Struct cosmic::iced_winit::graphics::futures::Subscription

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pub struct Subscription<T> { /* private fields */ }
Expand description

A request to listen to external events.

Besides performing async actions on demand with Task, most applications also need to listen to external events passively.

A Subscription is normally provided to some runtime, like a Task, and it will generate events as long as the user keeps requesting it.

For instance, you can use a Subscription to listen to a WebSocket connection, keyboard presses, mouse events, time ticks, etc.

§The Lifetime of a Subscription

Much like a Future or a Stream, a Subscription does not produce any effects on its own. For a Subscription to run, it must be returned to the iced runtime—normally in the subscription function of an application or a daemon.

When a Subscription is provided to the runtime for the first time, the runtime will start running it asynchronously. Running a Subscription consists in building its underlying Stream and executing it in an async runtime.

Therefore, you can think of a Subscription as a “stream builder”. It simply represents a way to build a certain Stream together with some way to identify it.

Identification is important because when a specific Subscription stops being returned to the iced runtime, the runtime will kill its associated Stream. The runtime uses the identity of a Subscription to keep track of it.

This way, iced allows you to declaratively subscribe to particular streams of data temporarily and whenever necessary.

use iced::time::{self, Duration, Instant};
use iced::Subscription;

struct State {
    timer_enabled: bool,
}

fn subscription(state: &State) -> Subscription<Instant> {
    if state.timer_enabled {
        time::every(Duration::from_secs(1))
    } else {
        Subscription::none()
    }
}

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impl<T> Subscription<T>

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pub fn none() -> Subscription<T>

Returns an empty Subscription that will not produce any output.

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pub fn run<S>(builder: fn() -> S) -> Subscription<T>
where S: Stream<Item = T> + MaybeSend + 'static, T: 'static,

Returns a Subscription that will call the given function to create and asynchronously run the given Stream.

§Creating an asynchronous worker with bidirectional communication

You can leverage this helper to create a Subscription that spawns an asynchronous worker in the background and establish a channel of communication with an iced application.

You can achieve this by creating an mpsc channel inside the closure and returning the Sender as a Message for the Application:

use iced::futures::channel::mpsc;
use iced::futures::sink::SinkExt;
use iced::futures::Stream;
use iced::stream;
use iced::Subscription;

pub enum Event {
    Ready(mpsc::Sender<Input>),
    WorkFinished,
    // ...
}

enum Input {
    DoSomeWork,
    // ...
}

fn some_worker() -> impl Stream<Item = Event> {
    stream::channel(100, |mut output| async move {
        // Create channel
        let (sender, mut receiver) = mpsc::channel(100);

        // Send the sender back to the application
        output.send(Event::Ready(sender)).await;

        loop {
            use iced_futures::futures::StreamExt;

            // Read next input sent from `Application`
            let input = receiver.select_next_some().await;

            match input {
                Input::DoSomeWork => {
                    // Do some async work...

                    // Finally, we can optionally produce a message to tell the
                    // `Application` the work is done
                    output.send(Event::WorkFinished).await;
                }
            }
        }
    })
}

fn subscription() -> Subscription<Event> {
    Subscription::run(some_worker)
}

Check out the websocket example, which showcases this pattern to maintain a WebSocket connection open.

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pub fn run_with_id<I, S>(id: I, stream: S) -> Subscription<T>
where I: Hash + 'static, S: Stream<Item = T> + MaybeSend + 'static, T: 'static,

Returns a Subscription that will create and asynchronously run the given Stream.

The id will be used to uniquely identify the Subscription.

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pub fn batch( subscriptions: impl IntoIterator<Item = Subscription<T>>, ) -> Subscription<T>

Batches all the provided subscriptions and returns the resulting Subscription.

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pub fn with<A>(self, value: A) -> Subscription<(A, T)>
where T: 'static, A: Hash + Clone + Send + Sync + 'static,

Adds a value to the Subscription context.

The value will be part of the identity of a Subscription.

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pub fn map<F, A>(self, f: F) -> Subscription<A>
where T: 'static, F: Fn(T) -> A + MaybeSend + Clone + 'static, A: 'static,

Transforms the Subscription output with the given function.

§Panics

The closure provided must be a non-capturing closure. The method will panic in debug mode otherwise.

Trait Implementations§

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impl<T> Debug for Subscription<T>

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fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter. Read more

Auto Trait Implementations§

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impl<T> Freeze for Subscription<T>

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impl<T> !RefUnwindSafe for Subscription<T>

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impl<T> !Send for Subscription<T>

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impl<T> !Sync for Subscription<T>

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impl<T> Unpin for Subscription<T>

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impl<T> !UnwindSafe for Subscription<T>

Blanket Implementations§

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impl<S, D, Swp, Dwp, T> AdaptInto<D, Swp, Dwp, T> for S
where T: Real + Zero + Arithmetics + Clone, Swp: WhitePoint<T>, Dwp: WhitePoint<T>, D: AdaptFrom<S, Swp, Dwp, T>,

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fn adapt_into_using<M>(self, method: M) -> D
where M: TransformMatrix<T>,

Convert the source color to the destination color using the specified method.
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fn adapt_into(self) -> D

Convert the source color to the destination color using the bradford method by default.
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where F: FnOnce(&mut Self),

Apply a function to this value and return the (possibly) modified value.
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where T: 'static + ?Sized,

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fn type_id(&self) -> TypeId

Gets the TypeId of self. Read more
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impl<T, Res> Apply<Res> for T
where T: ?Sized,

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fn apply<F>(self, f: F) -> Res
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Apply a function which takes the parameter by value.
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fn apply_ref<F>(&self, f: F) -> Res
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Apply a function which takes the parameter by reference.
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Apply a function which takes the parameter by mutable reference.
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impl<T, C> ArraysFrom<C> for T
where C: IntoArrays<T>,

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fn arrays_from(colors: C) -> T

Cast a collection of colors into a collection of arrays.
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impl<T, C> ArraysInto<C> for T
where C: FromArrays<T>,

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fn arrays_into(self) -> C

Cast this collection of arrays into a collection of colors.
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Immutably borrows from an owned value. Read more
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where T: FromCam16Unclamped<WpParam, U>,

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type Scalar = <T as FromCam16Unclamped<WpParam, U>>::Scalar

The number type that’s used in parameters when converting.
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Converts self into C, using the provided parameters.
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fn components_from(colors: C) -> T

Cast a collection of colors into a collection of color components.
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Performs a conversion from angle.
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fn from_stimulus(other: U) -> T

Converts other into Self, while performing the appropriate scaling, rounding and clamping.
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The number type that’s used in parameters when converting.
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Converts self into C, using the provided parameters.
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where U: FromColor<T>,

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fn into_color(self) -> U

Convert into T with values clamped to the color defined bounds Read more
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where U: FromColorUnclamped<T>,

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fn into_color_unclamped(self) -> U

Convert into T. The resulting color might be invalid in its color space Read more
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Converts self into T, while performing the appropriate scaling, rounding and clamping.
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The error for when try_into_colors fails to cast.
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fn try_components_into(self) -> Result<C, <T as TryComponentsInto<C>>::Error>

Try to cast this collection of color components into a collection of colors. Read more
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Cast a collection of colors into a collection of unsigned integers.
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Cast this collection of unsigned integers into a collection of colors.
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