Multithreaded event loop

This commit is contained in:
arkpar 2016-01-21 16:48:37 +01:00
parent 77d2303b55
commit e514d3d80f
17 changed files with 661 additions and 507 deletions

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@ -30,13 +30,15 @@ impl EthashManager {
/// `nonce` - The nonce to pack into the mix
pub fn compute_light(&self, block_number: u64, header_hash: &H256, nonce: u64) -> ProofOfWork {
let epoch = block_number / ETHASH_EPOCH_LENGTH;
if !self.lights.read().unwrap().contains_key(&epoch) {
let mut lights = self.lights.write().unwrap(); // obtain write lock
while !self.lights.read().unwrap().contains_key(&epoch) {
if let Ok(mut lights) = self.lights.try_write()
{
if !lights.contains_key(&epoch) {
let light = Light::new(block_number);
lights.insert(epoch, light);
}
}
}
self.lights.read().unwrap().get(&epoch).unwrap().compute(header_hash, nonce)
}
}

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@ -29,7 +29,7 @@ fn main() {
setup_log();
let spec = ethereum::new_frontier();
let mut service = ClientService::start(spec).unwrap();
let io_handler = Box::new(ClientIoHandler { client: service.client(), timer: 0 });
let io_handler = Arc::new(ClientIoHandler { client: service.client() });
service.io().register_handler(io_handler).expect("Error registering IO handler");
loop {
let mut cmd = String::new();
@ -43,16 +43,15 @@ fn main() {
struct ClientIoHandler {
client: Arc<RwLock<Client>>,
timer: TimerToken,
}
impl IoHandler<NetSyncMessage> for ClientIoHandler {
fn initialize<'s>(&'s mut self, io: &mut IoContext<'s, NetSyncMessage>) {
self.timer = io.register_timer(5000).expect("Error registering timer");
fn initialize(&self, io: &IoContext<NetSyncMessage>) {
io.register_timer(0, 5000).expect("Error registering timer");
}
fn timeout<'s>(&'s mut self, _io: &mut IoContext<'s, NetSyncMessage>, timer: TimerToken) {
if self.timer == timer {
fn timeout(&self, _io: &IoContext<NetSyncMessage>, timer: TimerToken) {
if timer == 0 {
println!("Chain info: {:?}", self.client.read().unwrap().deref().chain_info());
}
}

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@ -1,6 +1,5 @@
use util::*;
use rocksdb::{Options, DB};
use rocksdb::DBCompactionStyle::DBUniversalCompaction;
use blockchain::{BlockChain, BlockProvider};
use views::BlockView;
use error::*;
@ -113,7 +112,9 @@ impl Client {
pub fn new(spec: Spec, path: &Path, message_channel: IoChannel<NetSyncMessage> ) -> Result<Client, Error> {
let chain = Arc::new(RwLock::new(BlockChain::new(&spec.genesis_block(), path)));
let mut opts = Options::new();
opts.set_max_open_files(256);
opts.create_if_missing(true);
/*
opts.set_max_open_files(256);
opts.set_use_fsync(false);
opts.set_bytes_per_sync(8388608);
@ -131,6 +132,7 @@ impl Client {
opts.set_max_background_flushes(4);
opts.set_filter_deletes(false);
opts.set_disable_auto_compactions(true);
*/
let mut state_path = path.to_path_buf();
state_path.push("state");
@ -219,7 +221,7 @@ impl Client {
return;
}
}
info!(target: "client", "Imported #{} ({})", header.number(), header.hash());
//info!(target: "client", "Imported #{} ({})", header.number(), header.hash());
}
}
}

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@ -22,7 +22,7 @@ impl ClientService {
dir.push(H64::from(spec.genesis_header().hash()).hex());
let client = Arc::new(RwLock::new(try!(Client::new(spec, &dir, net_service.io().channel()))));
EthSync::register(&mut net_service, client.clone());
let client_io = Box::new(ClientIoHandler {
let client_io = Arc::new(ClientIoHandler {
client: client.clone()
});
try!(net_service.io().register_handler(client_io));
@ -48,14 +48,14 @@ struct ClientIoHandler {
}
impl IoHandler<NetSyncMessage> for ClientIoHandler {
fn initialize<'s>(&'s mut self, _io: &mut IoContext<'s, NetSyncMessage>) {
fn initialize(&self, _io: &IoContext<NetSyncMessage>) {
}
fn message<'s>(&'s mut self, _io: &mut IoContext<'s, NetSyncMessage>, net_message: &'s mut NetSyncMessage) {
fn message(&self, _io: &IoContext<NetSyncMessage>, net_message: &NetSyncMessage) {
match net_message {
&mut UserMessage(ref mut message) => {
&UserMessage(ref message) => {
match message {
&mut SyncMessage::BlockVerified => {
&SyncMessage::BlockVerified => {
self.client.write().unwrap().import_verified_blocks();
},
_ => {}, // ignore other messages

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@ -424,6 +424,10 @@ impl ChainSync {
let peer_difficulty = self.peers.get_mut(&peer_id).expect("ChainSync: unknown peer").difficulty;
if difficulty > peer_difficulty {
trace!(target: "sync", "Received block {:?} with no known parent. Peer needs syncing...", h);
{
let peer = self.peers.get_mut(&peer_id).expect("ChainSync: unknown peer");
peer.latest = header_view.sha3();
}
self.sync_peer(io, peer_id, true);
}
}

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@ -22,14 +22,14 @@ pub trait SyncIo {
}
/// Wraps `NetworkContext` and the blockchain client
pub struct NetSyncIo<'s, 'h, 'io> where 'h: 's, 'io: 'h {
network: &'s mut NetworkContext<'h, 'io, SyncMessage>,
pub struct NetSyncIo<'s, 'h> where 'h: 's {
network: &'s NetworkContext<'h, SyncMessage>,
chain: &'s mut BlockChainClient
}
impl<'s, 'h, 'io> NetSyncIo<'s, 'h, 'io> {
impl<'s, 'h> NetSyncIo<'s, 'h> {
/// Creates a new instance from the `NetworkContext` and the blockchain client reference.
pub fn new(network: &'s mut NetworkContext<'h, 'io, SyncMessage>, chain: &'s mut BlockChainClient) -> NetSyncIo<'s,'h,'io> {
pub fn new(network: &'s NetworkContext<'h, SyncMessage>, chain: &'s mut BlockChainClient) -> NetSyncIo<'s, 'h> {
NetSyncIo {
network: network,
chain: chain,
@ -37,7 +37,7 @@ impl<'s, 'h, 'io> NetSyncIo<'s, 'h, 'io> {
}
}
impl<'s, 'h, 'op> SyncIo for NetSyncIo<'s, 'h, 'op> {
impl<'s, 'h> SyncIo for NetSyncIo<'s, 'h> {
fn disable_peer(&mut self, peer_id: PeerId) {
self.network.disable_peer(peer_id);
}

