::hide()`] but is nicer to use when the
    /// visibility of the widget depends on some condition.
    /// ## `visible`
    /// whether the widget should be shown or not
    #[doc(alias = "gtk_widget_set_visible")]
    fn set_visible(&self, visible: bool);

    /// Returns whether `self` 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.
    ///
    /// # Returns
    ///
    /// [`true`] if child should be included in
    ///  measuring and allocating
    #[doc(alias = "gtk_widget_should_layout")]
    fn should_layout(&self) -> bool;

    /// 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 container is shown, it is immediately realized and
    /// mapped; other shown widgets are realized and mapped when their
    /// toplevel container is realized and mapped.
    #[doc(alias = "gtk_widget_show")]
    fn show(&self);

    /// Allocates widget with a transformation that translates
    /// the origin to the position in `allocation`.
    ///
    /// This is a simple form of [``allocate()``][`Self::allocate()`].
    /// ## `allocation`
    /// position and size to be allocated to `self`
    /// ## `baseline`
    /// The baseline of the child, or -1
    #[doc(alias = "gtk_widget_size_allocate")]
    fn size_allocate(&self, allocation: &Allocation, baseline: i32);

    /// Snapshot the a child of `self`.
    ///
    /// When a widget receives a call to the snapshot function,
    /// it must send synthetic `vfunc::Gtk::Widget::snapshot` calls
    /// to all children. This function provides a convenient way
    /// of doing this. A widget, when it receives a call to its
    /// `vfunc::Gtk::Widget::snapshot` function, calls
    /// [`snapshot_child()`][Self::snapshot_child()] once for each child, passing in
    /// the `snapshot` the widget received.
    ///
    /// [`snapshot_child()`][Self::snapshot_child()] takes care of translating the origin of
    /// `snapshot`, and deciding whether the child needs to be snapshot.
    ///
    /// This function does nothing for children that implement [`Native`][crate::Native].
    /// ## `child`
    /// a child of `self`
    /// ## `snapshot`
    /// [`Snapshot`][crate::Snapshot] as passed to the widget. In particular, no
    ///  calls to [`Snapshot::translate()`][crate::Snapshot::translate()] or other transform calls should
    ///  have been made.
    #[doc(alias = "gtk_widget_snapshot_child")]
    fn snapshot_child<P: IsA<Widget>>(&self, child: &P, snapshot: &Snapshot);

    /// Translate coordinates relative to `self`’s allocation
    /// to coordinates relative to `dest_widget`’s allocations.
    ///
    /// In order to perform this operation, both widget must share
    /// a common ancestor.
    /// ## `dest_widget`
    /// a [`Widget`][crate::Widget]
    /// ## `src_x`
    /// X position relative to `self`
    /// ## `src_y`
    /// Y position relative to `self`
    ///
    /// # Returns
    ///
    /// [`false`] if `self` and `dest_widget` have no common
    ///  ancestor. In this case, 0 is stored in *`dest_x` and *`dest_y`.
    ///  Otherwise [`true`].
    ///
    /// ## `dest_x`
    /// location to store X position relative to `dest_widget`
    ///
    /// ## `dest_y`
    /// location to store Y position relative to `dest_widget`
    #[doc(alias = "gtk_widget_translate_coordinates")]
    fn translate_coordinates<P: IsA<Widget>>(
        &self,
        dest_widget: &P,
        src_x: f64,
        src_y: f64,
    ) -> Option<(f64, f64)>;

    /// Triggers a tooltip query on the display where the toplevel
    /// of `self` is located.
    #[doc(alias = "gtk_widget_trigger_tooltip_query")]
    fn trigger_tooltip_query(&self);

    /// Causes a widget to be unmapped if it’s currently mapped.
    ///
    /// This function is only for use in widget implementations.
    #[doc(alias = "gtk_widget_unmap")]
    fn unmap(&self);

    /// Dissociate `self` from its parent.
    ///
    /// This function is only for use in widget implementations,
    /// typically in dispose.
    #[doc(alias = "gtk_widget_unparent")]
    fn unparent(&self);

    /// Causes a widget to be unrealized (frees all GDK resources
    /// associated with the widget).
    ///
    /// This function is only useful in widget implementations.
    #[doc(alias = "gtk_widget_unrealize")]
    fn unrealize(&self);

    /// Turns off flag values for the current widget state.
    ///
    /// See [``set_state_flags()``][`Self::set_state_flags()`].
    ///
    /// This function is for use in widget implementations.
    /// ## `flags`
    /// State flags to turn off
    #[doc(alias = "gtk_widget_unset_state_flags")]
    fn unset_state_flags(&self, flags: StateFlags);

    /// Override for height request of the widget.
    ///
    /// If this is -1, the natural request will be used.
    #[doc(alias = "height-request")]
    fn height_request(&self) -> i32;

    /// Override for height request of the widget.
    ///
    /// If this is -1, the natural request will be used.
    #[doc(alias = "height-request")]
    fn set_height_request(&self, height_request: i32);

    /// Override for width request of the widget.
    ///
    /// If this is -1, the natural request will be used.
    #[doc(alias = "width-request")]
    fn width_request(&self) -> i32;

    /// Override for width request of the widget.
    ///
    /// If this is -1, the natural request will be used.
    #[doc(alias = "width-request")]
    fn set_width_request(&self, width_request: i32);

    /// 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.
    #[doc(alias = "destroy")]
    fn connect_destroy<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    /// Emitted when the text direction of a widget changes.
    /// ## `previous_direction`
    /// the previous text direction of `widget`
    #[doc(alias = "direction-changed")]
    fn connect_direction_changed<F: Fn(&Self, TextDirection) + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId;

    /// Emitted when `widget` is hidden.
    #[doc(alias = "hide")]
    fn connect_hide<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    /// Emitted if keyboard navigation fails.
    ///
    /// See [``keynav_failed()``][`Self::keynav_failed()`] for details.
    /// ## `direction`
    /// the direction of movement
    ///
    /// # Returns
    ///
    /// [`true`] if stopping keyboard navigation is fine, [`false`]
    ///  if the emitting widget should try to handle the keyboard
    ///  navigation attempt in its parent widget(s).
    #[doc(alias = "keynav-failed")]
    fn connect_keynav_failed<F: Fn(&Self, DirectionType) -> glib::signal::Inhibit + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId;

