linux-x86/1.55.0/src/stdlibs/library/core/src/stream/mod.rs - platform/prebuilts/rust - Git at Google

 //! Composable asynchronous iteration.
 //!
 //! If futures are asynchronous values, then streams are asynchronous
 //! iterators. If you've found yourself with an asynchronous collection of some kind,
 //! and needed to perform an operation on the elements of said collection,
 //! you'll quickly run into 'streams'. Streams are heavily used in idiomatic
 //! asynchronous Rust code, so it's worth becoming familiar with them.
 //!
 //! Before explaining more, let's talk about how this module is structured:
 //!
 //! # Organization
 //!
 //! This module is largely organized by type:
 //!
 //! * [Traits] are the core portion: these traits define what kind of streams
 //!   exist and what you can do with them. The methods of these traits are worth
 //!   putting some extra study time into.
 //! * Functions provide some helpful ways to create some basic streams.
 //! * Structs are often the return types of the various methods on this
 //!   module's traits. You'll usually want to look at the method that creates
 //!   the `struct`, rather than the `struct` itself. For more detail about why,
 //!   see '[Implementing Stream](#implementing-stream)'.
 //!
 //! [Traits]: #traits
 //!
 //! That's it! Let's dig into streams.
 //!
 //! # Stream
 //!
 //! The heart and soul of this module is the [`Stream`] trait. The core of
 //! [`Stream`] looks like this:
 //!
 //! ```
 //! # use core::task::{Context, Poll};
 //! # use core::pin::Pin;
 //! trait Stream {
 //!     type Item;
 //!     fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>>;
 //! }
 //! ```
 //!
 //! Unlike `Iterator`, `Stream` makes a distinction between the [`poll_next`]
 //! method which is used when implementing a `Stream`, and a (to-be-implemented)
 //! `next` method which is used when consuming a stream. Consumers of `Stream`
 //! only need to consider `next`, which when called, returns a future which
 //! yields `Option<Stream::Item>`.
 //!
 //! The future returned by `next` will yield `Some(Item)` as long as there are
 //! elements, and once they've all been exhausted, will yield `None` to indicate
 //! that iteration is finished. If we're waiting on something asynchronous to
 //! resolve, the future will wait until the stream is ready to yield again.
 //!
 //! Individual streams may choose to resume iteration, and so calling `next`
 //! again may or may not eventually yield `Some(Item)` again at some point.
 //!
 //! [`Stream`]'s full definition includes a number of other methods as well,
 //! but they are default methods, built on top of [`poll_next`], and so you get
 //! them for free.
 //!
 //! [`Poll`]: super::task::Poll
 //! [`poll_next`]: Stream::poll_next
 //!
 //! # Implementing Stream
 //!
 //! Creating a stream of your own involves two steps: creating a `struct` to
 //! hold the stream's state, and then implementing [`Stream`] for that
 //! `struct`.
 //!
 //! Let's make a stream named `Counter` which counts from `1` to `5`:
 //!
 //! ```no_run
 //! #![feature(async_stream)]
 //! # use core::stream::Stream;
 //! # use core::task::{Context, Poll};
 //! # use core::pin::Pin;
 //!
 //! // First, the struct:
 //!
 //! /// A stream which counts from one to five
 //! struct Counter {
 //!     count: usize,
 //! }
 //!
 //! // we want our count to start at one, so let's add a new() method to help.
 //! // This isn't strictly necessary, but is convenient. Note that we start
 //! // `count` at zero, we'll see why in `poll_next()`'s implementation below.
 //! impl Counter {
 //!     fn new() -> Counter {
 //!         Counter { count: 0 }
 //!     }
 //! }
 //!
 //! // Then, we implement `Stream` for our `Counter`:
 //!
 //! impl Stream for Counter {
 //!     // we will be counting with usize
 //!     type Item = usize;
 //!
 //!     // poll_next() is the only required method
 //!     fn poll_next(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
 //!         // Increment our count. This is why we started at zero.
 //!         self.count += 1;
 //!
 //!         // Check to see if we've finished counting or not.
 //!         if self.count < 6 {
 //!             Poll::Ready(Some(self.count))
 //!         } else {
 //!             Poll::Ready(None)
 //!         }
 //!     }
 //! }
 //! ```
 //!
 //! # Laziness
 //!
 //! Streams are *lazy*. This means that just creating a stream doesn't _do_ a
 //! whole lot. Nothing really happens until you call `next`. This is sometimes a
 //! source of confusion when creating a stream solely for its side effects. The
 //! compiler will warn us about this kind of behavior:
 //!
 //! ```text
 //! warning: unused result that must be used: streams do nothing unless polled
 //! ```