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@ -26,9 +26,8 @@ use std::ops::*;
use std::sync::*;
use client::Client;
use util::network::{NetworkProtocolHandler, NetworkService, NetworkContext, PeerId, NetworkIoMessage};
use util::TimerToken;
use util::Bytes;
use sync::chain::ChainSync;
use util::{Bytes, TimerToken};
use sync::io::NetSyncIo;
mod chain;
@ -38,10 +37,13 @@ mod range_collection;
#[cfg(test)]
mod tests;
const SYNC_TIMER: usize = 0;
/// Message type for external events
#[derive(Clone)]
pub enum SyncMessage {
/// New block has been imported into the blockchain
NewChainBlock(Bytes),
NewChainBlock(Bytes), //TODO: use Cow
/// A block is ready
BlockVerified,
}
@ -53,7 +55,7 @@ pub struct EthSync {
/// Shared blockchain client. TODO: this should evetually become an IPC endpoint
chain: Arc<RwLock<Client>>,
/// Sync strategy
sync: ChainSync
sync: RwLock<ChainSync>
}
pub use self::chain::SyncStatus;
@ -61,52 +63,50 @@ pub use self::chain::SyncStatus;
impl EthSync {
/// Creates and register protocol with the network service
pub fn register(service: &mut NetworkService<SyncMessage>, chain: Arc<RwLock<Client>>) {
let sync = Box::new(EthSync {
let sync = Arc::new(EthSync {
chain: chain,
sync: ChainSync::new(),
sync: RwLock::new(ChainSync::new()),
});
service.register_protocol(sync, "eth", &[62u8, 63u8]).expect("Error registering eth protocol handler");
service.register_protocol(sync.clone(), "eth", &[62u8, 63u8]).expect("Error registering eth protocol handler");
}
/// Get sync status
pub fn status(&self) -> SyncStatus {
self.sync.status()
self.sync.read().unwrap().status()
}
/// Stop sync
pub fn stop(&mut self, io: &mut NetworkContext<SyncMessage>) {
self.sync.abort(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()));
self.sync.write().unwrap().abort(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()));
}
/// Restart sync
pub fn restart(&mut self, io: &mut NetworkContext<SyncMessage>) {
self.sync.restart(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()));
self.sync.write().unwrap().restart(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()));
}
}
impl NetworkProtocolHandler<SyncMessage> for EthSync {
fn initialize(&mut self, io: &mut NetworkContext<SyncMessage>) {
self.sync.restart(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()));
io.register_timer(1000).unwrap();
fn initialize(&self, io: &NetworkContext<SyncMessage>) {
io.register_timer(SYNC_TIMER, 1000).unwrap();
}
fn read(&mut self, io: &mut NetworkContext<SyncMessage>, peer: &PeerId, packet_id: u8, data: &[u8]) {
self.sync.on_packet(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()) , *peer, packet_id, data);
fn read(&self, io: &NetworkContext<SyncMessage>, peer: &PeerId, packet_id: u8, data: &[u8]) {
self.sync.write().unwrap().on_packet(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()) , *peer, packet_id, data);
}
fn connected(&mut self, io: &mut NetworkContext<SyncMessage>, peer: &PeerId) {
self.sync.on_peer_connected(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()), *peer);
fn connected(&self, io: &NetworkContext<SyncMessage>, peer: &PeerId) {
self.sync.write().unwrap().on_peer_connected(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()), *peer);
}
fn disconnected(&mut self, io: &mut NetworkContext<SyncMessage>, peer: &PeerId) {
self.sync.on_peer_aborting(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()), *peer);
fn disconnected(&self, io: &NetworkContext<SyncMessage>, peer: &PeerId) {
self.sync.write().unwrap().on_peer_aborting(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()), *peer);
}
fn timeout(&mut self, io: &mut NetworkContext<SyncMessage>, _timer: TimerToken) {
self.sync.maintain_sync(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()));
fn timeout(&self, io: &NetworkContext<SyncMessage>, timer: TimerToken) {
if timer == SYNC_TIMER {
self.sync.write().unwrap().maintain_sync(&mut NetSyncIo::new(io, self.chain.write().unwrap().deref_mut()));
}
fn message(&mut self, _io: &mut NetworkContext<SyncMessage>, _message: &SyncMessage) {
}
}

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@ -22,6 +22,7 @@ rust-crypto = "0.2.34"
elastic-array = "0.4"
heapsize = "0.2"
itertools = "0.4"
crossbeam = "0.2"
slab = { git = "https://github.com/arkpar/slab.git" }
sha3 = { path = "sha3" }