    /// Emitted when `widget` is going to be mapped.
    ///
    /// A widget is mapped when the widget is visible (which is controlled with
    /// `property::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 `signal::Widget::unmap`.
    #[doc(alias = "map")]
    fn connect_map<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    /// 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`].
    /// ## `group_cycling`
    /// [`true`] if there are other widgets with the same mnemonic
    ///
    /// # Returns
    ///
    /// [`true`] to stop other handlers from being invoked for the event.
    /// [`false`] to propagate the event further.
    #[doc(alias = "mnemonic-activate")]
    fn connect_mnemonic_activate<F: Fn(&Self, bool) -> glib::signal::Inhibit + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId;

    /// Emitted when the focus is moved.
    /// ## `direction`
    /// the direction of the focus move
    #[doc(alias = "move-focus")]
    fn connect_move_focus<F: Fn(&Self, DirectionType) + 'static>(&self, f: F) -> SignalHandlerId;

    fn emit_move_focus(&self, direction: DirectionType);

    /// Emitted when the widgets tooltip is about to be shown.
    ///
    /// This happens when the `property::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.
    /// ## `x`
    /// the x coordinate of the cursor position where the request has
    ///  been emitted, relative to `widget`'s left side
    /// ## `y`
    /// the y coordinate of the cursor position where the request has
    ///  been emitted, relative to `widget`'s top
    /// ## `keyboard_mode`
    /// [`true`] if the tooltip was triggered using the keyboard
    /// ## `tooltip`
    /// a [`Tooltip`][crate::Tooltip]
    ///
    /// # Returns
    ///
    /// [`true`] if `tooltip` should be shown right now, [`false`] otherwise.
    #[doc(alias = "query-tooltip")]
    fn connect_query_tooltip<F: Fn(&Self, i32, i32, bool, &Tooltip) -> bool + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId;

    /// Emitted when `widget` is associated with a [`gdk::Surface`][crate::gdk::Surface].
    ///
    /// This means that [``realize()``][`Self::realize()`] has been called
    /// or the widget has been mapped (that is, it is going to be drawn).
    #[doc(alias = "realize")]
    fn connect_realize<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    /// Emitted when `widget` is shown.
    #[doc(alias = "show")]
    fn connect_show<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    /// Emitted when the widget state changes.
    ///
    /// See [``state_flags()``][`Self::state_flags()`].
    /// ## `flags`
    /// The previous state flags.
    #[doc(alias = "state-flags-changed")]
    fn connect_state_flags_changed<F: Fn(&Self, StateFlags) + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId;

    /// 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.
    #[doc(alias = "unmap")]
    fn connect_unmap<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    /// Emitted when the [`gdk::Surface`][crate::gdk::Surface] associated with `widget` is destroyed.
    ///
    /// This means that [``unrealize()``][`Self::unrealize()`] has been called
    /// or the widget has been unmapped (that is, it is going to be hidden).
    #[doc(alias = "unrealize")]
    fn connect_unrealize<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "can-focus")]
    fn connect_can_focus_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "can-target")]
    fn connect_can_target_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "css-classes")]
    fn connect_css_classes_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "cursor")]
    fn connect_cursor_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "focus-on-click")]
    fn connect_focus_on_click_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "focusable")]
    fn connect_focusable_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "halign")]
    fn connect_halign_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "has-default")]
    fn connect_has_default_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "has-focus")]
    fn connect_has_focus_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "has-tooltip")]
    fn connect_has_tooltip_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "height-request")]
    fn connect_height_request_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "hexpand")]
    fn connect_hexpand_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "hexpand-set")]
    fn connect_hexpand_set_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "layout-manager")]
    fn connect_layout_manager_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "margin-bottom")]
    fn connect_margin_bottom_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "margin-end")]
    fn connect_margin_end_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "margin-start")]
    fn connect_margin_start_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "margin-top")]
    fn connect_margin_top_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "name")]
    fn connect_name_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "opacity")]
    fn connect_opacity_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "overflow")]
    fn connect_overflow_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "parent")]
    fn connect_parent_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "receives-default")]
    fn connect_receives_default_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "root")]
    fn connect_root_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "scale-factor")]
    fn connect_scale_factor_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "sensitive")]
    fn connect_sensitive_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "tooltip-markup")]
    fn connect_tooltip_markup_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "tooltip-text")]
    fn connect_tooltip_text_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "valign")]
    fn connect_valign_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "vexpand")]
    fn connect_vexpand_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "vexpand-set")]
    fn connect_vexpand_set_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "visible")]
    fn connect_visible_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;

    #[doc(alias = "width-request")]
    fn connect_width_request_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;
}

impl<O: IsA<Widget>> WidgetExt for O {
    fn action_set_enabled(&self, action_name: &str, enabled: bool) {
        unsafe {
            ffi::gtk_widget_action_set_enabled(
                self.as_ref().to_glib_none().0,
                action_name.to_glib_none().0,
                enabled.into_glib(),
            );
        }
    }

    fn activate(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_activate(self.as_ref().to_glib_none().0)) }
    }

    fn activate_action(&self, name: &str, args: Option<&glib::Variant>) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_activate_action_variant(
                self.as_ref().to_glib_none().0,
                name.to_glib_none().0,
                args.to_glib_none().0,
            ))
        }
    }

    fn activate_default(&self) {
        unsafe {
            ffi::gtk_widget_activate_default(self.as_ref().to_glib_none().0);
        }
    }

    fn add_controller<P: IsA<EventController>>(&self, controller: &P) {
        unsafe {
            ffi::gtk_widget_add_controller(
                self.as_ref().to_glib_none().0,
                controller.as_ref().to_glib_full(),
            );
        }
    }

    fn add_css_class(&self, css_class: &str) {
        unsafe {
            ffi::gtk_widget_add_css_class(
                self.as_ref().to_glib_none().0,
                css_class.to_glib_none().0,
            );
        }
    }

