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// This file was generated by gir (https://github.com/gtk-rs/gir)
// from gir-files (https://github.com/gtk-rs/gir-files)
// DO NOT EDIT
use glib::object::Cast;
use glib::object::IsA;
use glib::signal::connect_raw;
use glib::signal::SignalHandlerId;
use glib::translate::*;
use std::boxed::Box as Box_;
use std::fmt;
use std::mem::transmute;
use std::ptr;
glib::wrapper! {
/// [`Action`][crate::Action] represents a single named action.
///
/// The main interface to an action is that it can be activated with
/// [`ActionExt::activate()`][crate::prelude::ActionExt::activate()]. This results in the 'activate' signal being
/// emitted. An activation has a [`glib::Variant`][struct@crate::glib::Variant] parameter (which may be
/// [`None`]). The correct type for the parameter is determined by a static
/// parameter type (which is given at construction time).
///
/// An action may optionally have a state, in which case the state may be
/// set with [`ActionExt::change_state()`][crate::prelude::ActionExt::change_state()]. This call takes a [`glib::Variant`][struct@crate::glib::Variant]. The
/// correct type for the state is determined by a static state type
/// (which is given at construction time).
///
/// The state may have a hint associated with it, specifying its valid
/// range.
///
/// [`Action`][crate::Action] is merely the interface to the concept of an action, as
/// described above. Various implementations of actions exist, including
/// [`SimpleAction`][crate::SimpleAction].
///
/// In all cases, the implementing class is responsible for storing the
/// name of the action, the parameter type, the enabled state, the
/// optional state type and the state and emitting the appropriate
/// signals when these change. The implementor is responsible for filtering
/// calls to [`ActionExt::activate()`][crate::prelude::ActionExt::activate()] and [`ActionExt::change_state()`][crate::prelude::ActionExt::change_state()] for type
/// safety and for the state being enabled.
///
/// Probably the only useful thing to do with a [`Action`][crate::Action] is to put it
/// inside of a [`SimpleActionGroup`][crate::SimpleActionGroup].
///
/// # Implements
///
/// [`ActionExt`][trait@crate::prelude::ActionExt]
#[doc(alias = "GAction")]
pub struct Action(Interface<ffi::GAction, ffi::GActionInterface>);
match fn {
type_ => || ffi::g_action_get_type(),
}
}
impl Action {
pub const NONE: Option<&'static Action> = None;
/// Checks if `action_name` is valid.
///
/// `action_name` is valid if it consists only of alphanumeric characters,
/// plus '-' and '.'. The empty string is not a valid action name.
///
/// It is an error to call this function with a non-utf8 `action_name`.
/// `action_name` must not be [`None`].
/// ## `action_name`
/// a potential action name
///
/// # Returns
///
/// [`true`] if `action_name` is valid
#[doc(alias = "g_action_name_is_valid")]
pub fn name_is_valid(action_name: &str) -> bool {
unsafe { from_glib(ffi::g_action_name_is_valid(action_name.to_glib_none().0)) }
}
/// Parses a detailed action name into its separate name and target
/// components.
///
/// Detailed action names can have three formats.
///
/// The first format is used to represent an action name with no target
/// value and consists of just an action name containing no whitespace
/// nor the characters ':', '(' or ')'. For example: "app.action".
///
/// The second format is used to represent an action with a target value
/// that is a non-empty string consisting only of alphanumerics, plus '-'
/// and '.'. In that case, the action name and target value are
/// separated by a double colon ("::"). For example:
/// "app.action::target".
///
/// The third format is used to represent an action with any type of
/// target value, including strings. The target value follows the action
/// name, surrounded in parens. For example: "app.action(42)". The
/// target value is parsed using `g_variant_parse()`. If a tuple-typed
/// value is desired, it must be specified in the same way, resulting in
/// two sets of parens, for example: "app.action((1,2,3))". A string
/// target can be specified this way as well: "app.action('target')".
/// For strings, this third format must be used if * target value is
/// empty or contains characters other than alphanumerics, '-' and '.'.
/// ## `detailed_name`
/// a detailed action name
///
/// # Returns
///
/// [`true`] if successful, else [`false`] with `error` set
///
/// ## `action_name`
/// the action name
///
/// ## `target_value`
/// the target value, or [`None`] for no target
#[doc(alias = "g_action_parse_detailed_name")]
pub fn parse_detailed_name(
detailed_name: &str,
) -> Result<(glib::GString, glib::Variant), glib::Error> {
unsafe {
let mut action_name = ptr::null_mut();
let mut target_value = ptr::null_mut();
let mut error = ptr::null_mut();
let is_ok = ffi::g_action_parse_detailed_name(
detailed_name.to_glib_none().0,
&mut action_name,
&mut target_value,
&mut error,
);
assert_eq!(is_ok == glib::ffi::GFALSE, !error.is_null());
if error.is_null() {
Ok((from_glib_full(action_name), from_glib_full(target_value)))
} else {
Err(from_glib_full(error))
}
}
}
/// Formats a detailed action name from `action_name` and `target_value`.
///
/// It is an error to call this function with an invalid action name.