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@ -36,13 +36,16 @@
/// }
/// ```
mod service;
mod worker;
use mio::{EventLoop, Token};
#[derive(Debug)]
pub enum IoError {
Mio(::std::io::Error),
}
impl<Message> From<::mio::NotifyError<service::IoMessage<Message>>> for IoError where Message: Send {
impl<Message> From<::mio::NotifyError<service::IoMessage<Message>>> for IoError where Message: Send + Clone {
fn from(_err: ::mio::NotifyError<service::IoMessage<Message>>) -> IoError {
IoError::Mio(::std::io::Error::new(::std::io::ErrorKind::ConnectionAborted, "Network IO notification error"))
}
@ -51,27 +54,32 @@ impl<Message> From<::mio::NotifyError<service::IoMessage<Message>>> for IoError
/// Generic IO handler.
/// All the handler function are called from within IO event loop.
/// `Message` type is used as notification data
pub trait IoHandler<Message>: Send where Message: Send + 'static {
pub trait IoHandler<Message>: Send + Sync where Message: Send + Sync + Clone + 'static {
/// Initialize the handler
fn initialize<'s>(&'s mut self, _io: &mut IoContext<'s, Message>) {}
fn initialize(&self, _io: &IoContext<Message>) {}
/// Timer function called after a timeout created with `HandlerIo::timeout`.
fn timeout<'s>(&'s mut self, _io: &mut IoContext<'s, Message>, _timer: TimerToken) {}
fn timeout(&self, _io: &IoContext<Message>, _timer: TimerToken) {}
/// Called when a broadcasted message is received. The message can only be sent from a different IO handler.
fn message<'s>(&'s mut self, _io: &mut IoContext<'s, Message>, _message: &'s mut Message) {} // TODO: make message immutable and provide internal channel for adding network handler
fn message(&self, _io: &IoContext<Message>, _message: &Message) {}
/// Called when an IO stream gets closed
fn stream_hup<'s>(&'s mut self, _io: &mut IoContext<'s, Message>, _stream: StreamToken) {}
fn stream_hup(&self, _io: &IoContext<Message>, _stream: StreamToken) {}
/// Called when an IO stream can be read from
fn stream_readable<'s>(&'s mut self, _io: &mut IoContext<'s, Message>, _stream: StreamToken) {}
fn stream_readable(&self, _io: &IoContext<Message>, _stream: StreamToken) {}
/// Called when an IO stream can be written to
fn stream_writable<'s>(&'s mut self, _io: &mut IoContext<'s, Message>, _stream: StreamToken) {}
fn stream_writable(&self, _io: &IoContext<Message>, _stream: StreamToken) {}
/// Register a new stream with the event loop
fn register_stream(&self, _stream: StreamToken, _reg: Token, _event_loop: &mut EventLoop<IoManager<Message>>) {}
/// Re-register a stream with the event loop
fn update_stream(&self, _stream: StreamToken, _reg: Token, _event_loop: &mut EventLoop<IoManager<Message>>) {}
}
pub type TimerToken = service::TimerToken;
pub type StreamToken = service::StreamToken;
pub type IoContext<'s, M> = service::IoContext<'s, M>;
pub type IoService<M> = service::IoService<M>;
pub type IoChannel<M> = service::IoChannel<M>;
//pub const USER_TOKEN_START: usize = service::USER_TOKEN; // TODO: ICE in rustc 1.7.0-nightly (49c382779 2016-01-12)
pub use io::service::IoContext;
pub type IoService<Message> = service::IoService<Message>;
pub type IoChannel<Message> = service::IoChannel<Message>;
pub type IoManager<Message> = service::IoManager<Message>;
pub const TOKENS_PER_HANDLER: usize = service::TOKENS_PER_HANDLER;
#[cfg(test)]
mod tests {