    fn add_mnemonic_label<P: IsA<Widget>>(&self, label: &P) {
        unsafe {
            ffi::gtk_widget_add_mnemonic_label(
                self.as_ref().to_glib_none().0,
                label.as_ref().to_glib_none().0,
            );
        }
    }

    fn allocate(&self, width: i32, height: i32, baseline: i32, transform: Option<&gsk::Transform>) {
        unsafe {
            ffi::gtk_widget_allocate(
                self.as_ref().to_glib_none().0,
                width,
                height,
                baseline,
                transform.to_glib_full(),
            );
        }
    }

    fn child_focus(&self, direction: DirectionType) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_child_focus(
                self.as_ref().to_glib_none().0,
                direction.into_glib(),
            ))
        }
    }

    fn compute_bounds<P: IsA<Widget>>(&self, target: &P) -> Option<graphene::Rect> {
        unsafe {
            let mut out_bounds = graphene::Rect::uninitialized();
            let ret = from_glib(ffi::gtk_widget_compute_bounds(
                self.as_ref().to_glib_none().0,
                target.as_ref().to_glib_none().0,
                out_bounds.to_glib_none_mut().0,
            ));
            if ret {
                Some(out_bounds)
            } else {
                None
            }
        }
    }

    fn compute_expand(&self, orientation: Orientation) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_compute_expand(
                self.as_ref().to_glib_none().0,
                orientation.into_glib(),
            ))
        }
    }

    fn compute_point<P: IsA<Widget>>(
        &self,
        target: &P,
        point: &graphene::Point,
    ) -> Option<graphene::Point> {
        unsafe {
            let mut out_point = graphene::Point::uninitialized();
            let ret = from_glib(ffi::gtk_widget_compute_point(
                self.as_ref().to_glib_none().0,
                target.as_ref().to_glib_none().0,
                point.to_glib_none().0,
                out_point.to_glib_none_mut().0,
            ));
            if ret {
                Some(out_point)
            } else {
                None
            }
        }
    }

    fn compute_transform<P: IsA<Widget>>(&self, target: &P) -> Option<graphene::Matrix> {
        unsafe {
            let mut out_transform = graphene::Matrix::uninitialized();
            let ret = from_glib(ffi::gtk_widget_compute_transform(
                self.as_ref().to_glib_none().0,
                target.as_ref().to_glib_none().0,
                out_transform.to_glib_none_mut().0,
            ));
            if ret {
                Some(out_transform)
            } else {
                None
            }
        }
    }

    fn contains(&self, x: f64, y: f64) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_contains(
                self.as_ref().to_glib_none().0,
                x,
                y,
            ))
        }
    }

    fn create_pango_context(&self) -> pango::Context {
        unsafe {
            from_glib_full(ffi::gtk_widget_create_pango_context(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn create_pango_layout(&self, text: Option<&str>) -> pango::Layout {
        unsafe {
            from_glib_full(ffi::gtk_widget_create_pango_layout(
                self.as_ref().to_glib_none().0,
                text.to_glib_none().0,
            ))
        }
    }

    fn drag_check_threshold(
        &self,
        start_x: i32,
        start_y: i32,
        current_x: i32,
        current_y: i32,
    ) -> bool {
        unsafe {
            from_glib(ffi::gtk_drag_check_threshold(
                self.as_ref().to_glib_none().0,
                start_x,
                start_y,
                current_x,
                current_y,
            ))
        }
    }

    fn error_bell(&self) {
        unsafe {
            ffi::gtk_widget_error_bell(self.as_ref().to_glib_none().0);
        }
    }

    fn allocated_baseline(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_allocated_baseline(self.as_ref().to_glib_none().0) }
    }

    fn allocated_height(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_allocated_height(self.as_ref().to_glib_none().0) }
    }

    fn allocated_width(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_allocated_width(self.as_ref().to_glib_none().0) }
    }

    fn allocation(&self) -> Allocation {
        unsafe {
            let mut allocation = Allocation::uninitialized();
            ffi::gtk_widget_get_allocation(
                self.as_ref().to_glib_none().0,
                allocation.to_glib_none_mut().0,
            );
            allocation
        }
    }

    fn ancestor(&self, widget_type: glib::types::Type) -> Option<Widget> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_ancestor(
                self.as_ref().to_glib_none().0,
                widget_type.into_glib(),
            ))
        }
    }

    fn can_focus(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_can_focus(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn can_target(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_can_target(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn is_child_visible(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_child_visible(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn clipboard(&self) -> gdk::Clipboard {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_clipboard(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn css_classes(&self) -> Vec<glib::GString> {
        unsafe {
            FromGlibPtrContainer::from_glib_full(ffi::gtk_widget_get_css_classes(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn css_name(&self) -> glib::GString {
        unsafe { from_glib_none(ffi::gtk_widget_get_css_name(self.as_ref().to_glib_none().0)) }
    }

    fn cursor(&self) -> Option<gdk::Cursor> {
        unsafe { from_glib_none(ffi::gtk_widget_get_cursor(self.as_ref().to_glib_none().0)) }
    }

    fn direction(&self) -> TextDirection {
        unsafe {
            from_glib(ffi::gtk_widget_get_direction(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn display(&self) -> gdk::Display {
        unsafe { from_glib_none(ffi::gtk_widget_get_display(self.as_ref().to_glib_none().0)) }
    }

    fn first_child(&self) -> Option<Widget> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_first_child(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn focus_child(&self) -> Option<Widget> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_focus_child(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn gets_focus_on_click(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_focus_on_click(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn is_focusable(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_focusable(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn font_map(&self) -> Option<pango::FontMap> {
        unsafe { from_glib_none(ffi::gtk_widget_get_font_map(self.as_ref().to_glib_none().0)) }
    }

    fn font_options(&self) -> Option<cairo::FontOptions> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_font_options(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn frame_clock(&self) -> Option<gdk::FrameClock> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_frame_clock(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn halign(&self) -> Align {
        unsafe { from_glib(ffi::gtk_widget_get_halign(self.as_ref().to_glib_none().0)) }
    }

    fn has_tooltip(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_has_tooltip(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn height(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_height(self.as_ref().to_glib_none().0) }
    }

