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use crate::runtime::handle::Handle; use crate::runtime::shell::Shell; use crate::runtime::{blocking, io, time, Callback, Runtime, Spawner}; use std::fmt; #[cfg(not(loom))] use std::sync::Arc; /// Builds Tokio Runtime with custom configuration values. /// /// Methods can be chained in order to set the configuration values. The /// Runtime is constructed by calling [`build`]. /// /// New instances of `Builder` are obtained via [`Builder::new`]. /// /// See function level documentation for details on the various configuration /// settings. /// /// [`build`]: method@Self::build /// [`Builder::new`]: method@Self::new /// /// # Examples /// /// ``` /// use tokio::runtime::Builder; /// /// fn main() { /// // build runtime /// let runtime = Builder::new() /// .threaded_scheduler() /// .core_threads(4) /// .thread_name("my-custom-name") /// .thread_stack_size(3 * 1024 * 1024) /// .build() /// .unwrap(); /// /// // use runtime ... /// } /// ``` pub struct Builder { /// The task execution model to use. kind: Kind, /// Whether or not to enable the I/O driver enable_io: bool, /// Whether or not to enable the time driver enable_time: bool, /// The number of worker threads, used by Runtime. /// /// Only used when not using the current-thread executor. core_threads: Option<usize>, /// Cap on thread usage. max_threads: usize, /// Name used for threads spawned by the runtime. pub(super) thread_name: String, /// Stack size used for threads spawned by the runtime. pub(super) thread_stack_size: Option<usize>, /// Callback to run after each thread starts. pub(super) after_start: Option<Callback>, /// To run before each worker thread stops pub(super) before_stop: Option<Callback>, } #[derive(Debug, Clone, Copy)] enum Kind { Shell, #[cfg(feature = "rt-core")] Basic, #[cfg(feature = "rt-threaded")] ThreadPool, } impl Builder { /// Returns a new runtime builder initialized with default configuration /// values. /// /// Configuration methods can be chained on the return value. pub fn new() -> Builder { Builder { // No task execution by default kind: Kind::Shell, // I/O defaults to "off" enable_io: false, // Time defaults to "off" enable_time: false, // Default to lazy auto-detection (one thread per CPU core) core_threads: None, max_threads: 512, // Default thread name thread_name: "tokio-runtime-worker".into(), // Do not set a stack size by default thread_stack_size: None, // No worker thread callbacks after_start: None, before_stop: None, } } /// Enables both I/O and time drivers. /// /// Doing this is a shorthand for calling `enable_io` and `enable_time` /// individually. If additional components are added to Tokio in the future, /// `enable_all` will include these future components. /// /// # Examples /// /// ``` /// use tokio::runtime; /// /// let rt = runtime::Builder::new() /// .threaded_scheduler() /// .enable_all() /// .build() /// .unwrap(); /// ``` pub fn enable_all(&mut self) -> &mut Self { #[cfg(feature = "io-driver")] self.enable_io(); #[cfg(feature = "time")] self.enable_time(); self } #[deprecated(note = "In future will be replaced by core_threads method")] /// Sets the maximum number of worker threads for the `Runtime`'s thread pool. /// /// This must be a number between 1 and 32,768 though it is advised to keep /// this value on the smaller side. /// /// The default value is the number of cores available to the system. pub fn num_threads(&mut self, val: usize) -> &mut Self { self.core_threads = Some(val); self } /// Sets the core number of worker threads for the `Runtime`'s thread pool. /// /// This should be a number between 1 and 32,768 though it is advised to keep /// this value on the smaller side. /// /// The default value is the number of cores available to the system. /// /// These threads will be always active and running. /// /// # Examples /// /// ``` /// use tokio::runtime; /// /// let rt = runtime::Builder::new() /// .threaded_scheduler() /// .core_threads(4) /// .build() /// .unwrap(); /// ``` pub fn core_threads(&mut self, val: usize) -> &mut Self { assert_ne!