///
/// This function is the opposite of [`parse_detailed_name()`][Self::parse_detailed_name()].
/// It will produce a string that can be parsed back to the `action_name`
/// and `target_value` by that function.
///
/// See that function for the types of strings that will be printed by
/// this function.
/// ## `action_name`
/// a valid action name
/// ## `target_value`
/// a [`glib::Variant`][struct@crate::glib::Variant] target value, or [`None`]
///
/// # Returns
///
/// a detailed format string
#[doc(alias = "g_action_print_detailed_name")]
pub fn print_detailed_name(
action_name: &str,
target_value: Option<&glib::Variant>,
) -> glib::GString {
unsafe {
from_glib_full(ffi::g_action_print_detailed_name(
action_name.to_glib_none().0,
target_value.to_glib_none().0,
))
}
}
}
/// Trait containing all [`struct@Action`] methods.
///
/// # Implementors
///
/// [`Action`][struct@crate::Action], [`PropertyAction`][struct@crate::PropertyAction], [`SimpleAction`][struct@crate::SimpleAction]
pub trait ActionExt: 'static {
/// Activates the action.
///
/// `parameter` must be the correct type of parameter for the action (ie:
/// the parameter type given at construction time). If the parameter
/// type was [`None`] then `parameter` must also be [`None`].
///
/// If the `parameter` GVariant is floating, it is consumed.
/// ## `parameter`
/// the parameter to the activation
#[doc(alias = "g_action_activate")]
fn activate(&self, parameter: Option<&glib::Variant>);
/// Request for the state of `self` to be changed to `value`.
///
/// The action must be stateful and `value` must be of the correct type.
/// See [`state_type()`][Self::state_type()].
///
/// This call merely requests a change. The action may refuse to change
/// its state or may change its state to something other than `value`.
/// See [`state_hint()`][Self::state_hint()].
///
/// If the `value` GVariant is floating, it is consumed.
/// ## `value`
/// the new state
#[doc(alias = "g_action_change_state")]
fn change_state(&self, value: &glib::Variant);
/// Checks if `self` is currently enabled.
///
/// An action must be enabled in order to be activated or in order to
/// have its state changed from outside callers.
///
/// # Returns
///
/// whether the action is enabled
#[doc(alias = "g_action_get_enabled")]
#[doc(alias = "get_enabled")]
fn is_enabled(&self) -> bool;
/// Queries the name of `self`.
///
/// # Returns
///
/// the name of the action
#[doc(alias = "g_action_get_name")]
#[doc(alias = "get_name")]
fn name(&self) -> glib::GString;
/// Queries the type of the parameter that must be given when activating
/// `self`.
///
/// When activating the action using [`activate()`][Self::activate()], the [`glib::Variant`][struct@crate::glib::Variant]
/// given to that function must be of the type returned by this function.
///
/// In the case that this function returns [`None`], you must not give any
/// [`glib::Variant`][struct@crate::glib::Variant], but [`None`] instead.
///
/// # Returns
///
/// the parameter type
#[doc(alias = "g_action_get_parameter_type")]
#[doc(alias = "get_parameter_type")]
fn parameter_type(&self) -> Option<glib::VariantType>;
/// Queries the current state of `self`.
///
/// If the action is not stateful then [`None`] will be returned. If the
/// action is stateful then the type of the return value is the type
/// given by [`state_type()`][Self::state_type()].
///
/// The return value (if non-[`None`]) should be freed with
/// `g_variant_unref()` when it is no longer required.
///
/// # Returns
///
/// the current state of the action
#[doc(alias = "g_action_get_state")]
#[doc(alias = "get_state")]
fn state(&self) -> Option<glib::Variant>;
/// Requests a hint about the valid range of values for the state of
/// `self`.
///
/// If [`None`] is returned it either means that the action is not stateful
/// or that there is no hint about the valid range of values for the
/// state of the action.
///
/// If a [`glib::Variant`][struct@crate::glib::Variant] array is returned then each item in the array is a
/// possible value for the state. If a [`glib::Variant`][struct@crate::glib::Variant] pair (ie: two-tuple) is
/// returned then the tuple specifies the inclusive lower and upper bound
/// of valid values for the state.
///
/// In any case, the information is merely a hint. It may be possible to
/// have a state value outside of the hinted range and setting a value
/// within the range may fail.
///
/// The return value (if non-[`None`]) should be freed with
/// `g_variant_unref()` when it is no longer required.
///
/// # Returns
///
/// the state range hint
#[doc(alias = "g_action_get_state_hint")]
#[doc(alias = "get_state_hint")]
fn state_hint(&self) -> Option<glib::Variant>;
/// Queries the type of the state of `self`.
///
/// If the action is stateful (e.g. created with
/// [`SimpleAction::new_stateful()`][crate::SimpleAction::new_stateful()]) then this function returns the
/// [`glib::VariantType`][crate::glib::VariantType] of the state. This is the type of the initial value
/// given as the state. All calls to [`change_state()`][Self::change_state()] must give a
/// [`glib::Variant`][struct@crate::glib::Variant] of this type and [`state()`][Self::state()] will return a
/// [`glib::Variant`][struct@crate::glib::Variant] of the same type.