    fn hexpands(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_get_hexpand(self.as_ref().to_glib_none().0)) }
    }

    fn is_hexpand_set(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_hexpand_set(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn last_child(&self) -> Option<Widget> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_last_child(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn layout_manager(&self) -> Option<LayoutManager> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_layout_manager(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn is_mapped(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_get_mapped(self.as_ref().to_glib_none().0)) }
    }

    fn margin_bottom(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_margin_bottom(self.as_ref().to_glib_none().0) }
    }

    fn margin_end(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_margin_end(self.as_ref().to_glib_none().0) }
    }

    fn margin_start(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_margin_start(self.as_ref().to_glib_none().0) }
    }

    fn margin_top(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_margin_top(self.as_ref().to_glib_none().0) }
    }

    fn widget_name(&self) -> glib::GString {
        unsafe { from_glib_none(ffi::gtk_widget_get_name(self.as_ref().to_glib_none().0)) }
    }

    fn native(&self) -> Option<Native> {
        unsafe { from_glib_none(ffi::gtk_widget_get_native(self.as_ref().to_glib_none().0)) }
    }

    fn next_sibling(&self) -> Option<Widget> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_next_sibling(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn opacity(&self) -> f64 {
        unsafe { ffi::gtk_widget_get_opacity(self.as_ref().to_glib_none().0) }
    }

    fn overflow(&self) -> Overflow {
        unsafe { from_glib(ffi::gtk_widget_get_overflow(self.as_ref().to_glib_none().0)) }
    }

    fn pango_context(&self) -> pango::Context {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_pango_context(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn parent(&self) -> Option<Widget> {
        unsafe { from_glib_none(ffi::gtk_widget_get_parent(self.as_ref().to_glib_none().0)) }
    }

    fn preferred_size(&self) -> (Requisition, Requisition) {
        unsafe {
            let mut minimum_size = Requisition::uninitialized();
            let mut natural_size = Requisition::uninitialized();
            ffi::gtk_widget_get_preferred_size(
                self.as_ref().to_glib_none().0,
                minimum_size.to_glib_none_mut().0,
                natural_size.to_glib_none_mut().0,
            );
            (minimum_size, natural_size)
        }
    }

    fn prev_sibling(&self) -> Option<Widget> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_prev_sibling(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn primary_clipboard(&self) -> gdk::Clipboard {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_primary_clipboard(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn is_realized(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_get_realized(self.as_ref().to_glib_none().0)) }
    }

    fn receives_default(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_receives_default(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn request_mode(&self) -> SizeRequestMode {
        unsafe {
            from_glib(ffi::gtk_widget_get_request_mode(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn root(&self) -> Option<Root> {
        unsafe { from_glib_none(ffi::gtk_widget_get_root(self.as_ref().to_glib_none().0)) }
    }

    fn scale_factor(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_scale_factor(self.as_ref().to_glib_none().0) }
    }

    fn get_sensitive(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_sensitive(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn settings(&self) -> Settings {
        unsafe { from_glib_none(ffi::gtk_widget_get_settings(self.as_ref().to_glib_none().0)) }
    }

    fn size(&self, orientation: Orientation) -> i32 {
        unsafe { ffi::gtk_widget_get_size(self.as_ref().to_glib_none().0, orientation.into_glib()) }
    }

    fn size_request(&self) -> (i32, i32) {
        unsafe {
            let mut width = mem::MaybeUninit::uninit();
            let mut height = mem::MaybeUninit::uninit();
            ffi::gtk_widget_get_size_request(
                self.as_ref().to_glib_none().0,
                width.as_mut_ptr(),
                height.as_mut_ptr(),
            );
            let width = width.assume_init();
            let height = height.assume_init();
            (width, height)
        }
    }

    fn state_flags(&self) -> StateFlags {
        unsafe {
            from_glib(ffi::gtk_widget_get_state_flags(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn style_context(&self) -> StyleContext {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_style_context(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn template_child(&self, widget_type: glib::types::Type, name: &str) -> Option<glib::Object> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_template_child(
                self.as_ref().to_glib_none().0,
                widget_type.into_glib(),
                name.to_glib_none().0,
            ))
        }
    }

    fn tooltip_markup(&self) -> Option<glib::GString> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_tooltip_markup(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn tooltip_text(&self) -> Option<glib::GString> {
        unsafe {
            from_glib_none(ffi::gtk_widget_get_tooltip_text(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn valign(&self) -> Align {
        unsafe { from_glib(ffi::gtk_widget_get_valign(self.as_ref().to_glib_none().0)) }
    }

    fn vexpands(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_get_vexpand(self.as_ref().to_glib_none().0)) }
    }

    fn is_vexpand_set(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_get_vexpand_set(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn get_visible(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_get_visible(self.as_ref().to_glib_none().0)) }
    }

    fn width(&self) -> i32 {
        unsafe { ffi::gtk_widget_get_width(self.as_ref().to_glib_none().0) }
    }

    fn grab_focus(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_grab_focus(self.as_ref().to_glib_none().0)) }
    }

    fn has_css_class(&self, css_class: &str) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_has_css_class(
                self.as_ref().to_glib_none().0,
                css_class.to_glib_none().0,
            ))
        }
    }

    fn has_default(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_has_default(self.as_ref().to_glib_none().0)) }
    }

    fn has_focus(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_has_focus(self.as_ref().to_glib_none().0)) }
    }

    fn has_visible_focus(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_has_visible_focus(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn hide(&self) {
        unsafe {
            ffi::gtk_widget_hide(self.as_ref().to_glib_none().0);
        }
    }

    fn in_destruction(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_in_destruction(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn init_template(&self) {
        unsafe {
            ffi::gtk_widget_init_template(self.as_ref().to_glib_none().0);
        }
    }

    fn insert_action_group<P: IsA<gio::ActionGroup>>(&self, name: &str, group: Option<&P>) {
        unsafe {
            ffi::gtk_widget_insert_action_group(
                self.as_ref().to_glib_none().0,
                name.to_glib_none().0,
                group.map(|p| p.as_ref()).to_glib_none().0,
            );
        }
    }

