//! The Tokio runtime. //! //! Unlike other Rust programs, asynchronous applications require runtime //! support. In particular, the following runtime services are necessary: //! //! * An **I/O event loop**, called the driver, which drives I/O resources and //! dispatches I/O events to tasks that depend on them. //! * A **scheduler** to execute [tasks] that use these I/O resources. //! * A **timer** for scheduling work to run after a set period of time. //! //! Tokio's [`Runtime`] bundles all of these services as a single type, allowing //! them to be started, shut down, and configured together. However, often it is //! not required to configure a [`Runtime`] manually, and user may just use the //! [`tokio::main`] attribute macro, which creates a [`Runtime`] under the hood. //! //! # Usage //! //! When no fine tuning is required, the [`tokio::main`] attribute macro can be //! used. //! //! ```no_run //! use tokio::net::TcpListener; //! use tokio::prelude::*; //! //! #[tokio::main] //! async fn main() -> Result<(), Box> { //! let listener = TcpListener::bind("127.0.0.1:8080").await?; //! //! loop { //! let (mut socket, _) = listener.accept().await?; //! //! tokio::spawn(async move { //! let mut buf = [0; 1024]; //! //! // In a loop, read data from the socket and write the data back. //! loop { //! let n = match socket.read(&mut buf).await { //! // socket closed //! Ok(n) if n == 0 => return, //! Ok(n) => n, //! Err(e) => { //! println!("failed to read from socket; err = {:?}", e); //! return; //! } //! }; //! //! // Write the data back //! if let Err(e) = socket.write_all(&buf[0..n]).await { //! println!("failed to write to socket; err = {:?}", e); //! return; //! } //! } //! }); //! } //! } //! ``` //! //! From within the context of the runtime, additional tasks are spawned using //! the [`tokio::spawn`] function. Futures spawned using this function will be //! executed on the same thread pool used by the [`Runtime`]. //! //! A [`Runtime`] instance can also be used directly. //! //! ```no_run //! use tokio::net::TcpListener; //! use tokio::prelude::*; //! use tokio::runtime::Runtime; //! //! fn main() -> Result<(), Box> { //! // Create the runtime //! let rt = Runtime::new()?; //! //! // Spawn the root task //! rt.block_on(async { //! let listener = TcpListener::bind("127.0.0.1:8080").await?; //! //! loop { //! let (mut socket, _) = listener.accept().await?; //! //! tokio::spawn(async move { //! let mut buf = [0; 1024]; //! //! // In a loop, read data from the socket and write the data back. //! loop { //! let n = match socket.read(&mut buf).await { //! // socket closed //! Ok(n) if n == 0 => return, //! Ok(n) => n, //! Err(e) => { //! println!("failed to read from socket; err = {:?}", e); //! return; //! } //! }; //! //! // Write the data back //! if let Err(e) = socket.write_all(&buf[0..n]).await { //! println!("failed to write to socket; err = {:?}", e); //! return; //! } //! } //! }); //! } //! }) //! } //! ``` //! //! ## Runtime Configurations //! //! Tokio provides multiple task scheduling strategies, suitable for different //! applications. The [runtime builder] or `#[tokio::main]` attribute may be //! used to select which scheduler to use. //! //! #### Multi-Thread Scheduler //! //! The multi-thread scheduler executes futures on a _thread pool_, using a //! work-stealing strategy. By default, it will start a worker thread for each //! CPU core available on the system. This tends to be the ideal configurations //! for most applications. The multi-thread scheduler requires the `rt-multi-thread` //! feature flag, and is selected by default: //! ``` //! use tokio::runtime; //! //! # fn main() -> Result<(), Box> { //! let threaded_rt = runtime::Runtime::new()?; //! # Ok(()) } //! ``` //! //! Most applications should use the multi-thread scheduler, except in some //! niche use-cases, such as when running only a single thread is required. //! //! #### Current-Thread Scheduler //! //! The current-thread scheduler provides a _single-threaded_ future executor. //! All tasks will be