use std::time::Duration; use std::{io, mem, net}; use futures::sync::{mpsc, mpsc::unbounded}; use futures::{Future, Sink, Stream}; use net2::TcpBuilder; use num_cpus; use actix::{ actors::signal, fut, msgs::Execute, Actor, ActorFuture, Addr, Arbiter, AsyncContext, Context, Handler, Response, StreamHandler, System, WrapFuture, }; use super::accept::{AcceptLoop, AcceptNotify, Command}; use super::services::{InternalServiceFactory, StreamNewService, StreamServiceFactory}; use super::services::{ServiceFactory, ServiceNewService}; use super::worker::{self, Worker, WorkerAvailability, WorkerClient}; use super::{PauseServer, ResumeServer, StopServer, Token}; pub(crate) enum ServerCommand { WorkerDied(usize), } /// Server pub struct Server { threads: usize, workers: Vec<(usize, WorkerClient)>, services: Vec>, sockets: Vec<(Token, net::TcpListener)>, accept: AcceptLoop, exit: bool, shutdown_timeout: Duration, signals: Option>, no_signals: bool, } impl Default for Server { fn default() -> Self { Self::new() } } impl Server { /// Create new Server instance pub fn new() -> Server { Server { threads: num_cpus::get(), workers: Vec::new(), services: Vec::new(), sockets: Vec::new(), accept: AcceptLoop::new(), exit: false, shutdown_timeout: Duration::from_secs(30), signals: None, no_signals: false, } } /// Set number of workers to start. /// /// By default server uses number of available logical cpu as threads /// count. pub fn workers(mut self, num: usize) -> Self { self.threads = num; self } /// Sets the maximum per-worker number of concurrent connections. /// /// All socket listeners will stop accepting connections when this limit is /// reached for each worker. /// /// By default max connections is set to a 25k per worker. pub fn maxconn(self, num: usize) -> Self { worker::max_concurrent_connections(num); self } /// Stop actix system. /// /// `SystemExit` message stops currently running system. pub fn system_exit(mut self) -> Self { self.exit = true; self } #[doc(hidden)] /// Set alternative address for `ProcessSignals` actor. pub fn signals(mut self, addr: Addr) -> Self { self.signals = Some(addr); self } /// Disable signal handling pub fn disable_signals(mut self) -> Self { self.no_signals = true; self } /// Timeout for graceful workers shutdown in seconds. /// /// After receiving a stop signal, workers have this much time to finish /// serving requests. Workers still alive after the timeout are force /// dropped. /// /// By default shutdown timeout sets to 30 seconds. pub fn shutdown_timeout(mut self, sec: u16) -> Self { self.shutdown_timeout = Duration::from_secs(u64::from(sec)); self } /// Run external configuration as part of the server building /// process /// /// This function is useful for moving parts of configuration to a /// different module or event library. pub fn configure(self, cfg: F) -> Server where F: Fn(Server) -> Server, { cfg(self) } /// Add new service to server pub fn bind>(mut self, name: N, addr: U, factory: F) -> io::Result where F: StreamServiceFactory, U: net::ToSocketAddrs, { let sockets = bind_addr(addr)?; for lst in sockets { self = self.listen(name.as_ref(), lst, factory.clone()) } Ok(self) } /// Add new service to server pub fn listen>( mut self, name: N, lst: net::TcpListener, factory: F, ) -> Self where F: StreamServiceFactory, { let token = Token(self.services.len()); self.services .push(StreamNewService::create(name.as_ref().to_string(), factory)); self.sockets.push((token, lst)); self } /// Add new service to server pub fn listen2>( mut self, name: N, lst: net::TcpListener, factory: F, ) -> Self where F: ServiceFactory, { let token = Token(self.services.len()); self.services.push(ServiceNewService::create( name.as_ref().to_string(), factory, )); self.sockets.push((token, lst)); self } /// Spawn new thread and start listening for incoming connections. /// /// This method spawns new thread and starts new actix system. Other than /// that it is similar to `start()` method. This method blocks. /// /// This methods panics if no socket addresses get bound. /// /// ```rust,ignore /// # extern crate futures; /// # extern crate actix_web; /// # use futures::Future; /// use actix_web::*; /// /// fn main() { /// Server::new(). /// .service( /// HttpServer::new(|| App::new().resource("/", |r| r.h(|_| HttpResponse::Ok()))) /// .bind("127.0.0.1:0") /// .expect("Can not bind to 127.0.0.1:0")) /// .run(); /// } /// ``` pub fn run(self) { let sys = System::new("http-server"); self.start(); sys.run(); } /// Starts Server Actor and returns its address pub fn start(mut self) -> Addr { if self.sockets.is_empty() { panic!("Service should have at least one bound socket"); } else { info!