(val, 0, "Core threads cannot be zero"); self.core_threads = Some(val); self } /// Specifies limit for threads, spawned by the Runtime. /// /// This is number of threads to be used by Runtime, including `core_threads` /// Having `max_threads` less than `core_threads` results in invalid configuration /// when building multi-threaded `Runtime`, which would cause a panic. /// /// Similarly to the `core_threads`, this number should be between 1 and 32,768. /// /// The default value is 512. /// /// When multi-threaded runtime is not used, will act as limit on additional threads. /// /// Otherwise as `core_threads` are always active, it limits additional threads (e.g. for /// blocking annotations) as `max_threads - core_threads`. pub fn max_threads(&mut self, val: usize) -> &mut Self { assert_ne!(val, 0, "Thread limit cannot be zero"); self.max_threads = val; self } /// Sets name of threads spawned by the `Runtime`'s thread pool. /// /// The default name is "tokio-runtime-worker". /// /// # Examples /// /// ``` /// # use tokio::runtime; /// /// # pub fn main() { /// let rt = runtime::Builder::new() /// .thread_name("my-pool") /// .build(); /// # } /// ``` pub fn thread_name(&mut self, val: impl Into<String>) -> &mut Self { self.thread_name = val.into(); self } /// Sets the stack size (in bytes) for worker threads. /// /// The actual stack size may be greater than this value if the platform /// specifies minimal stack size. /// /// The default stack size for spawned threads is 2 MiB, though this /// particular stack size is subject to change in the future. /// /// # Examples /// /// ``` /// # use tokio::runtime; /// /// # pub fn main() { /// let rt = runtime::Builder::new() /// .threaded_scheduler() /// .thread_stack_size(32 * 1024) /// .build(); /// # } /// ``` pub fn thread_stack_size(&mut self, val: usize) -> &mut Self { self.thread_stack_size = Some(val); self } /// Executes function `f` after each thread is started but before it starts /// doing work. /// /// This is intended for bookkeeping and monitoring use cases. /// /// # Examples /// /// ``` /// # use tokio::runtime; /// /// # pub fn main() { /// let runtime = runtime::Builder::new() /// .threaded_scheduler() /// .on_thread_start(|| { /// println!("thread started"); /// }) /// .build(); /// # } /// ``` #[cfg(not(loom))] pub fn on_thread_start<F>(&mut self, f: F) -> &mut Self where F: Fn() + Send + Sync + 'static, { self.after_start = Some(Arc::new(f)); self } /// Executes function `f` before each thread stops. /// /// This is intended for bookkeeping and monitoring use cases. /// /// # Examples /// /// ``` /// # use tokio::runtime; /// /// # pub fn main() { /// let runtime = runtime::Builder::new() /// .threaded_scheduler() /// .on_thread_stop(|| { /// println!("thread stopping"); /// }) /// .build(); /// # } /// ``` #[cfg(not(loom))] pub fn on_thread_stop<F>(&mut self, f: F) -> &mut Self where F: Fn() + Send + Sync + 'static, { self.before_stop = Some(Arc::new(f)); self } /// Creates the configured `Runtime`. /// /// The returned `ThreadPool` instance is ready to spawn tasks. /// /// # Examples /// /// ``` /// use tokio::runtime::Builder; /// /// let mut rt = Builder::new().build().unwrap(); /// /// rt.block_on(async { /// println!("Hello from the Tokio runtime"); /// }); /// ``` pub fn build(&mut self) -> io::Result<Runtime> { match self.kind { Kind::Shell => self.build_shell_runtime(), #[cfg(feature = "rt-core")] Kind::Basic => self.build_basic_runtime(), #[cfg(feature = "rt-threaded")] Kind::ThreadPool => self.build_threaded_runtime(), } } fn build_shell_runtime(&mut self) -> io::Result<Runtime> { use crate::runtime::Kind; let clock = time::create_clock(); // Create I/O driver let (io_driver, io_handle) = io::create_driver(self.enable_io)?; let (driver, time_handle) = time::create_driver(self.enable_time, io_driver, clock.clone()); let spawner = Spawner::Shell; let blocking_pool = blocking::create_blocking_pool(self, self.max_threads); let blocking_spawner = blocking_pool.spawner().clone(); Ok(Runtime { kind: Kind::Shell(Shell::new(driver)), handle: Handle { spawner, io_handle, time_handle, clock, blocking_spawner, }, blocking_pool, }) } } cfg_io_driver! { impl