// Copyright 2015, 2016 Ethcore (UK) Ltd. // This file is part of Parity. // Parity is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // Parity is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // You should have received a copy of the GNU General Public License // along with Parity. If not, see . use std::sync::*; use std::thread::{self, JoinHandle}; use std::collections::HashMap; use mio::*; use crossbeam::sync::chase_lev; use slab::Slab; use error::*; use io::{IoError, IoHandler}; use io::worker::{Worker, Work, WorkType}; use panics::*; /// Timer ID pub type TimerToken = usize; /// Timer ID pub type StreamToken = usize; /// IO Hadndler ID pub type HandlerId = usize; /// Maximum number of tokens a handler can use pub const TOKENS_PER_HANDLER: usize = 16384; const MAX_HANDLERS: usize = 8; /// Messages used to communicate with the event loop from other threads. #[derive(Clone)] pub enum IoMessage where Message: Send + Clone + Sized { /// Shutdown the event loop Shutdown, /// Register a new protocol handler. AddHandler { handler: Arc+Send>, }, RemoveHandler { handler_id: HandlerId, }, AddTimer { handler_id: HandlerId, token: TimerToken, delay: u64, }, RemoveTimer { handler_id: HandlerId, token: TimerToken, }, RegisterStream { handler_id: HandlerId, token: StreamToken, }, DeregisterStream { handler_id: HandlerId, token: StreamToken, }, UpdateStreamRegistration { handler_id: HandlerId, token: StreamToken, }, /// Broadcast a message across all protocol handlers. UserMessage(Message) } /// IO access point. This is passed to all IO handlers and provides an interface to the IO subsystem. pub struct IoContext where Message: Send + Clone + 'static { channel: IoChannel, handler: HandlerId, } impl IoContext where Message: Send + Clone + 'static { /// Create a new IO access point. Takes references to all the data that can be updated within the IO handler. pub fn new(channel: IoChannel, handler: HandlerId) -> IoContext { IoContext { handler: handler, channel: channel, } } /// Register a new IO timer. 'IoHandler::timeout' will be called with the token. pub fn register_timer(&self, token: TimerToken, ms: u64) -> Result<(), UtilError> { try!(self.channel.send_io(IoMessage::AddTimer { token: token, delay: ms, handler_id: self.handler, })); Ok(()) } /// Delete a timer. pub fn clear_timer(&self, token: TimerToken) -> Result<(), UtilError> { try!(self.channel.send_io(IoMessage::RemoveTimer { token: token, handler_id: self.handler, })); Ok(()) } /// Register a new IO stream. pub fn register_stream(&self, token: StreamToken) -> Result<(), UtilError> { try!(self.channel.send_io(IoMessage::RegisterStream { token: token, handler_id: self.handler, })); Ok(()) } /// Deregister an IO stream. pub fn deregister_stream(&self, token: StreamToken) -> Result<(), UtilError> { try!(self.channel.send_io(IoMessage::DeregisterStream { token: token, handler_id: self.handler, })); Ok(()) } /// Reregister an IO stream. pub fn update_registration(&self, token: StreamToken) -> Result<(), UtilError> { try!(self.channel.send_io(IoMessage::UpdateStreamRegistration { token: token, handler_id: self.handler, })); Ok(()) } /// Broadcast a message to other IO clients pub fn message(&self, message: Message) -> Result<(), UtilError> { try!(self.channel.send(message)); Ok(()) } /// Get message channel pub fn channel(&self) -> IoChannel { self.channel.clone() } /// Unregister current IO handler. pub fn unregister_handler(&self) -> Result<(), IoError> { try!