created and executed on the current thread. This requires //! the `rt` feature flag. //! ``` //! use tokio::runtime; //! //! # fn main() -> Result<(), Box> { //! let basic_rt = runtime::Builder::new_current_thread() //! .build()?; //! # Ok(()) } //! ``` //! //! #### Resource drivers //! //! When configuring a runtime by hand, no resource drivers are enabled by //! default. In this case, attempting to use networking types or time types will //! fail. In order to enable these types, the resource drivers must be enabled. //! This is done with [`Builder::enable_io`] and [`Builder::enable_time`]. As a //! shorthand, [`Builder::enable_all`] enables both resource drivers. //! //! ## Lifetime of spawned threads //! //! The runtime may spawn threads depending on its configuration and usage. The //! multi-thread scheduler spawns threads to schedule tasks and for `spawn_blocking` //! calls. //! //! While the `Runtime` is active, threads may shutdown after periods of being //! idle. Once `Runtime` is dropped, all runtime threads are forcibly shutdown. //! Any tasks that have not yet completed will be dropped. //! //! [tasks]: crate::task //! [`Runtime`]: Runtime //! [`tokio::spawn`]: crate::spawn //! [`tokio::main`]: ../attr.main.html //! [runtime builder]: crate::runtime::Builder //! [`Runtime::new`]: crate::runtime::Runtime::new //! [`Builder::basic_scheduler`]: crate::runtime::Builder::basic_scheduler //! [`Builder::threaded_scheduler`]: crate::runtime::Builder::threaded_scheduler //! [`Builder::enable_io`]: crate::runtime::Builder::enable_io //! [`Builder::enable_time`]: crate::runtime::Builder::enable_time //! [`Builder::enable_all`]: crate::runtime::Builder::enable_all // At the top due to macros #[cfg(test)] #[macro_use] mod tests; pub(crate) mod enter; pub(crate) mod task; cfg_rt! { mod basic_scheduler; use basic_scheduler::BasicScheduler; mod blocking; use blocking::BlockingPool; pub(crate) use blocking::spawn_blocking; mod builder; pub use self::builder::Builder; pub(crate) mod context; pub(crate) mod driver; use self::enter::enter; mod handle; use handle::Handle; mod spawner; use self::spawner::Spawner; } cfg_rt_multi_thread! { mod park; use park::Parker; } cfg_rt_multi_thread! { mod queue; pub(crate) mod thread_pool; use self::thread_pool::ThreadPool; } cfg_rt! { use crate::task::JoinHandle; use std::future::Future; use std::time::Duration; /// The Tokio runtime. /// /// The runtime provides an I/O driver, task scheduler, [timer], and /// blocking pool, necessary for running asynchronous tasks. /// /// Instances of `Runtime` can be created using [`new`], or [`Builder`]. /// However, most users will use the `#[tokio::main]` annotation on their /// entry point instead. /// /// See [module level][mod] documentation for more details. /// /// # Shutdown /// /// Shutting down the runtime is done by dropping the value. The current /// thread will block until the shut down operation has completed. /// /// * Drain any scheduled work queues. /// * Drop any futures that have not yet completed. /// * Drop the reactor. /// /// Once the reactor has dropped, any outstanding I/O resources bound to /// that reactor will no longer function. Calling any method on them will /// result in an error. /// /// # Sharing /// /// The Tokio runtime implements `Sync` and `Send` to allow you to wrap it /// in a `Arc`. Most fn take `&self` to allow you to call them concurrently /// accross multiple threads. /// /// Calls to `shutdown` and `shutdown_timeout` require exclusive ownership of /// the runtime type and this can be achieved via `Arc::try_unwrap` when only /// one strong count reference is left over. /// /// [timer]: crate::time /// [mod]: index.html /// [`new`]: method@Self::new /// [`Builder`]: struct@Builder #[derive(Debug)] pub struct Runtime { /// Task executor kind: Kind, /// Handle to runtime, also contains driver handles handle: Handle, /// Blocking pool handle, used to signal shutdown blocking_pool: BlockingPool, } /// Runtime context guard. /// /// Returned by [`Runtime::enter`], the context