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@ -1,148 +1,221 @@
use std::sync::*;
use std::thread::{self, JoinHandle};
use std::collections::HashMap;
use mio::*;
use mio::util::{Slab};
use hash::*;
use rlp::*;
use error::*;
use io::{IoError, IoHandler};
use arrayvec::*;
use crossbeam::sync::chase_lev;
use io::worker::{Worker, Work, WorkType};
pub type TimerToken = usize;
pub type StreamToken = usize;
pub type HandlerId = usize;
// Tokens
const MAX_USER_TIMERS: usize = 32;
const USER_TIMER: usize = 0;
const LAST_USER_TIMER: usize = USER_TIMER + MAX_USER_TIMERS - 1;
//const USER_TOKEN: usize = LAST_USER_TIMER + 1;
pub const TOKENS_PER_HANDLER: usize = 16384;
/// Messages used to communicate with the event loop from other threads.
pub enum IoMessage<Message> where Message: Send + Sized {
#[derive(Clone)]
pub enum IoMessage<Message> where Message: Send + Clone + Sized {
/// Shutdown the event loop
Shutdown,
/// Register a new protocol handler.
AddHandler {
handler: Box<IoHandler<Message>+Send>,
handler: Arc<IoHandler<Message>+Send>,
},
AddTimer {
handler_id: HandlerId,
token: TimerToken,
delay: u64,
},
RemoveTimer {
handler_id: HandlerId,
token: TimerToken,
},
RegisterStream {
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<'s, Message> where Message: Send + 'static {
timers: &'s mut Slab<UserTimer>,
/// Low leve MIO Event loop for custom handler registration.
pub event_loop: &'s mut EventLoop<IoManager<Message>>,
pub struct IoContext<Message> where Message: Send + Clone + 'static {
pub channel: IoChannel<Message>,
pub handler: HandlerId,
}
impl<'s, Message> IoContext<'s, Message> where Message: Send + 'static {
impl<Message> IoContext<Message> 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.
fn new(event_loop: &'s mut EventLoop<IoManager<Message>>, timers: &'s mut Slab<UserTimer>) -> IoContext<'s, Message> {
pub fn new(channel: IoChannel<Message>, handler: HandlerId) -> IoContext<Message> {
IoContext {
event_loop: event_loop,
timers: timers,
handler: handler,
channel: channel,
}
}
/// Register a new IO timer. Returns a new timer token. 'IoHandler::timeout' will be called with the token.
pub fn register_timer(&mut self, ms: u64) -> Result<TimerToken, UtilError> {
match self.timers.insert(UserTimer {
/// 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,
}) {
Ok(token) => {
self.event_loop.timeout_ms(token, ms).expect("Error registering user timer");
Ok(token.as_usize())
},
_ => { panic!("Max timers reached") }
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(())
}
/// 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(&mut self, message: Message) {
match self.event_loop.channel().send(IoMessage::UserMessage(message)) {
Ok(_) => {}
Err(e) => { panic!("Error sending io message {:?}", e); }
}
pub fn message(&self, message: Message) {
self.channel.send(message).expect("Error seding message");
}
}
#[derive(Clone)]
struct UserTimer {
delay: u64,
timeout: Timeout,
}
/// Root IO handler. Manages user handlers, messages and IO timers.
pub struct IoManager<Message> where Message: Send {
timers: Slab<UserTimer>,
handlers: Vec<Box<IoHandler<Message>>>,
pub struct IoManager<Message> where Message: Send + Sync {
timers: Arc<RwLock<HashMap<HandlerId, UserTimer>>>,
handlers: Vec<Arc<IoHandler<Message>>>,
_workers: Vec<Worker>,
worker_channel: chase_lev::Worker<Work<Message>>,
work_ready: Arc<Condvar>,
}
impl<Message> IoManager<Message> where Message: Send + 'static {
impl<Message> IoManager<Message> where Message: Send + Sync + Clone + 'static {
/// Creates a new instance and registers it with the event loop.
pub fn start(event_loop: &mut EventLoop<IoManager<Message>>) -> Result<(), UtilError> {
let (worker, stealer) = chase_lev::deque();
let num_workers = 4;
let work_ready_mutex = Arc::new(Mutex::new(false));
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())).collect();
let mut io = IoManager {
timers: Slab::new_starting_at(Token(USER_TIMER), MAX_USER_TIMERS),
timers: Arc::new(RwLock::new(HashMap::new())),
handlers: Vec::new(),
worker_channel: worker,
_workers: workers,
work_ready: work_ready,
};
try!(event_loop.run(&mut io));
Ok(())
}
}
impl<Message> Handler for IoManager<Message> where Message: Send + 'static {
impl<Message> Handler for IoManager<Message> where Message: Send + Clone + Sync + 'static {
type Timeout = Token;
type Message = IoMessage<Message>;
fn ready(&mut self, event_loop: &mut EventLoop<Self>, token: Token, events: EventSet) {
fn ready(&mut self, _event_loop: &mut EventLoop<Self>, token: Token, events: EventSet) {
let handler_index = token.as_usize() / TOKENS_PER_HANDLER;
let token_id = token.as_usize() % TOKENS_PER_HANDLER;
if handler_index >= self.handlers.len() {
panic!("Unexpected stream token: {}", token.as_usize());
}
let handler = self.handlers[handler_index].clone();
if events.is_hup() {
for h in self.handlers.iter_mut() {
h.stream_hup(&mut IoContext::new(event_loop, &mut self.timers), token.as_usize());
}
}
else if events.is_readable() {
for h in self.handlers.iter_mut() {
h.stream_readable(&mut IoContext::new(event_loop, &mut self.timers), token.as_usize());
}
}
else if events.is_writable() {
for h in self.handlers.iter_mut() {
h.stream_writable(&mut IoContext::new(event_loop, &mut self.timers), token.as_usize());
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<Self>, token: Token) {
match token.as_usize() {
USER_TIMER ... LAST_USER_TIMER => {
let delay = {
let timer = self.timers.get_mut(token).expect("Unknown user timer token");
timer.delay
};
for h in self.handlers.iter_mut() {
h.timeout(&mut IoContext::new(event_loop, &mut self.timers), token.as_usize());
}
event_loop.timeout_ms(token, delay).expect("Error re-registering user timer");
}
_ => { // Just pass the event down. IoHandler is supposed to re-register it if required.
for h in self.handlers.iter_mut() {
h.timeout(&mut IoContext::new(event_loop, &mut self.timers), token.as_usize());
}
let handler_index = token.as_usize() / TOKENS_PER_HANDLER;
let token_id = token.as_usize() % TOKENS_PER_HANDLER;
if handler_index >= self.handlers.len() {
panic!("Unexpected timer token: {}", token.as_usize());
}
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");
let handler = self.handlers[handler_index].clone();
self.worker_channel.push(Work { work_type: WorkType::Timeout, token: token_id, handler: handler, handler_id: handler_index });
self.work_ready.notify_all();
}
}
fn notify(&mut self, event_loop: &mut EventLoop<Self>, msg: Self::Message) {
let mut m = msg;
match m {
match msg {
IoMessage::Shutdown => event_loop.shutdown(),
IoMessage::AddHandler {
handler,
} => {
self.handlers.push(handler);
self.handlers.last_mut().unwrap().initialize(&mut IoContext::new(event_loop, &mut self.timers));
IoMessage::AddHandler { handler } => {
let handler_id = {
self.handlers.push(handler.clone());
self.handlers.len() - 1
};
handler.initialize(&IoContext::new(IoChannel::new(event_loop.channel()), handler_id));
},
IoMessage::UserMessage(ref mut data) => {
for h in self.handlers.iter_mut() {
h.message(&mut IoContext::new(event_loop, &mut self.timers), data);
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 } => {
let handler = self.handlers.get(handler_id).expect("Unknown handler id").clone();
handler.register_stream(token, Token(token + handler_id * TOKENS_PER_HANDLER), event_loop);
},
IoMessage::UpdateStreamRegistration { handler_id, token } => {
let handler = self.handlers.get(handler_id).expect("Unknown handler id").clone();
handler.update_stream(token, Token(token + handler_id * TOKENS_PER_HANDLER), event_loop);
},
IoMessage::UserMessage(data) => {
for n in 0 .. self.handlers.len() {
let handler = self.handlers[n].clone();
self.worker_channel.push(Work { work_type: WorkType::Message(data.clone()), token: 0, handler: handler, handler_id: n });
}
self.work_ready.notify_all();
}
}
}
@ -150,11 +223,19 @@ impl<Message> Handler for IoManager<Message> where Message: Send + 'static {
/// Allows sending messages into the event loop. All the IO handlers will get the message
/// in the `message` callback.
pub struct IoChannel<Message> where Message: Send {
pub struct IoChannel<Message> where Message: Send + Clone{
channel: Option<Sender<IoMessage<Message>>>
}
impl<Message> IoChannel<Message> where Message: Send {
impl<Message> Clone for IoChannel<Message> where Message: Send + Clone {
fn clone(&self) -> IoChannel<Message> {
IoChannel {
channel: self.channel.clone()
}
}
}
impl<Message> IoChannel<Message> 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 {
@ -163,20 +244,30 @@ impl<Message> IoChannel<Message> where Message: Send {
Ok(())
}
pub fn send_io(&self, message: IoMessage<Message>) -> 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<Message> {
IoChannel { channel: None }
}
fn new(channel: Sender<IoMessage<Message>>) -> IoChannel<Message> {
IoChannel { channel: Some(channel) }
}
}
/// General IO Service. Starts an event loop and dispatches IO requests.
/// 'Message' is a notification message type
pub struct IoService<Message> where Message: Send + 'static {
pub struct IoService<Message> where Message: Send + Sync + Clone + 'static {
thread: Option<JoinHandle<()>>,
host_channel: Sender<IoMessage<Message>>
host_channel: Sender<IoMessage<Message>>,
}
impl<Message> IoService<Message> where Message: Send + 'static {
impl<Message> IoService<Message> where Message: Send + Sync + Clone + 'static {
/// Starts IO event loop
pub fn start() -> Result<IoService<Message>, UtilError> {
let mut event_loop = EventLoop::new().unwrap();
@ -191,7 +282,7 @@ impl<Message> IoService<Message> where Message: Send + 'static {
}
/// Regiter a IO hadnler with the event loop.
pub fn register_handler(&mut self, handler: Box<IoHandler<Message>+Send>) -> Result<(), IoError> {
pub fn register_handler(&mut self, handler: Arc<IoHandler<Message>+Send>) -> Result<(), IoError> {
try!(self.host_channel.send(IoMessage::AddHandler {
handler: handler,
}));
@ -210,7 +301,7 @@ impl<Message> IoService<Message> where Message: Send + 'static {
}
}
impl<Message> Drop for IoService<Message> where Message: Send {
impl<Message> Drop for IoService<Message> where Message: Send + Sync + Clone {
fn drop(&mut self) {
self.host_channel.send(IoMessage::Shutdown).unwrap();
self.thread.take().unwrap().join().unwrap();