    fn insert_after<P: IsA<Widget>, Q: IsA<Widget>>(
        &self,
        parent: &P,
        previous_sibling: Option<&Q>,
    ) {
        unsafe {
            ffi::gtk_widget_insert_after(
                self.as_ref().to_glib_none().0,
                parent.as_ref().to_glib_none().0,
                previous_sibling.map(|p| p.as_ref()).to_glib_none().0,
            );
        }
    }

    fn insert_before<P: IsA<Widget>, Q: IsA<Widget>>(&self, parent: &P, next_sibling: Option<&Q>) {
        unsafe {
            ffi::gtk_widget_insert_before(
                self.as_ref().to_glib_none().0,
                parent.as_ref().to_glib_none().0,
                next_sibling.map(|p| p.as_ref()).to_glib_none().0,
            );
        }
    }

    fn is_ancestor<P: IsA<Widget>>(&self, ancestor: &P) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_is_ancestor(
                self.as_ref().to_glib_none().0,
                ancestor.as_ref().to_glib_none().0,
            ))
        }
    }

    fn is_drawable(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_is_drawable(self.as_ref().to_glib_none().0)) }
    }

    fn is_focus(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_is_focus(self.as_ref().to_glib_none().0)) }
    }

    fn is_sensitive(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_is_sensitive(self.as_ref().to_glib_none().0)) }
    }

    fn is_visible(&self) -> bool {
        unsafe { from_glib(ffi::gtk_widget_is_visible(self.as_ref().to_glib_none().0)) }
    }

    fn keynav_failed(&self, direction: DirectionType) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_keynav_failed(
                self.as_ref().to_glib_none().0,
                direction.into_glib(),
            ))
        }
    }

    fn list_mnemonic_labels(&self) -> Vec<Widget> {
        unsafe {
            FromGlibPtrContainer::from_glib_container(ffi::gtk_widget_list_mnemonic_labels(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn map(&self) {
        unsafe {
            ffi::gtk_widget_map(self.as_ref().to_glib_none().0);
        }
    }

    fn measure(&self, orientation: Orientation, for_size: i32) -> (i32, i32, i32, i32) {
        unsafe {
            let mut minimum = mem::MaybeUninit::uninit();
            let mut natural = mem::MaybeUninit::uninit();
            let mut minimum_baseline = mem::MaybeUninit::uninit();
            let mut natural_baseline = mem::MaybeUninit::uninit();
            ffi::gtk_widget_measure(
                self.as_ref().to_glib_none().0,
                orientation.into_glib(),
                for_size,
                minimum.as_mut_ptr(),
                natural.as_mut_ptr(),
                minimum_baseline.as_mut_ptr(),
                natural_baseline.as_mut_ptr(),
            );
            let minimum = minimum.assume_init();
            let natural = natural.assume_init();
            let minimum_baseline = minimum_baseline.assume_init();
            let natural_baseline = natural_baseline.assume_init();
            (minimum, natural, minimum_baseline, natural_baseline)
        }
    }

    fn mnemonic_activate(&self, group_cycling: bool) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_mnemonic_activate(
                self.as_ref().to_glib_none().0,
                group_cycling.into_glib(),
            ))
        }
    }

    fn observe_children(&self) -> gio::ListModel {
        unsafe {
            from_glib_full(ffi::gtk_widget_observe_children(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn observe_controllers(&self) -> gio::ListModel {
        unsafe {
            from_glib_full(ffi::gtk_widget_observe_controllers(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn pick(&self, x: f64, y: f64, flags: PickFlags) -> Option<Widget> {
        unsafe {
            from_glib_none(ffi::gtk_widget_pick(
                self.as_ref().to_glib_none().0,
                x,
                y,
                flags.into_glib(),
            ))
        }
    }

    fn queue_allocate(&self) {
        unsafe {
            ffi::gtk_widget_queue_allocate(self.as_ref().to_glib_none().0);
        }
    }

    fn queue_draw(&self) {
        unsafe {
            ffi::gtk_widget_queue_draw(self.as_ref().to_glib_none().0);
        }
    }

    fn queue_resize(&self) {
        unsafe {
            ffi::gtk_widget_queue_resize(self.as_ref().to_glib_none().0);
        }
    }

    fn realize(&self) {
        unsafe {
            ffi::gtk_widget_realize(self.as_ref().to_glib_none().0);
        }
    }

    fn remove_controller<P: IsA<EventController>>(&self, controller: &P) {
        unsafe {
            ffi::gtk_widget_remove_controller(
                self.as_ref().to_glib_none().0,
                controller.as_ref().to_glib_none().0,
            );
        }
    }

    fn remove_css_class(&self, css_class: &str) {
        unsafe {
            ffi::gtk_widget_remove_css_class(
                self.as_ref().to_glib_none().0,
                css_class.to_glib_none().0,
            );
        }
    }

    fn remove_mnemonic_label<P: IsA<Widget>>(&self, label: &P) {
        unsafe {
            ffi::gtk_widget_remove_mnemonic_label(
                self.as_ref().to_glib_none().0,
                label.as_ref().to_glib_none().0,
            );
        }
    }

    fn set_can_focus(&self, can_focus: bool) {
        unsafe {
            ffi::gtk_widget_set_can_focus(self.as_ref().to_glib_none().0, can_focus.into_glib());
        }
    }

    fn set_can_target(&self, can_target: bool) {
        unsafe {
            ffi::gtk_widget_set_can_target(self.as_ref().to_glib_none().0, can_target.into_glib());
        }
    }

    fn set_child_visible(&self, child_visible: bool) {
        unsafe {
            ffi::gtk_widget_set_child_visible(
                self.as_ref().to_glib_none().0,
                child_visible.into_glib(),
            );
        }
    }

    fn set_css_classes(&self, classes: &[&str]) {
        unsafe {
            ffi::gtk_widget_set_css_classes(
                self.as_ref().to_glib_none().0,
                classes.to_glib_none().0,
            );
        }
    }

    fn set_cursor(&self, cursor: Option<&gdk::Cursor>) {
        unsafe {
            ffi::gtk_widget_set_cursor(self.as_ref().to_glib_none().0, cursor.to_glib_none().0);
        }
    }