///
/// If the action is not stateful (e.g. created with [`SimpleAction::new()`][crate::SimpleAction::new()])
/// then this function will return [`None`]. In that case, [`state()`][Self::state()]
/// will return [`None`] and you must not call [`change_state()`][Self::change_state()].
///
/// # Returns
///
/// the state type, if the action is stateful
#[doc(alias = "g_action_get_state_type")]
#[doc(alias = "get_state_type")]
fn state_type(&self) -> Option<glib::VariantType>;
#[doc(alias = "enabled")]
fn connect_enabled_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 = "parameter-type")]
fn connect_parameter_type_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;
#[doc(alias = "state")]
fn connect_state_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;
#[doc(alias = "state-type")]
fn connect_state_type_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId;
}
impl<O: IsA<Action>> ActionExt for O {
fn activate(&self, parameter: Option<&glib::Variant>) {
unsafe {
ffi::g_action_activate(self.as_ref().to_glib_none().0, parameter.to_glib_none().0);
}
}
fn change_state(&self, value: &glib::Variant) {
unsafe {
ffi::g_action_change_state(self.as_ref().to_glib_none().0, value.to_glib_none().0);
}
}
fn is_enabled(&self) -> bool {
unsafe { from_glib(ffi::g_action_get_enabled(self.as_ref().to_glib_none().0)) }
}
fn name(&self) -> glib::GString {
unsafe { from_glib_none(ffi::g_action_get_name(self.as_ref().to_glib_none().0)) }
}
fn parameter_type(&self) -> Option<glib::VariantType> {
unsafe {
from_glib_none(ffi::g_action_get_parameter_type(
self.as_ref().to_glib_none().0,
))
}
}
fn state(&self) -> Option<glib::Variant> {
unsafe { from_glib_full(ffi::g_action_get_state(self.as_ref().to_glib_none().0)) }
}
fn state_hint(&self) -> Option<glib::Variant> {
unsafe { from_glib_full(ffi::g_action_get_state_hint(self.as_ref().to_glib_none().0)) }
}
fn state_type(&self) -> Option<glib::VariantType> {
unsafe { from_glib_none(ffi::g_action_get_state_type(self.as_ref().to_glib_none().0)) }
}
fn connect_enabled_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
unsafe extern "C" fn notify_enabled_trampoline<P: IsA<Action>, F: Fn(&P) + 'static>(
this: *mut ffi::GAction,
_param_spec: glib::ffi::gpointer,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(Action::from_glib_borrow(this).unsafe_cast_ref())
}
unsafe {
let f: Box_<F> = Box_::new(f);
connect_raw(
self.as_ptr() as *mut _,
b"notify::enabled\0".as_ptr() as *const _,
Some(transmute::<_, unsafe extern "C" fn()>(
notify_enabled_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<Action>, F: Fn(&P) + 'static>(
this: *mut ffi::GAction,
_param_spec: glib::ffi::gpointer,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(Action::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_parameter_type_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
unsafe extern "C" fn notify_parameter_type_trampoline<
P: IsA<Action>,
F: Fn(&P) + 'static,
>(
this: *mut ffi::GAction,
_param_spec: glib::ffi::gpointer,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(Action::from_glib_borrow(this).unsafe_cast_ref())
}
unsafe {
let f: Box_<F> = Box_::new(f);
connect_raw(
self.as_ptr() as *mut _,
b"notify::parameter-type\0".as_ptr() as *const _,
Some(transmute::<_, unsafe extern "C" fn()>(
notify_parameter_type_trampoline::<Self, F> as *const (),
)),
Box_::into_raw(f),
)
}
}
fn connect_state_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
unsafe extern "C" fn notify_state_trampoline<P: IsA<Action>, F: Fn(&P) + 'static>(
this: *mut ffi::GAction,
_param_spec: glib::ffi::gpointer,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(Action::from_glib_borrow(this).unsafe_cast_ref())
}
unsafe {
let f: Box_<F> = Box_::new(f);
connect_raw(
self.as_ptr() as *mut _,
b"notify::state\0".as_ptr() as *const _,
Some(transmute::<_, unsafe extern "C" fn()>(
notify_state_trampoline::<Self, F> as *const (),
)),
Box_::into_raw(f),
)
}
}
fn connect_state_type_notify<F: Fn(&Self) + 'static>(&self, f: F) -> SignalHandlerId {
unsafe extern "C" fn notify_state_type_trampoline<P: IsA<Action>, F: Fn(&P) + 'static>(
this: *mut ffi::GAction,
_param_spec: glib::ffi::gpointer,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(Action::from_glib_borrow(this).unsafe_cast_ref())
}
unsafe {
let f: Box_<F> = Box_::new(f);
connect_raw(
self.as_ptr() as *mut _,
b"notify::state-type\0".as_ptr() as *const _,
Some(transmute::<_, unsafe extern "C" fn()>(
notify_state_type_trampoline::<Self, F> as *const (),
)),
Box_::into_raw(f),
)
}
}
}
impl fmt::Display for Action {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.write_str("Action")
}
}