View File

@ -51,6 +51,7 @@ extern crate crypto as rcrypto;
extern crate secp256k1;
extern crate arrayvec;
extern crate elastic_array;
extern crate crossbeam;
pub mod standard;
#[macro_use]

View File

@ -1,5 +1,5 @@
use std::collections::VecDeque;
use mio::{Handler, Token, EventSet, EventLoop, Timeout, PollOpt, TryRead, TryWrite};
use mio::{Handler, Token, EventSet, EventLoop, PollOpt, TryRead, TryWrite};
use mio::tcp::*;
use hash::*;
use sha3::*;
@ -7,6 +7,7 @@ use bytes::*;
use rlp::*;
use std::io::{self, Cursor, Read};
use error::*;
use io::{IoContext, StreamToken};
use network::error::NetworkError;
use network::handshake::Handshake;
use crypto;
@ -17,11 +18,12 @@ use rcrypto::buffer::*;
use tiny_keccak::Keccak;
const ENCRYPTED_HEADER_LEN: usize = 32;
const RECIEVE_PAYLOAD_TIMEOUT: u64 = 30000;
/// Low level tcp connection
pub struct Connection {
/// Connection id (token)
pub token: Token,
pub token: StreamToken,
/// Network socket
pub socket: TcpStream,
/// Receive buffer
@ -45,14 +47,14 @@ pub enum WriteStatus {
impl Connection {
/// Create a new connection with given id and socket.
pub fn new(token: Token, socket: TcpStream) -> Connection {
pub fn new(token: StreamToken, socket: TcpStream) -> Connection {
Connection {
token: token,
socket: socket,
send_queue: VecDeque::new(),
rec_buf: Bytes::new(),
rec_size: 0,
interest: EventSet::hup(),
interest: EventSet::hup() | EventSet::readable(),
}
}
@ -132,20 +134,19 @@ impl Connection {
}
/// Register this connection with the IO event loop.
pub fn register<Host: Handler>(&mut self, event_loop: &mut EventLoop<Host>) -> io::Result<()> {
trace!(target: "net", "connection register; token={:?}", self.token);
self.interest.insert(EventSet::readable());
event_loop.register(&self.socket, self.token, self.interest, PollOpt::edge() | PollOpt::oneshot()).or_else(|e| {
error!("Failed to register {:?}, {:?}", self.token, e);
pub fn register_socket<Host: Handler>(&self, reg: Token, event_loop: &mut EventLoop<Host>) -> io::Result<()> {
trace!(target: "net", "connection register; token={:?}", reg);
event_loop.register(&self.socket, reg, self.interest, PollOpt::edge() | PollOpt::oneshot()).or_else(|e| {
error!("Failed to register {:?}, {:?}", reg, e);
Err(e)
})
}
/// Update connection registration. Should be called at the end of the IO handler.
pub fn reregister<Host: Handler>(&mut self, event_loop: &mut EventLoop<Host>) -> io::Result<()> {
trace!(target: "net", "connection reregister; token={:?}", self.token);
event_loop.reregister( &self.socket, self.token, self.interest, PollOpt::edge() | PollOpt::oneshot()).or_else(|e| {
error!("Failed to reregister {:?}, {:?}", self.token, e);
pub fn update_socket<Host: Handler>(&self, reg: Token, event_loop: &mut EventLoop<Host>) -> io::Result<()> {
trace!(target: "net", "connection reregister; token={:?}", reg);
event_loop.reregister( &self.socket, reg, self.interest, PollOpt::edge() | PollOpt::oneshot()).or_else(|e| {
error!("Failed to reregister {:?}, {:?}", reg, e);
Err(e)
})
}
@ -182,8 +183,6 @@ pub struct EncryptedConnection {
ingress_mac: Keccak,
/// Read state
read_state: EncryptedConnectionState,
/// Disconnect timeout
idle_timeout: Option<Timeout>,
/// Protocol id for the last received packet
protocol_id: u16,
/// Payload expected to be received for the last header.
@ -192,7 +191,7 @@ pub struct EncryptedConnection {
impl EncryptedConnection {
/// Create an encrypted connection out of the handshake. Consumes a handshake object.
pub fn new(handshake: Handshake) -> Result<EncryptedConnection, UtilError> {
pub fn new(mut handshake: Handshake) -> Result<EncryptedConnection, UtilError> {
let shared = try!(crypto::ecdh::agree(handshake.ecdhe.secret(), &handshake.remote_public));
let mut nonce_material = H512::new();
if handshake.originated {
@ -227,6 +226,7 @@ impl EncryptedConnection {
ingress_mac.update(&mac_material);
ingress_mac.update(if handshake.originated { &handshake.ack_cipher } else { &handshake.auth_cipher });
handshake.connection.expect(ENCRYPTED_HEADER_LEN);
Ok(EncryptedConnection {
connection: handshake.connection,
encoder: encoder,
@ -235,7 +235,6 @@ impl EncryptedConnection {
egress_mac: egress_mac,
ingress_mac: ingress_mac,
read_state: EncryptedConnectionState::Header,
idle_timeout: None,
protocol_id: 0,
payload_len: 0
})
@ -337,13 +336,14 @@ impl EncryptedConnection {
}
/// Readable IO handler. Tracker receive status and returns decoded packet if avaialable.
pub fn readable<Host:Handler>(&mut self, event_loop: &mut EventLoop<Host>) -> Result<Option<Packet>, UtilError> {
self.idle_timeout.map(|t| event_loop.clear_timeout(t));
pub fn readable<Message>(&mut self, io: &IoContext<Message>) -> Result<Option<Packet>, UtilError> where Message: Send + Clone{
io.clear_timer(self.connection.token).unwrap();
match self.read_state {
EncryptedConnectionState::Header => {
match try!(self.connection.readable()) {
Some(data) => {
try!(self.read_header(&data));
try!(io.register_timer(self.connection.token, RECIEVE_PAYLOAD_TIMEOUT));
},
None => {}
};
@ -363,24 +363,15 @@ impl EncryptedConnection {
}
/// Writable IO handler. Processes send queeue.
pub fn writable<Host:Handler>(&mut self, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
self.idle_timeout.map(|t| event_loop.clear_timeout(t));
pub fn writable<Message>(&mut self, io: &IoContext<Message>) -> Result<(), UtilError> where Message: Send + Clone {
io.clear_timer(self.connection.token).unwrap();
try!(self.connection.writable());
Ok(())
}
/// Register this connection with the event handler.
pub fn register<Host:Handler<Timeout=Token>>(&mut self, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
self.connection.expect(ENCRYPTED_HEADER_LEN);
self.idle_timeout.map(|t| event_loop.clear_timeout(t));
self.idle_timeout = event_loop.timeout_ms(self.connection.token, 1800).ok();
try!(self.connection.reregister(event_loop));
Ok(())
}
/// Update connection registration. This should be called at the end of the event loop.
pub fn reregister<Host:Handler>(&mut self, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
try!(self.connection.reregister(event_loop));
pub fn update_socket<Host:Handler>(&self, reg: Token, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
try!(self.connection.update_socket(reg, event_loop));
Ok(())
}
}

