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//! Utilities for tracking time. //! //! This module provides a number of types for executing code after a set period //! of time. //! //! * `Sleep` is a future that does no work and completes at a specific `Instant` //! in time. //! //! * `Interval` is a stream yielding a value at a fixed period. It is //! initialized with a `Duration` and repeatedly yields each time the duration //! elapses. //! //! * `Timeout`: Wraps a future or stream, setting an upper bound to the amount //! of time it is allowed to execute. If the future or stream does not //! complete in time, then it is canceled and an error is returned. //! //! These types are sufficient for handling a large number of scenarios //! involving time. //! //! These types must be used from within the context of the `Runtime`. //! //! # Examples //! //! Wait 100ms and print "100 ms have elapsed" //! //! ``` //! use tokio::time::sleep; //! //! use std::time::Duration; //! //! //! #[tokio::main] //! async fn main() { //! sleep(Duration::from_millis(100)).await; //! println!("100 ms have elapsed"); //! } //! ``` //! //! Require that an operation takes no more than 300ms. Note that this uses the //! `timeout` function on the `FutureExt` trait. This trait is included in the //! prelude. //! //! ``` //! use tokio::time::{timeout, Duration}; //! //! async fn long_future() { //! // do work here //! } //! //! # async fn dox() { //! let res = timeout(Duration::from_secs(1), long_future()).await; //! //! if res.is_err() { //! println!("operation timed out"); //! } //! # } //! ``` //! //! A simple example using [`interval`] to execute a task every two seconds. //! //! The difference between [`interval`] and [`sleep`] is that an //! [`interval`] measures the time since the last tick, which means that //! `.tick().await` may wait for a shorter time than the duration specified //! for the interval if some time has passed between calls to `.tick().await`. //! //! If the tick in the example below was replaced with [`sleep`], the task //! would only be executed once every three seconds, and not every two //! seconds. //! //! ``` //! use tokio::time; //! //! async fn task_that_takes_a_second() { //! println!("hello"); //! time::sleep(time::Duration::from_secs(1)).await //! } //! //! #[tokio::main] //! async fn main() { //! let interval = time::interval(time::Duration::from_secs(2)); //! tokio::pin!(interval); //! //! for _i in 0..5 { //! interval.as_mut().tick().await; //! task_that_takes_a_second().await; //! } //! } //! ``` //! //! [`sleep`]: crate::time::sleep() //! [`interval`]: crate::time::interval() mod clock; pub(crate) use self::clock::Clock; #[cfg(feature = "test-util")] pub use clock::{advance, pause, resume}; pub(crate) mod driver; #[doc(inline)] pub use driver::sleep::{sleep, sleep_until, Sleep}; pub mod error; mod instant; pub use self::instant::Instant; mod interval; pub use interval::{interval, interval_at, Interval}; mod timeout; #[doc(inline)] pub use timeout::{timeout, timeout_at, Timeout}; #[cfg(test)] #[cfg(not(loom))] mod tests; // Re-export for convenience #[doc(no_inline)] pub use std::time::Duration;