    fn set_cursor_from_name(&self, name: Option<&str>) {
        unsafe {
            ffi::gtk_widget_set_cursor_from_name(
                self.as_ref().to_glib_none().0,
                name.to_glib_none().0,
            );
        }
    }

    fn set_direction(&self, dir: TextDirection) {
        unsafe {
            ffi::gtk_widget_set_direction(self.as_ref().to_glib_none().0, dir.into_glib());
        }
    }

    fn set_focus_child<P: IsA<Widget>>(&self, child: Option<&P>) {
        unsafe {
            ffi::gtk_widget_set_focus_child(
                self.as_ref().to_glib_none().0,
                child.map(|p| p.as_ref()).to_glib_none().0,
            );
        }
    }

    fn set_focus_on_click(&self, focus_on_click: bool) {
        unsafe {
            ffi::gtk_widget_set_focus_on_click(
                self.as_ref().to_glib_none().0,
                focus_on_click.into_glib(),
            );
        }
    }

    fn set_focusable(&self, focusable: bool) {
        unsafe {
            ffi::gtk_widget_set_focusable(self.as_ref().to_glib_none().0, focusable.into_glib());
        }
    }

    fn set_font_map<P: IsA<pango::FontMap>>(&self, font_map: Option<&P>) {
        unsafe {
            ffi::gtk_widget_set_font_map(
                self.as_ref().to_glib_none().0,
                font_map.map(|p| p.as_ref()).to_glib_none().0,
            );
        }
    }

    fn set_font_options(&self, options: Option<&cairo::FontOptions>) {
        unsafe {
            ffi::gtk_widget_set_font_options(
                self.as_ref().to_glib_none().0,
                options.to_glib_none().0,
            );
        }
    }

    fn set_halign(&self, align: Align) {
        unsafe {
            ffi::gtk_widget_set_halign(self.as_ref().to_glib_none().0, align.into_glib());
        }
    }

    fn set_has_tooltip(&self, has_tooltip: bool) {
        unsafe {
            ffi::gtk_widget_set_has_tooltip(
                self.as_ref().to_glib_none().0,
                has_tooltip.into_glib(),
            );
        }
    }

    fn set_hexpand(&self, expand: bool) {
        unsafe {
            ffi::gtk_widget_set_hexpand(self.as_ref().to_glib_none().0, expand.into_glib());
        }
    }

    fn set_hexpand_set(&self, set: bool) {
        unsafe {
            ffi::gtk_widget_set_hexpand_set(self.as_ref().to_glib_none().0, set.into_glib());
        }
    }

    fn set_layout_manager<P: IsA<LayoutManager>>(&self, layout_manager: Option<&P>) {
        unsafe {
            ffi::gtk_widget_set_layout_manager(
                self.as_ref().to_glib_none().0,
                layout_manager.map(|p| p.as_ref()).to_glib_full(),
            );
        }
    }

    fn set_margin_bottom(&self, margin: i32) {
        unsafe {
            ffi::gtk_widget_set_margin_bottom(self.as_ref().to_glib_none().0, margin);
        }
    }

    fn set_margin_end(&self, margin: i32) {
        unsafe {
            ffi::gtk_widget_set_margin_end(self.as_ref().to_glib_none().0, margin);
        }
    }

    fn set_margin_start(&self, margin: i32) {
        unsafe {
            ffi::gtk_widget_set_margin_start(self.as_ref().to_glib_none().0, margin);
        }
    }

    fn set_margin_top(&self, margin: i32) {
        unsafe {
            ffi::gtk_widget_set_margin_top(self.as_ref().to_glib_none().0, margin);
        }
    }

    fn set_widget_name(&self, name: &str) {
        unsafe {
            ffi::gtk_widget_set_name(self.as_ref().to_glib_none().0, name.to_glib_none().0);
        }
    }

    fn set_opacity(&self, opacity: f64) {
        unsafe {
            ffi::gtk_widget_set_opacity(self.as_ref().to_glib_none().0, opacity);
        }
    }

    fn set_overflow(&self, overflow: Overflow) {
        unsafe {
            ffi::gtk_widget_set_overflow(self.as_ref().to_glib_none().0, overflow.into_glib());
        }
    }

    fn set_parent<P: IsA<Widget>>(&self, parent: &P) {
        unsafe {
            ffi::gtk_widget_set_parent(
                self.as_ref().to_glib_none().0,
                parent.as_ref().to_glib_none().0,
            );
        }
    }

    fn set_receives_default(&self, receives_default: bool) {
        unsafe {
            ffi::gtk_widget_set_receives_default(
                self.as_ref().to_glib_none().0,
                receives_default.into_glib(),
            );
        }
    }

    fn set_sensitive(&self, sensitive: bool) {
        unsafe {
            ffi::gtk_widget_set_sensitive(self.as_ref().to_glib_none().0, sensitive.into_glib());
        }
    }

    fn set_size_request(&self, width: i32, height: i32) {
        unsafe {
            ffi::gtk_widget_set_size_request(self.as_ref().to_glib_none().0, width, height);
        }
    }

    fn set_state_flags(&self, flags: StateFlags, clear: bool) {
        unsafe {
            ffi::gtk_widget_set_state_flags(
                self.as_ref().to_glib_none().0,
                flags.into_glib(),
                clear.into_glib(),
            );
        }
    }

    fn set_tooltip_markup(&self, markup: Option<&str>) {
        unsafe {
            ffi::gtk_widget_set_tooltip_markup(
                self.as_ref().to_glib_none().0,
                markup.to_glib_none().0,
            );
        }
    }

    fn set_tooltip_text(&self, text: Option<&str>) {
        unsafe {
            ffi::gtk_widget_set_tooltip_text(self.as_ref().to_glib_none().0, text.to_glib_none().0);
        }
    }

    fn set_valign(&self, align: Align) {
        unsafe {
            ffi::gtk_widget_set_valign(self.as_ref().to_glib_none().0, align.into_glib());
        }
    }

    fn set_vexpand(&self, expand: bool) {
        unsafe {
            ffi::gtk_widget_set_vexpand(self.as_ref().to_glib_none().0, expand.into_glib());
        }
    }