View File

@ -10,6 +10,7 @@ use network::host::{HostInfo};
use network::node::NodeId;
use error::*;
use network::error::NetworkError;
use io::{IoContext, StreamToken};
#[derive(PartialEq, Eq, Debug)]
enum HandshakeState {
@ -33,8 +34,6 @@ pub struct Handshake {
state: HandshakeState,
/// Outgoing or incoming connection
pub originated: bool,
/// Disconnect timeout
idle_timeout: Option<Timeout>,
/// ECDH ephemeral
pub ecdhe: KeyPair,
/// Connection nonce
@ -51,16 +50,16 @@ pub struct Handshake {
const AUTH_PACKET_SIZE: usize = 307;
const ACK_PACKET_SIZE: usize = 210;
const HANDSHAKE_TIMEOUT: u64 = 30000;
impl Handshake {
/// Create a new handshake object
pub fn new(token: Token, id: &NodeId, socket: TcpStream, nonce: &H256) -> Result<Handshake, UtilError> {
pub fn new(token: StreamToken, id: &NodeId, socket: TcpStream, nonce: &H256) -> Result<Handshake, UtilError> {
Ok(Handshake {
id: id.clone(),
connection: Connection::new(token, socket),
originated: false,
state: HandshakeState::New,
idle_timeout: None,
ecdhe: try!(KeyPair::create()),
nonce: nonce.clone(),
remote_public: Public::new(),
@ -71,8 +70,9 @@ impl Handshake {
}
/// Start a handhsake
pub fn start(&mut self, host: &HostInfo, originated: bool) -> Result<(), UtilError> {
pub fn start<Message>(&mut self, io: &IoContext<Message>, host: &HostInfo, originated: bool) -> Result<(), UtilError> where Message: Send + Clone{
self.originated = originated;
io.register_timer(self.connection.token, HANDSHAKE_TIMEOUT).ok();
if originated {
try!(self.write_auth(host));
}
@ -89,8 +89,8 @@ impl Handshake {
}
/// Readable IO handler. Drives the state change.
pub fn readable<Host:Handler>(&mut self, event_loop: &mut EventLoop<Host>, host: &HostInfo) -> Result<(), UtilError> {
self.idle_timeout.map(|t| event_loop.clear_timeout(t));
pub fn readable<Message>(&mut self, io: &IoContext<Message>, host: &HostInfo) -> Result<(), UtilError> where Message: Send + Clone {
io.clear_timer(self.connection.token).unwrap();
match self.state {
HandshakeState::ReadingAuth => {
match try!(self.connection.readable()) {
@ -110,29 +110,33 @@ impl Handshake {
None => {}
};
},
HandshakeState::StartSession => {},
_ => { panic!("Unexpected state"); }
}
if self.state != HandshakeState::StartSession {
try!(self.connection.reregister(event_loop));
try!(io.update_registration(self.connection.token));
}
Ok(())
}
/// Writabe IO handler.
pub fn writable<Host:Handler>(&mut self, event_loop: &mut EventLoop<Host>, _host: &HostInfo) -> Result<(), UtilError> {
self.idle_timeout.map(|t| event_loop.clear_timeout(t));
pub fn writable<Message>(&mut self, io: &IoContext<Message>, _host: &HostInfo) -> Result<(), UtilError> where Message: Send + Clone {
io.clear_timer(self.connection.token).unwrap();
try!(self.connection.writable());
if self.state != HandshakeState::StartSession {
try!(self.connection.reregister(event_loop));
io.update_registration(self.connection.token).unwrap();
}
Ok(())
}
/// Register the IO handler with the event loop
pub fn register<Host:Handler<Timeout=Token>>(&mut self, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
self.idle_timeout.map(|t| event_loop.clear_timeout(t));
self.idle_timeout = event_loop.timeout_ms(self.connection.token, 1800).ok();
try!(self.connection.register(event_loop));
/// Register the socket with the event loop
pub fn register_socket<Host:Handler<Timeout=Token>>(&self, reg: Token, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
try!(self.connection.register_socket(reg, event_loop));
Ok(())
}
pub fn update_socket<Host:Handler<Timeout=Token>>(&self, reg: Token, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
try!(self.connection.update_socket(reg, event_loop));
Ok(())
}