guard exits the runtime /// context on drop. #[derive(Debug)] pub struct EnterGuard<'a> { rt: &'a Runtime, guard: context::EnterGuard, } /// The runtime executor is either a thread-pool or a current-thread executor. #[derive(Debug)] enum Kind { /// Execute all tasks on the current-thread. CurrentThread(BasicScheduler), /// Execute tasks across multiple threads. #[cfg(feature = "rt-multi-thread")] ThreadPool(ThreadPool), } /// After thread starts / before thread stops type Callback = std::sync::Arc; impl Runtime { /// Create a new runtime instance with default configuration values. /// /// This results in the multi threaded scheduler, I/O driver, and time driver being /// initialized. /// /// Most applications will not need to call this function directly. Instead, /// they will use the [`#[tokio::main]` attribute][main]. When a more complex /// configuration is necessary, the [runtime builder] may be used. /// /// See [module level][mod] documentation for more details. /// /// # Examples /// /// Creating a new `Runtime` with default configuration values. /// /// ``` /// use tokio::runtime::Runtime; /// /// let rt = Runtime::new() /// .unwrap(); /// /// // Use the runtime... /// ``` /// /// [mod]: index.html /// [main]: ../attr.main.html /// [threaded scheduler]: index.html#threaded-scheduler /// [basic scheduler]: index.html#basic-scheduler /// [runtime builder]: crate::runtime::Builder #[cfg(feature = "rt-multi-thread")] #[cfg_attr(docsrs, doc(cfg(feature = "rt-multi-thread")))] pub fn new() -> std::io::Result { Builder::new_multi_thread().enable_all().build() } /// Spawn a future onto the Tokio runtime. /// /// This spawns the given future onto the runtime's executor, usually a /// thread pool. The thread pool is then responsible for polling the future /// until it completes. /// /// See [module level][mod] documentation for more details. /// /// [mod]: index.html /// /// # Examples /// /// ``` /// use tokio::runtime::Runtime; /// /// # fn dox() { /// // Create the runtime /// let rt = Runtime::new().unwrap(); /// /// // Spawn a future onto the runtime /// rt.spawn(async { /// println!("now running on a worker thread"); /// }); /// # } /// ``` #[cfg_attr(tokio_track_caller, track_caller)] pub fn spawn(&self, future: F) -> JoinHandle where F: Future + Send + 'static, F::Output: Send + 'static, { #[cfg(feature = "tracing")] let future = crate::util::trace::task(future, "task"); match &self.kind { #[cfg(feature = "rt-multi-thread")] Kind::ThreadPool(exec) => exec.spawn(future), Kind::CurrentThread(exec) => exec.spawn(future), } } /// Run the provided function on an executor dedicated to blocking operations. /// /// # Examples /// /// ``` /// use tokio::runtime::Runtime; /// /// # fn dox() { /// // Create the runtime /// let rt = Runtime::new().unwrap(); /// /// // Spawn a blocking function onto the runtime /// rt.spawn_blocking(|| { /// println!("now running on a worker thread"); /// }); /// # } #[cfg_attr(tokio_track_caller, track_caller)] pub fn spawn_blocking(&self, func: F) -> JoinHandle where F: FnOnce() -> R + Send + 'static, { self.handle.spawn_blocking(func) } /// Run a future to completion on the Tokio runtime. This is the /// runtime's entry point. /// /// This runs the given future on the runtime, blocking until it is /// complete, and yielding its resolved result. Any tasks or timers /// which the future spawns internally will be executed on the runtime. /// /// # Multi thread scheduler /// /// When the multi thread scheduler is used this will allow futures /// to run within the io driver and timer context of the overall runtime. /// /// # Current thread scheduler /// /// When the current thread scheduler is enabled `block_on` /// can be called concurrently from multiple threads. The first call /// will take ownership of the io and timer drivers. This means /// other threads which do not own the drivers will hook into that one. /// When the first `block_on` completes, other threads will be able to /// "steal" the driver to allow continued execution of their futures. /// /// # Panics /// /// This function panics if the provided future panics, or if called within an /// asynchronous execution context. /// /// # Examples /// /// ```no_run /// use tokio::runtime::Runtime; /// /// // Create the runtime /// let rt = Runtime::new().unwrap(); /// /// // Execute the future, blocking the current thread until completion /// rt.block_on(async { /// println!