 mod stream;

 pub use stream::Stream;
	//! Composable asynchronous iteration.
	//!
	//! If futures are asynchronous values, then streams are asynchronous
	//! iterators. If you've found yourself with an asynchronous collection of some kind,
	//! and needed to perform an operation on the elements of said collection,
	//! you'll quickly run into 'streams'. Streams are heavily used in idiomatic
	//! asynchronous Rust code, so it's worth becoming familiar with them.
	//!
	//! Before explaining more, let's talk about how this module is structured:
	//!
	//! # Organization
	//!
	//! This module is largely organized by type:
	//!
	//! * [Traits] are the core portion: these traits define what kind of streams
	//! exist and what you can do with them. The methods of these traits are worth
	//! putting some extra study time into.
	//! * Functions provide some helpful ways to create some basic streams.
	//! * Structs are often the return types of the various methods on this
	//! module's traits. You'll usually want to look at the method that creates
	//! the `struct`, rather than the `struct` itself. For more detail about why,
	//! see '[Implementing Stream](#implementing-stream)'.
	//!
	//! [Traits]: #traits
	//!
	//! That's it! Let's dig into streams.
	//!
	//! # Stream
	//!
	//! The heart and soul of this module is the [`Stream`] trait. The core of
	//! [`Stream`] looks like this:
	//!
	//! ```
	//! # use core::task::{Context, Poll};
	//! # use core::pin::Pin;
	//! trait Stream {
	//! type Item;
	//! fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>>;
	//! }
	//! ```
	//!
	//! Unlike `Iterator`, `Stream` makes a distinction between the [`poll_next`]
	//! method which is used when implementing a `Stream`, and a (to-be-implemented)
	//! `next` method which is used when consuming a stream. Consumers of `Stream`
	//! only need to consider `next`, which when called, returns a future which
	//! yields `Option<Stream::Item>`.
	//!
	//! The future returned by `next` will yield `Some(Item)` as long as there are
	//! elements, and once they've all been exhausted, will yield `None` to indicate
	//! that iteration is finished. If we're waiting on something asynchronous to
	//! resolve, the future will wait until the stream is ready to yield again.
	//!
	//! Individual streams may choose to resume iteration, and so calling `next`
	//! again may or may not eventually yield `Some(Item)` again at some point.
	//!
	//! [`Stream`]'s full definition includes a number of other methods as well,
	//! but they are default methods, built on top of [`poll_next`], and so you get
	//! them for free.
	//!
	//! [`Poll`]: super::task::Poll
	//! [`poll_next`]: Stream::poll_next
	//!
	//! # Implementing Stream
	//!
	//! Creating a stream of your own involves two steps: creating a `struct` to
	//! hold the stream's state, and then implementing [`Stream`] for that
	//! `struct`.
	//!
	//! Let's make a stream named `Counter` which counts from `1` to `5`:
	//!
	//! ```no_run
	//! #![feature(async_stream)]
	//! # use core::stream::Stream;
	//! # use core::task::{Context, Poll};
	//! # use core::pin::Pin;
	//!
	//! // First, the struct:
	//!
	//! /// A stream which counts from one to five
	//! struct Counter {
	//! count: usize,
	//! }
	//!
	//! // we want our count to start at one, so let's add a new() method to help.
	//! // This isn't strictly necessary, but is convenient. Note that we start
	//! // `count` at zero, we'll see why in `poll_next()`'s implementation below.
	//! impl Counter {
	//! fn new() -> Counter {
	//! Counter { count: 0 }
	//! }
	//! }
	//!
	//! // Then, we implement `Stream` for our `Counter`:
	//!
	//! impl Stream for Counter {
	//! // we will be counting with usize
	//! type Item = usize;
	//!
	//! // poll_next() is the only required method
	//! fn poll_next(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
	//! // Increment our count. This is why we started at zero.
	//! self.count += 1;
	//!
	//! // Check to see if we've finished counting or not.
	//! if self.count < 6 {
	//! Poll::Ready(Some(self.count))
	//! } else {
	//! Poll::Ready(None)
	//! }
	//! }
	//! }
	//! ```
	//!
	//! # Laziness
	//!
	//! Streams are lazy. This means that just creating a stream doesn't _do_ a
	//! whole lot. Nothing really happens until you call `next`. This is sometimes a
	//! source of confusion when creating a stream solely for its side effects. The
	//! compiler will warn us about this kind of behavior:
	//!
	//! ```text
	//! warning: unused result that must be used: streams do nothing unless polled
	//! ```

	mod stream;

	pub use stream::Stream;