View File

@ -1,8 +1,9 @@
use std::mem;
use std::net::{SocketAddr};
use std::collections::{HashMap};
use std::hash::{Hasher};
use std::str::{FromStr};
use std::sync::*;
use std::ops::*;
use mio::*;
use mio::tcp::*;
use mio::udp::*;
@ -64,14 +65,20 @@ pub type PacketId = u8;
pub type ProtocolId = &'static str;
/// Messages used to communitate with the event loop from other threads.
pub enum NetworkIoMessage<Message> where Message: Send {
#[derive(Clone)]
pub enum NetworkIoMessage<Message> where Message: Send + Sync + Clone {
/// Register a new protocol handler.
AddHandler {
handler: Option<Box<NetworkProtocolHandler<Message>+Send>>,
handler: Arc<NetworkProtocolHandler<Message> + Sync>,
protocol: ProtocolId,
versions: Vec<u8>,
},
/// Send data over the network.
AddTimer {
protocol: ProtocolId,
token: TimerToken,
delay: u64,
},
/// Send data over the network. // TODO: remove this
Send {
peer: PeerId,
packet_id: PacketId,
@ -104,46 +111,45 @@ impl Encodable for CapabilityInfo {
}
/// IO access point. This is passed to all IO handlers and provides an interface to the IO subsystem.
pub struct NetworkContext<'s, 'io, Message> where Message: Send + 'static, 'io: 's {
io: &'s mut IoContext<'io, NetworkIoMessage<Message>>,
pub struct NetworkContext<'s, Message> where Message: Send + Sync + Clone + 'static, 's {
io: &'s IoContext<NetworkIoMessage<Message>>,
protocol: ProtocolId,
connections: &'s mut Slab<ConnectionEntry>,
timers: &'s mut HashMap<TimerToken, ProtocolId>,
connections: Arc<RwLock<Slab<SharedConnectionEntry>>>,
session: Option<StreamToken>,
}
impl<'s, 'io, Message> NetworkContext<'s, 'io, Message> where Message: Send + 'static, {
impl<'s, Message> NetworkContext<'s, Message> where Message: Send + Sync + Clone + 'static, {
/// Create a new network IO access point. Takes references to all the data that can be updated within the IO handler.
fn new(io: &'s mut IoContext<'io, NetworkIoMessage<Message>>,
fn new(io: &'s IoContext<NetworkIoMessage<Message>>,
protocol: ProtocolId,
session: Option<StreamToken>, connections: &'s mut Slab<ConnectionEntry>,
timers: &'s mut HashMap<TimerToken, ProtocolId>) -> NetworkContext<'s, 'io, Message> {
session: Option<StreamToken>, connections: Arc<RwLock<Slab<SharedConnectionEntry>>>) -> NetworkContext<'s, Message> {
NetworkContext {
io: io,
protocol: protocol,
session: session,
connections: connections,
timers: timers,
}
}
/// Send a packet over the network to another peer.
pub fn send(&mut self, peer: PeerId, packet_id: PacketId, data: Vec<u8>) -> Result<(), UtilError> {
match self.connections.get_mut(peer) {
Some(&mut ConnectionEntry::Session(ref mut s)) => {
pub fn send(&self, peer: PeerId, packet_id: PacketId, data: Vec<u8>) -> Result<(), UtilError> {
if let Some(connection) = self.connections.read().unwrap().get(peer).map(|c| c.clone()) {
match connection.lock().unwrap().deref_mut() {
&mut ConnectionEntry::Session(ref mut s) => {
s.send_packet(self.protocol, packet_id as u8, &data).unwrap_or_else(|e| {
warn!(target: "net", "Send error: {:?}", e);
}); //TODO: don't copy vector data
},
_ => {
warn!(target: "net", "Send: Peer does not exist");
_ => warn!(target: "net", "Send: Peer is not connected yet")
}
} else {
warn!(target: "net", "Send: Peer does not exist")
}
Ok(())
}
/// Respond to a current network message. Panics if no there is no packet in the context.
pub fn respond(&mut self, packet_id: PacketId, data: Vec<u8>) -> Result<(), UtilError> {
pub fn respond(&self, packet_id: PacketId, data: Vec<u8>) -> Result<(), UtilError> {
match self.session {
Some(session) => self.send(session, packet_id, data),
None => {
@ -153,33 +159,33 @@ impl<'s, 'io, Message> NetworkContext<'s, 'io, Message> where Message: Send + 's
}
/// Disable current protocol capability for given peer. If no capabilities left peer gets disconnected.
pub fn disable_peer(&mut self, _peer: PeerId) {
pub fn disable_peer(&self, _peer: PeerId) {
//TODO: remove capability, disconnect if no capabilities left
}
/// Register a new IO timer. Returns a new timer token. 'NetworkProtocolHandler::timeout' will be called with the token.
pub fn register_timer(&mut self, ms: u64) -> Result<TimerToken, UtilError>{
match self.io.register_timer(ms) {
Ok(token) => {
self.timers.insert(token, self.protocol);
Ok(token)
},
e => e,
}
/// Register a new IO timer. 'IoHandler::timeout' will be called with the token.
pub fn register_timer(&self, token: TimerToken, ms: u64) -> Result<(), UtilError> {
self.io.message(NetworkIoMessage::AddTimer {
token: token,
delay: ms,
protocol: self.protocol,
});
Ok(())
}
/// Returns peer identification string
pub fn peer_info(&self, peer: PeerId) -> String {
match self.connections.get(peer) {
Some(&ConnectionEntry::Session(ref s)) => {
s.info.client_version.clone()
if let Some(connection) = self.connections.read().unwrap().get(peer).map(|c| c.clone()) {
match connection.lock().unwrap().deref() {
&ConnectionEntry::Session(ref s) => {
return s.info.client_version.clone()
},
_ => {
_ => {}
}
}
"unknown".to_string()
}
}
}
}
/// Shared host information
pub struct HostInfo {
@ -222,26 +228,35 @@ enum ConnectionEntry {
Session(Session)
}
/// Root IO handler. Manages protocol handlers, IO timers and network connections.
pub struct Host<Message> where Message: Send {
pub info: HostInfo,
udp_socket: UdpSocket,
listener: TcpListener,
connections: Slab<ConnectionEntry>,
timers: HashMap<TimerToken, ProtocolId>,
nodes: HashMap<NodeId, Node>,
handlers: HashMap<ProtocolId, Box<NetworkProtocolHandler<Message>>>,
type SharedConnectionEntry = Arc<Mutex<ConnectionEntry>>;
#[derive(Copy, Clone)]
struct ProtocolTimer {
pub protocol: ProtocolId,
pub token: TimerToken, // Handler level token
}
impl<Message> Host<Message> where Message: Send {
/// Root IO handler. Manages protocol handlers, IO timers and network connections.
pub struct Host<Message> where Message: Send + Sync + Clone {