("hello"); /// }); /// ``` /// /// [handle]: fn@Handle::block_on pub fn block_on(&self, future: F) -> F::Output { let _enter = self.enter(); match &self.kind { Kind::CurrentThread(exec) => exec.block_on(future), #[cfg(feature = "rt-multi-thread")] Kind::ThreadPool(exec) => exec.block_on(future), } } /// Enter the runtime context. /// /// This allows you to construct types that must have an executor /// available on creation such as [`Sleep`] or [`TcpStream`]. It will /// also allow you to call methods such as [`tokio::spawn`]. /// /// [`Sleep`]: struct@crate::time::Sleep /// [`TcpStream`]: struct@crate::net::TcpStream /// [`tokio::spawn`]: fn@crate::spawn /// /// # Example /// /// ``` /// use tokio::runtime::Runtime; /// /// fn function_that_spawns(msg: String) { /// // Had we not used `rt.enter` below, this would panic. /// tokio::spawn(async move { /// println!("{}", msg); /// }); /// } /// /// fn main() { /// let rt = Runtime::new().unwrap(); /// /// let s = "Hello World!".to_string(); /// /// // By entering the context, we tie `tokio::spawn` to this executor. /// let _guard = rt.enter(); /// function_that_spawns(s); /// } /// ``` pub fn enter(&self) -> EnterGuard<'_> { EnterGuard { rt: self, guard: context::enter(self.handle.clone()), } } /// Shutdown the runtime, waiting for at most `duration` for all spawned /// task to shutdown. /// /// Usually, dropping a `Runtime` handle is sufficient as tasks are able to /// shutdown in a timely fashion. However, dropping a `Runtime` will wait /// indefinitely for all tasks to terminate, and there are cases where a long /// blocking task has been spawned, which can block dropping `Runtime`. /// /// In this case, calling `shutdown_timeout` with an explicit wait timeout /// can work. The `shutdown_timeout` will signal all tasks to shutdown and /// will wait for at most `duration` for all spawned tasks to terminate. If /// `timeout` elapses before all tasks are dropped, the function returns and /// outstanding tasks are potentially leaked. /// /// # Examples /// /// ``` /// use tokio::runtime::Runtime; /// use tokio::task; /// /// use std::thread; /// use std::time::Duration; /// /// fn main() { /// let runtime = Runtime::new().unwrap(); /// /// runtime.block_on(async move { /// task::spawn_blocking(move || { /// thread::sleep(Duration::from_secs(10_000)); /// }); /// }); /// /// runtime.shutdown_timeout(Duration::from_millis(100)); /// } /// ``` pub fn shutdown_timeout(mut self, duration: Duration) { // Wakeup and shutdown all the worker threads self.handle.spawner.shutdown(); self.blocking_pool.shutdown(Some(duration)); } /// Shutdown the runtime, without waiting for any spawned tasks to shutdown. /// /// This can be useful if you want to drop a runtime from within another runtime. /// Normally, dropping a runtime will block indefinitely for spawned blocking tasks /// to complete, which would normally not be permitted within an asynchronous context. /// By calling `shutdown_background()`, you can drop the runtime from such a context. /// /// Note however, that because we do not wait for any blocking tasks to complete, this /// may result in a resource leak (in that any blocking tasks are still running until they /// return. /// /// This function is equivalent to calling `shutdown_timeout(Duration::of_nanos(0))`. /// /// ``` /// use tokio::runtime::Runtime; /// /// fn main() { /// let runtime = Runtime::new().unwrap(); /// /// runtime.block_on(async move { /// let inner_runtime = Runtime::new().unwrap(); /// // ... /// inner_runtime.shutdown_background(); /// }); /// } /// ``` pub fn shutdown_background(self) { self.shutdown_timeout(Duration::from_nanos(0)) } } }