(self.channel.send_io(IoMessage::RemoveHandler { handler_id: self.handler, })); Ok(()) } } #[derive(Clone)] struct UserTimer { delay: u64, timeout: Timeout, } /// Root IO handler. Manages user handlers, messages and IO timers. pub struct IoManager where Message: Send + Sync { timers: Arc>>, handlers: Slab>, HandlerId>, workers: Vec, worker_channel: chase_lev::Worker>, work_ready: Arc, } impl IoManager where Message: Send + Sync + Clone + 'static { /// Creates a new instance and registers it with the event loop. pub fn start(panic_handler: Arc, event_loop: &mut EventLoop>) -> Result<(), UtilError> { let (worker, stealer) = chase_lev::deque(); let num_workers = 4; let work_ready_mutex = Arc::new(Mutex::new(())); let work_ready = Arc::new(Condvar::new()); let workers = (0..num_workers).map(|i| Worker::new( i, stealer.clone(), IoChannel::new(event_loop.channel()), work_ready.clone(), work_ready_mutex.clone(), panic_handler.clone() ) ).collect(); let mut io = IoManager { timers: Arc::new(RwLock::new(HashMap::new())), handlers: Slab::new(MAX_HANDLERS), worker_channel: worker, workers: workers, work_ready: work_ready, }; try!(event_loop.run(&mut io)); Ok(()) } } impl Handler for IoManager where Message: Send + Clone + Sync + 'static { type Timeout = Token; type Message = IoMessage; fn ready(&mut self, _event_loop: &mut EventLoop, token: Token, events: EventSet) { let handler_index = token.as_usize() / TOKENS_PER_HANDLER; let token_id = token.as_usize() % TOKENS_PER_HANDLER; if let Some(handler) = self.handlers.get(handler_index) { if events.is_hup() { self.worker_channel.push(Work { work_type: WorkType::Hup, token: token_id, handler: handler.clone(), handler_id: handler_index }); } else { if events.is_readable() { self.worker_channel.push(Work { work_type: WorkType::Readable, token: token_id, handler: handler.clone(), handler_id: handler_index }); } if events.is_writable() { self.worker_channel.push(Work { work_type: WorkType::Writable, token: token_id, handler: handler.clone(), handler_id: handler_index }); } } self.work_ready.notify_all(); } } fn timeout(&mut self, event_loop: &mut EventLoop, token: Token) { let handler_index = token.as_usize() / TOKENS_PER_HANDLER; let token_id = token.as_usize() % TOKENS_PER_HANDLER; if let Some(handler) = self.handlers.get(handler_index) { if let Some(timer) = self.timers.read().unwrap().get(&token.as_usize()) { event_loop.timeout_ms(token, timer.delay).expect("Error re-registering user timer"); self.worker_channel.push(Work { work_type: WorkType::Timeout, token: token_id, handler: handler.clone(), handler_id: handler_index }); self.work_ready.notify_all(); } } } fn notify(&mut self, event_loop: &mut EventLoop, msg: Self::Message) { match msg { IoMessage::Shutdown => { self.workers.clear(); event_loop.shutdown(); }, IoMessage::AddHandler { handler } => { let handler_id = self.handlers.insert(handler.clone()).unwrap_or_else(|_| panic!("Too many handlers registered")); handler.initialize(&IoContext::new(IoChannel::new(event_loop.channel()), handler_id)); }, IoMessage::RemoveHandler { handler_id } => { // TODO: flush event loop self.handlers.remove(handler_id); // unregister timers let mut timers = self.timers.write().unwrap(); let to_remove: Vec<_> = timers.keys().cloned().filter(|timer_id| timer_id / TOKENS_PER_HANDLER == handler_id).collect(); for timer_id in to_remove { let timer = timers.remove(&timer_id).expect("to_remove only contains keys from timers; qed"); event_loop.clear_timeout(timer.timeout); } }, IoMessage::AddTimer { handler_id, token, delay } => { let timer_id = token + handler_id * TOKENS_PER_HANDLER; let timeout = event_loop.timeout_ms(Token(timer_id), delay).expect("Error registering user timer"); self.timers.write().unwrap().insert(timer_id, UserTimer { delay: delay, timeout: timeout }); }, IoMessage::RemoveTimer { handler_id, token } => { let timer_id = token + handler_id * TOKENS_PER_HANDLER; if let Some(timer) = self.timers.write().unwrap().remove(&timer_id) { event_loop.clear_timeout(timer.timeout); } }, IoMessage::RegisterStream { handler_id, token } => { if let Some(handler) = self.handlers.get(handler_id) { handler.register_stream(token, Token(token + handler_id * TOKENS_PER_HANDLER), event_loop); } }, IoMessage::DeregisterStream { handler_id, token } => { if let Some(handler) = self.handlers.get(handler_id) { handler.deregister_stream(token, event_loop); // unregister a timer associated with the token (if any) let timer_id = token + handler_id * TOKENS_PER_HANDLER; if let Some(timer) = self.timers.write().unwrap().remove(&timer_id) { event_loop.clear_timeout(timer.timeout); } } }, IoMessage::UpdateStreamRegistration { handler_id, token } => { if let Some(handler) = self.handlers.get(handler_id) { handler.update_stream(token, Token(token + handler_id * TOKENS_PER_HANDLER), event_loop); } }, IoMessage::UserMessage(data) => { //TODO: better way to iterate the slab for id in 0 .. MAX_HANDLERS { if let Some(h) = self.handlers.get(id) { let handler = h.clone(); self.worker_channel.push(Work { work_type: WorkType::Message(data.clone()), token: 0, handler: handler, handler_id: id }); } } self.work_ready.notify_all(); } } } } /// Allows sending messages into the event loop. All the IO handlers will get the message /// in the `message` callback. pub struct IoChannel where Message: Send + Clone{ channel: Option>> } impl Clone for IoChannel where Message: Send + Clone { fn clone(&self) -> IoChannel { IoChannel { channel: self.channel.clone() } } } impl IoChannel where Message: Send + Clone { /// Send a msessage through the channel pub fn send(&self, message: Message) -> Result<(), IoError> { if let Some(ref channel) = self.channel { try!(channel.send(IoMessage::UserMessage(message))); } Ok(()) } /// Send low level io message pub fn send_io(&self, message: IoMessage) -> Result<(), IoError> { if let Some(ref channel) = self.channel { try!(channel.send(message)) } Ok(()) } /// Create a new channel to connected to event loop. pub fn disconnected() -> IoChannel { IoChannel { channel: None } } fn new(channel: Sender>) -> IoChannel { IoChannel { channel: Some(channel) } } } /// General IO Service. Starts an event loop and dispatches IO requests. /// 'Message' is a notification message type pub struct IoService where Message: Send + Sync + Clone + 'static { panic_handler: Arc, thread: Option>, host_channel: Sender>, } impl MayPanic for IoService where Message: Send + Sync + Clone + 'static { fn on_panic(&self, closure: F) where F: OnPanicListener { self.panic_handler.on_panic(closure); } } impl IoService where Message: Send + Sync + Clone + 'static { /// Starts IO event loop pub fn start() -> Result, UtilError> { let panic_handler = PanicHandler::new_in_arc(); let mut config = EventLoopConfig::new(); config.messages_per_tick(1024); let mut event_loop = EventLoop::configured(config).expect("Error creating event loop"); let channel = event_loop.channel(); let panic = panic_handler.clone(); let thread = thread::spawn(move || { let p = panic.clone(); panic.catch_panic(move || { IoManager::::start(p, &mut event_loop).unwrap(); }).unwrap() }); Ok(IoService { panic_handler: panic_handler, thread: Some(thread), host_channel: channel }) } /// Regiter an IO handler with the event loop. pub fn register_handler(&self, handler: Arc+Send>) -> Result<(), IoError> { try!(self.host_channel.send(IoMessage::AddHandler { handler: handler, })); Ok(()) } /// Send a message over the network. Normaly `HostIo::send` should be used. This can be used from non-io threads. pub fn send_message(&self, message: Message) -> Result<(), IoError> { try!(self.host_channel.send(IoMessage::UserMessage(message))); Ok(()) } /// Create a new message channel pub fn channel(&self) -> IoChannel { IoChannel { channel: Some(self.host_channel.clone()) } } } impl Drop for IoService where Message: Send + Sync + Clone { fn drop(&mut self) { trace!(target: "shutdown", "[IoService] Closing..."); self.host_channel.send(IoMessage::Shutdown).unwrap_or_else(|e| warn!("Error on IO service shutdown: {:?}", e)); self.thread.take().unwrap().join().ok(); trace!(target: "shutdown", "[IoService] Closed."); } }