    fn set_vexpand_set(&self, set: bool) {
        unsafe {
            ffi::gtk_widget_set_vexpand_set(self.as_ref().to_glib_none().0, set.into_glib());
        }
    }

    fn set_visible(&self, visible: bool) {
        unsafe {
            ffi::gtk_widget_set_visible(self.as_ref().to_glib_none().0, visible.into_glib());
        }
    }

    fn should_layout(&self) -> bool {
        unsafe {
            from_glib(ffi::gtk_widget_should_layout(
                self.as_ref().to_glib_none().0,
            ))
        }
    }

    fn show(&self) {
        unsafe {
            ffi::gtk_widget_show(self.as_ref().to_glib_none().0);
        }
    }

    fn size_allocate(&self, allocation: &Allocation, baseline: i32) {
        unsafe {
            ffi::gtk_widget_size_allocate(
                self.as_ref().to_glib_none().0,
                allocation.to_glib_none().0,
                baseline,
            );
        }
    }

    fn snapshot_child<P: IsA<Widget>>(&self, child: &P, snapshot: &Snapshot) {
        unsafe {
            ffi::gtk_widget_snapshot_child(
                self.as_ref().to_glib_none().0,
                child.as_ref().to_glib_none().0,
                snapshot.to_glib_none().0,
            );
        }
    }

    fn translate_coordinates<P: IsA<Widget>>(
        &self,
        dest_widget: &P,
        src_x: f64,
        src_y: f64,
    ) -> Option<(f64, f64)> {
        unsafe {
            let mut dest_x = mem::MaybeUninit::uninit();
            let mut dest_y = mem::MaybeUninit::uninit();
            let ret = from_glib(ffi::gtk_widget_translate_coordinates(
                self.as_ref().to_glib_none().0,
                dest_widget.as_ref().to_glib_none().0,
                src_x,
                src_y,
                dest_x.as_mut_ptr(),
                dest_y.as_mut_ptr(),
            ));
            let dest_x = dest_x.assume_init();
            let dest_y = dest_y.assume_init();
            if ret {
                Some((dest_x, dest_y))
            } else {
                None
            }
        }
    }

    fn trigger_tooltip_query(&self) {
        unsafe {
            ffi::gtk_widget_trigger_tooltip_query(self.as_ref().to_glib_none().0);
        }
    }

    fn unmap(&self) {
        unsafe {
            ffi::gtk_widget_unmap(self.as_ref().to_glib_none().0);
        }
    }

    fn unparent(&self) {
        unsafe {
            ffi::gtk_widget_unparent(self.as_ref().to_glib_none().0);
        }
    }

    fn unrealize(&self) {
        unsafe {
            ffi::gtk_widget_unrealize(self.as_ref().to_glib_none().0);
        }
    }

    fn unset_state_flags(&self, flags: StateFlags) {
        unsafe {
            ffi::gtk_widget_unset_state_flags(self.as_ref().to_glib_none().0, flags.into_glib());
        }
    }

    fn height_request(&self) -> i32 {
        unsafe {
            let mut value = glib::Value::from_type(<i32 as StaticType>::static_type());
            glib::gobject_ffi::g_object_get_property(
                self.to_glib_none().0 as *mut glib::gobject_ffi::GObject,
                b"height-request\0".as_ptr() as *const _,
                value.to_glib_none_mut().0,
            );
            value
                .get()
                .expect("Return Value for property `height-request` getter")
        }
    }

    fn set_height_request(&self, height_request: i32) {
        unsafe {
            glib::gobject_ffi::g_object_set_property(
                self.to_glib_none().0 as *mut glib::gobject_ffi::GObject,
                b"height-request\0".as_ptr() as *const _,
                height_request.to_value().to_glib_none().0,
            );
        }
    }

    fn width_request(&self) -> i32 {
        unsafe {
            let mut value = glib::Value::from_type(<i32 as StaticType>::static_type());
            glib::gobject_ffi::g_object_get_property(
                self.to_glib_none().0 as *mut glib::gobject_ffi::GObject,
                b"width-request\0".as_ptr() as *const _,
                value.to_glib_none_mut().0,
            );
            value
                .get()
                .expect("Return Value for property `width-request` getter")
        }
    }

    fn set_width_request(&self, width_request: i32) {
        unsafe {
            glib::gobject_ffi::g_object_set_property(
                self.to_glib_none().0 as *mut glib::gobject_ffi::GObject,
                b"width-request\0".as_ptr() as *const _,
                width_request.to_value().to_glib_none().0,
            );
        }
    }

    fn connect_destroy<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn destroy_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"destroy\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    destroy_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_direction_changed<F: Fn(&Self, TextDirection) + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId {
        unsafe extern "C" fn direction_changed_trampoline<
            P: IsA<Widget>,
            F: Fn(&P, TextDirection) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            previous_direction: ffi::GtkTextDirection,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(
                Widget::from_glib_borrow(this).unsafe_cast_ref(),
                from_glib(previous_direction),
            )
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"direction-changed\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    direction_changed_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_hide<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn hide_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"hide\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    hide_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_keynav_failed<F: Fn(&Self, DirectionType) -> glib::signal::Inhibit + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId {
        unsafe extern "C" fn keynav_failed_trampoline<
            P: IsA<Widget>,
            F: Fn(&P, DirectionType) -> glib::signal::Inhibit + 'static,
        >(
            this: *mut ffi::GtkWidget,
            direction: ffi::GtkDirectionType,
            f: glib::ffi::gpointer,
        ) -> glib::ffi::gboolean {
            let f: &F = &*(f as *const F);
            f(
                Widget::from_glib_borrow(this).unsafe_cast_ref(),
                from_glib(direction),
            )
            .into_glib()
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"keynav-failed\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    keynav_failed_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_map<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn map_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"map\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    map_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_mnemonic_activate<F: Fn(&Self, bool) -> glib::signal::Inhibit + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId {
        unsafe extern "C" fn mnemonic_activate_trampoline<
            P: IsA<Widget>,
            F: Fn(&P, bool) -> glib::signal::Inhibit + 'static,
        >(
            this: *mut ffi::GtkWidget,
            group_cycling: glib::ffi::gboolean,
            f: glib::ffi::gpointer,
        ) -> glib::ffi::gboolean {
            let f: &F = &*(f as *const F);
            f(
                Widget::from_glib_borrow(this).unsafe_cast_ref(),
                from_glib(group_cycling),
            )
            .into_glib()
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"mnemonic-activate\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    mnemonic_activate_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_move_focus<F: Fn(&Self, DirectionType) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn move_focus_trampoline<
            P: IsA<Widget>,
            F: Fn(&P, DirectionType) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            direction: ffi::GtkDirectionType,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(
                Widget::from_glib_borrow(this).unsafe_cast_ref(),
                from_glib(direction),
            )
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"move-focus\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    move_focus_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn emit_move_focus(&self, direction: DirectionType) {
        let _ = unsafe {
            glib::Object::from_glib_borrow(self.as_ptr() as *mut glib::gobject_ffi::GObject)
                .emit_by_name("move-focus", &[&direction])
                .unwrap()
        };
    }