Builder { /// Enables the I/O driver. /// /// Doing this enables using net, process, signal, and some I/O types on /// the runtime. /// /// # Examples /// /// ``` /// use tokio::runtime; /// /// let rt = runtime::Builder::new() /// .enable_io() /// .build() /// .unwrap(); /// ``` pub fn enable_io(&mut self) -> &mut Self { self.enable_io = true; self } } } cfg_time! { impl Builder { /// Enables the time driver. /// /// Doing this enables using `tokio::time` on the runtime. /// /// # Examples /// /// ``` /// use tokio::runtime; /// /// let rt = runtime::Builder::new() /// .enable_time() /// .build() /// .unwrap(); /// ``` pub fn enable_time(&mut self) -> &mut Self { self.enable_time = true; self } } } cfg_rt_core! { impl Builder { /// Sets runtime to use a simpler scheduler that runs all tasks on the current-thread. /// /// The executor and all necessary drivers will all be run on the current /// thread during [`block_on`] calls. /// /// See also [the module level documentation][1], which has a section on scheduler /// types. /// /// [1]: index.html#runtime-configurations /// [`block_on`]: Runtime::block_on pub fn basic_scheduler(&mut self) -> &mut Self { self.kind = Kind::Basic; self } fn build_basic_runtime(&mut self) -> io::Result<Runtime> { use crate::runtime::{BasicScheduler, Kind}; let clock = time::create_clock(); // Create I/O driver let (io_driver, io_handle) = io::create_driver(self.enable_io)?; let (driver, time_handle) = time::create_driver(self.enable_time, io_driver, clock.clone()); // And now put a single-threaded scheduler on top of the timer. When // there are no futures ready to do something, it'll let the timer or // the reactor to generate some new stimuli for the futures to continue // in their life. let scheduler = BasicScheduler::new(driver); let spawner = Spawner::Basic(scheduler.spawner().clone()); // Blocking pool let blocking_pool = blocking::create_blocking_pool(self, self.max_threads); let blocking_spawner = blocking_pool.spawner().clone(); Ok(Runtime { kind: Kind::Basic(scheduler), handle: Handle { spawner, io_handle, time_handle, clock, blocking_spawner, }, blocking_pool, }) } } } cfg_rt_threaded! { impl Builder { /// Sets runtime to use a multi-threaded scheduler for executing tasks. /// /// See also [the module level documentation][1], which has a section on scheduler /// types. /// /// [1]: index.html#runtime-configurations pub fn threaded_scheduler(&mut self) -> &mut Self { self.kind = Kind::ThreadPool; self } fn build_threaded_runtime(&mut self) -> io::Result<Runtime> { use crate::loom::sys::num_cpus; use crate::runtime::{Kind, ThreadPool}; use crate::runtime::park::Parker; use std::cmp; let core_threads = self.core_threads.unwrap_or_else(|| cmp::min(self.max_threads, num_cpus())); assert!(core_threads <= self.max_threads, "Core threads number cannot be above max limit"); let clock = time::create_clock(); let (io_driver, io_handle) = io::create_driver(self.enable_io)?; let (driver, time_handle) = time::create_driver(self.enable_time, io_driver, clock.clone()); let (scheduler, launch) = ThreadPool::new(core_threads, Parker::new(driver)); let spawner = Spawner::ThreadPool(scheduler.spawner().clone()); // Create the blocking pool let blocking_pool = blocking::create_blocking_pool(self, self.max_threads); let blocking_spawner = blocking_pool.spawner().clone(); // Create the runtime handle let handle = Handle { spawner, io_handle, time_handle, clock, blocking_spawner, }; // Spawn the thread pool workers handle.enter(|| launch.launch()); Ok(Runtime { kind: Kind::ThreadPool(scheduler), handle, blocking_pool, }) } } } impl Default for Builder { fn default() -> Self { Self::new() } } impl fmt::Debug for Builder { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("Builder") .field("kind", &self.kind) .field("core_threads", &self.core_threads) .field("max_threads", &self.max_threads) .field("thread_name", &self.thread_name) .field("thread_stack_size", &self.thread_stack_size) .field("after_start", &self.after_start.as_ref().map(|_| "...")) .field("before_stop", &self.after_start.as_ref().map(|_| "...")) .finish() } }