("Starting {} workers", self.threads); // start workers let mut workers = Vec::new(); for idx in 0..self.threads { let worker = self.start_worker(idx, self.accept.get_notify()); workers.push(worker.clone()); self.workers.push((idx, worker)); } // start accept thread for sock in &self.sockets { info!("Starting server on {}", sock.1.local_addr().ok().unwrap()); } let rx = self .accept .start(mem::replace(&mut self.sockets, Vec::new()), workers); // start http server actor let signals = self.subscribe_to_signals(); let addr = Actor::create(move |ctx| { ctx.add_stream(rx); self }); if let Some(signals) = signals { signals.do_send(signal::Subscribe(addr.clone().recipient())) } addr } } // subscribe to os signals fn subscribe_to_signals(&self) -> Option> { if !self.no_signals { if let Some(ref signals) = self.signals { Some(signals.clone()) } else { Some(System::current().registry().get::()) } } else { None } } fn start_worker(&self, idx: usize, notify: AcceptNotify) -> WorkerClient { let (tx, rx) = unbounded(); let timeout = self.shutdown_timeout; let avail = WorkerAvailability::new(notify); let worker = WorkerClient::new(idx, tx, avail.clone()); let services: Vec> = self.services.iter().map(|v| v.clone_factory()).collect(); Arbiter::new(format!("actix-net-worker-{}", idx)).do_send(Execute::new(move || { Worker::start(rx, services, avail, timeout.clone()); Ok::<_, ()>(()) })); worker } } impl Actor for Server { type Context = Context; } /// Signals support /// Handle `SIGINT`, `SIGTERM`, `SIGQUIT` signals and stop actix system /// message to `System` actor. impl Handler for Server { type Result = (); fn handle(&mut self, msg: signal::Signal, ctx: &mut Context) { match msg.0 { signal::SignalType::Int => { info!("SIGINT received, exiting"); self.exit = true; Handler::::handle(self, StopServer { graceful: false }, ctx); } signal::SignalType::Term => { info!("SIGTERM received, stopping"); self.exit = true; Handler::::handle(self, StopServer { graceful: true }, ctx); } signal::SignalType::Quit => { info!("SIGQUIT received, exiting"); self.exit = true; Handler::::handle(self, StopServer { graceful: false }, ctx); } _ => (), } } } impl Handler for Server { type Result = (); fn handle(&mut self, _: PauseServer, _: &mut Context) { self.accept.send(Command::Pause); } } impl Handler for Server { type Result = (); fn handle(&mut self, _: ResumeServer, _: &mut Context) { self.accept.send(Command::Resume); } } impl Handler for Server { type Result = Response<(), ()>; fn handle(&mut self, msg: StopServer, ctx: &mut Context) -> Self::Result { // stop accept thread self.accept.send(Command::Stop); // stop workers let (tx, rx) = mpsc::channel(1); for worker in &self.workers { let tx2 = tx.clone(); ctx.spawn( worker .1 .stop(msg.graceful) .into_actor(self) .then(move |_, slf, ctx| { slf.workers.pop(); if slf.workers.is_empty() { let _ = tx2.send(()); // we need to stop system if server was spawned if slf.exit { ctx.run_later(Duration::from_millis(300), |_, _| { System::current().stop(); }); } } fut::ok(()) }), ); } if !self.workers.is_empty() { Response::async(rx.into_future().map(|_| ()).map_err(|_| ())) } else { // we need to stop system if server was spawned if self.exit { ctx.run_later(Duration::from_millis(300), |_, _| { System::current().stop(); }); } Response::reply(Ok(())) } } } /// Commands from accept threads impl StreamHandler for Server { fn finished(&mut self, _: &mut Context) {} fn handle(&mut self, msg: ServerCommand, _: &mut Context) { match msg { ServerCommand::WorkerDied(idx) => { let mut found = false; for i in 0..self.workers.len() { if self.workers[i].0 == idx { self.workers.swap_remove(i); found = true; break; } } if found { error!("Worker has died {:?}, restarting", idx); let mut new_idx = self.workers.len(); 'found: loop { for i in 0..self.workers.len() { if self.workers[i].0 == new_idx { new_idx += 1; continue 'found; } } break; } let worker = self.start_worker(new_idx, self.accept.get_notify()); self.workers.push((new_idx, worker.clone())); self.accept.send(Command::Worker(worker)); } } } } } fn bind_addr(addr: S) -> io::Result> { let mut err = None; let mut succ = false; let mut sockets = Vec::new(); for addr in addr.to_socket_addrs()? { match create_tcp_listener(addr) { Ok(lst) => { succ = true; sockets.push(lst); } Err(e) => err = Some(e), } } if !succ { if let Some(e) = err.take() { Err(e) } else { Err(io::Error::new( io::ErrorKind::Other, "Can not bind to address.", )) } } else { Ok(sockets) } } fn create_tcp_listener(addr: net::SocketAddr) -> io::Result { let builder = match addr { net::SocketAddr::V4(_) => TcpBuilder::new_v4()?, net::SocketAddr::V6(_) => TcpBuilder::new_v6()?, }; builder.reuse_address(true)?; builder.bind(addr)?; Ok(builder.listen(1024)?) }