    fn connect_query_tooltip<F: Fn(&Self, i32, i32, bool, &Tooltip) -> bool + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId {
        unsafe extern "C" fn query_tooltip_trampoline<
            P: IsA<Widget>,
            F: Fn(&P, i32, i32, bool, &Tooltip) -> bool + 'static,
        >(
            this: *mut ffi::GtkWidget,
            x: libc::c_int,
            y: libc::c_int,
            keyboard_mode: glib::ffi::gboolean,
            tooltip: *mut ffi::GtkTooltip,
            f: glib::ffi::gpointer,
        ) -> glib::ffi::gboolean {
            let f: &F = &*(f as *const F);
            f(
                Widget::from_glib_borrow(this).unsafe_cast_ref(),
                x,
                y,
                from_glib(keyboard_mode),
                &from_glib_borrow(tooltip),
            )
            .into_glib()
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"query-tooltip\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    query_tooltip_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_realize<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn realize_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"realize\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    realize_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_show<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn show_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"show\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    show_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_state_flags_changed<F: Fn(&Self, StateFlags) + 'static>(
        &self,
        f: F,
    ) -> SignalHandlerId {
        unsafe extern "C" fn state_flags_changed_trampoline<
            P: IsA<Widget>,
            F: Fn(&P, StateFlags) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            flags: ffi::GtkStateFlags,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(
                Widget::from_glib_borrow(this).unsafe_cast_ref(),
                from_glib(flags),
            )
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"state-flags-changed\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    state_flags_changed_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_unmap<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn unmap_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"unmap\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    unmap_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_unrealize<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn unrealize_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"unrealize\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    unrealize_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_can_focus_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_can_focus_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::can-focus\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_can_focus_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_can_target_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_can_target_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::can-target\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_can_target_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_css_classes_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_css_classes_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::css-classes\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_css_classes_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_cursor_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_cursor_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::cursor\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_cursor_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_focus_on_click_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_focus_on_click_trampoline<
            P: IsA<Widget>,
            F: Fn(&P) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::focus-on-click\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_focus_on_click_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_focusable_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_focusable_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::focusable\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_focusable_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_halign_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_halign_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::halign\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_halign_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_has_default_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_has_default_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::has-default\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_has_default_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_has_focus_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_has_focus_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::has-focus\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_has_focus_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_has_tooltip_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_has_tooltip_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::has-tooltip\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_has_tooltip_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_height_request_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_height_request_trampoline<
            P: IsA<Widget>,
            F: Fn(&P) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::height-request\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_height_request_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_hexpand_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_hexpand_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::hexpand\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_hexpand_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_hexpand_set_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_hexpand_set_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::hexpand-set\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_hexpand_set_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_layout_manager_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_layout_manager_trampoline<
            P: IsA<Widget>,
            F: Fn(&P) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::layout-manager\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_layout_manager_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_margin_bottom_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_margin_bottom_trampoline<
            P: IsA<Widget>,
            F: Fn(&P) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::margin-bottom\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_margin_bottom_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_margin_end_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_margin_end_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::margin-end\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_margin_end_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_margin_start_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_margin_start_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::margin-start\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_margin_start_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_margin_top_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_margin_top_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::margin-top\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_margin_top_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_name_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_name_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::name\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_name_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_opacity_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_opacity_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::opacity\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_opacity_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_overflow_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_overflow_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::overflow\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_overflow_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_parent_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_parent_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::parent\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_parent_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_receives_default_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_receives_default_trampoline<
            P: IsA<Widget>,
            F: Fn(&P) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::receives-default\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_receives_default_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_root_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_root_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::root\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_root_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_scale_factor_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_scale_factor_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::scale-factor\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_scale_factor_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_sensitive_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_sensitive_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::sensitive\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_sensitive_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_tooltip_markup_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_tooltip_markup_trampoline<
            P: IsA<Widget>,
            F: Fn(&P) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::tooltip-markup\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_tooltip_markup_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_tooltip_text_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_tooltip_text_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::tooltip-text\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_tooltip_text_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_valign_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_valign_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::valign\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_valign_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_vexpand_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_vexpand_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::vexpand\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_vexpand_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_vexpand_set_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_vexpand_set_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::vexpand-set\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_vexpand_set_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_visible_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_visible_trampoline<P: IsA<Widget>, F: Fn(&P) + 'static>(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::visible\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_visible_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }

    fn connect_width_request_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
        unsafe extern "C" fn notify_width_request_trampoline<
            P: IsA<Widget>,
            F: Fn(&P) + 'static,
        >(
            this: *mut ffi::GtkWidget,
            _param_spec: glib::ffi::gpointer,
            f: glib::ffi::gpointer,
        ) {
            let f: &F = &*(f as *const F);
            f(Widget::from_glib_borrow(this).unsafe_cast_ref())
        }
        unsafe {
            let f: Box_<F> = Box_::new(f);
            connect_raw(
                self.as_ptr() as *mut _,
                b"notify::width-request\0".as_ptr() as *const _,
                Some(transmute::<_, unsafe extern "C" fn()>(
                    notify_width_request_trampoline::<Self, F> as *const (),
                )),
                Box_::into_raw(f),
            )
        }
    }
}