pub info: RwLock<HostInfo>,
udp_socket: Mutex<UdpSocket>,
tcp_listener: Mutex<TcpListener>,
connections: Arc<RwLock<Slab<SharedConnectionEntry>>>,
nodes: RwLock<HashMap<NodeId, Node>>,
handlers: RwLock<HashMap<ProtocolId, Arc<NetworkProtocolHandler<Message>>>>,
timers: RwLock<HashMap<TimerToken, ProtocolTimer>>,
timer_counter: RwLock<usize>,
}
impl<Message> Host<Message> where Message: Send + Sync + Clone {
pub fn new() -> Host<Message> {
let config = NetworkConfiguration::new();
let addr = config.listen_address;
// Setup the server socket
let listener = TcpListener::bind(&addr).unwrap();
let tcp_listener = TcpListener::bind(&addr).unwrap();
let udp_socket = UdpSocket::bound(&addr).unwrap();
Host::<Message> {
info: HostInfo {
let mut host = Host::<Message> {
info: RwLock::new(HostInfo {
keys: KeyPair::create().unwrap(),
config: config,
nonce: H256::random(),
@ -249,39 +264,64 @@ impl<Message> Host<Message> where Message: Send {
client_version: "parity".to_string(),
listen_port: 0,
capabilities: Vec::new(),
},
udp_socket: udp_socket,
listener: listener,
connections: Slab::new_starting_at(FIRST_CONNECTION, MAX_CONNECTIONS),
timers: HashMap::new(),
nodes: HashMap::new(),
handlers: HashMap::new(),
}
}),
udp_socket: Mutex::new(udp_socket),
tcp_listener: Mutex::new(tcp_listener),
connections: Arc::new(RwLock::new(Slab::new_starting_at(FIRST_CONNECTION, MAX_CONNECTIONS))),
nodes: RwLock::new(HashMap::new()),
handlers: RwLock::new(HashMap::new()),
timers: RwLock::new(HashMap::new()),
timer_counter: RwLock::new(LAST_CONNECTION + 1),
};
let port = host.info.read().unwrap().config.listen_address.port();
host.info.write().unwrap().deref_mut().listen_port = port;
/*
match ::ifaces::Interface::get_all().unwrap().into_iter().filter(|x| x.kind == ::ifaces::Kind::Packet && x.addr.is_some()).next() {
Some(iface) => config.public_address = iface.addr.unwrap(),
None => warn!("No public network interface"),
*/
// self.add_node("enode://a9a921de2ff09a9a4d38b623c67b2d6b477a8e654ae95d874750cbbcb31b33296496a7b4421934e2629269e180823e52c15c2b19fc59592ec51ffe4f2de76ed7@127.0.0.1:30303");
// GO bootnodes
host.add_node("enode://a979fb575495b8d6db44f750317d0f4622bf4c2aa3365d6af7c284339968eef29b69ad0dce72a4d8db5ebb4968de0e3bec910127f134779fbcb0cb6d3331163c@52.16.188.185:30303"); // IE
host.add_node("enode://de471bccee3d042261d52e9bff31458daecc406142b401d4cd848f677479f73104b9fdeb090af9583d3391b7f10cb2ba9e26865dd5fca4fcdc0fb1e3b723c786@54.94.239.50:30303"); // BR
host.add_node("enode://1118980bf48b0a3640bdba04e0fe78b1add18e1cd99bf22d53daac1fd9972ad650df52176e7c7d89d1114cfef2bc23a2959aa54998a46afcf7d91809f0855082@52.74.57.123:30303"); // SG
// ETH/DEV cpp-ethereum (poc-9.ethdev.com)
host.add_node("enode://979b7fa28feeb35a4741660a16076f1943202cb72b6af70d327f053e248bab9ba81760f39d0701ef1d8f89cc1fbd2cacba0710a12cd5314d5e0c9021aa3637f9@5.1.83.226:30303");
host
}
fn add_node(&mut self, id: &str) {
pub fn add_node(&mut self, id: &str) {
match Node::from_str(id) {
Err(e) => { warn!("Could not add node: {:?}", e); },
Ok(n) => {
self.nodes.insert(n.id.clone(), n);
self.nodes.write().unwrap().insert(n.id.clone(), n);
}
}
}
fn maintain_network(&mut self, io: &mut IoContext<NetworkIoMessage<Message>>) {
pub fn client_version(&self) -> String {
self.info.read().unwrap().client_version.clone()
}
pub fn client_id(&self) -> NodeId {
self.info.read().unwrap().id().clone()
}
fn maintain_network(&self, io: &IoContext<NetworkIoMessage<Message>>) {
self.connect_peers(io);
io.event_loop.timeout_ms(Token(IDLE), MAINTENANCE_TIMEOUT).unwrap();
}
fn have_session(&self, id: &NodeId) -> bool {
self.connections.iter().any(|e| match e { &ConnectionEntry::Session(ref s) => s.info.id.eq(&id), _ => false })
self.connections.read().unwrap().iter().any(|e| match e.lock().unwrap().deref() { &ConnectionEntry::Session(ref s) => s.info.id.eq(&id), _ => false })
}
fn connecting_to(&self, id: &NodeId) -> bool {
self.connections.iter().any(|e| match e { &ConnectionEntry::Handshake(ref h) => h.id.eq(&id), _ => false })
self.connections.read().unwrap().iter().any(|e| match e.lock().unwrap().deref() { &ConnectionEntry::Handshake(ref h) => h.id.eq(&id), _ => false })
}
fn connect_peers(&mut self, io: &mut IoContext<NetworkIoMessage<Message>>) {
fn connect_peers(&self, io: &IoContext<NetworkIoMessage<Message>>) {
struct NodeInfo {
id: NodeId,
peer_type: PeerType
@ -292,13 +332,14 @@ impl<Message> Host<Message> where Message: Send {
let mut req_conn = 0;
//TODO: use nodes from discovery here
//for n in self.node_buckets.iter().flat_map(|n| &n.nodes).map(|id| NodeInfo { id: id.clone(), peer_type: self.nodes.get(id).unwrap().peer_type}) {
for n in self.nodes.values().map(|n| NodeInfo { id: n.id.clone(), peer_type: n.peer_type }) {
let pin = self.info.read().unwrap().deref().config.pin;
for n in self.nodes.read().unwrap().values().map(|n| NodeInfo { id: n.id.clone(), peer_type: n.peer_type }) {
let connected = self.have_session(&n.id) || self.connecting_to(&n.id);
let required = n.peer_type == PeerType::Required;
if connected && required {
req_conn += 1;
}
else if !connected && (!self.info.config.pin || required) {
else if !connected && (!pin || required) {
to_connect.push(n);
}
}
@ -312,8 +353,7 @@ impl<Message> Host<Message> where Message: Send {
}
}
if !self.info.config.pin
{
if !pin {
let pending_count = 0; //TODO:
let peer_count = 0;
let mut open_slots = IDEAL_PEERS - peer_count - pending_count + req_conn;
@ -328,23 +368,24 @@ impl<Message> Host<Message> where Message: Send {
}
}
fn connect_peer(&mut self, id: &NodeId, io: &mut IoContext<NetworkIoMessage<Message>>) {
if self.have_session(id)
{
fn connect_peer(&self, id: &NodeId, io: &IoContext<NetworkIoMessage<Message>>) {
if self.have_session(id) {
warn!("Aborted connect. Node already connected.");
return;
}
if self.connecting_to(id)
{
if self.connecting_to(id) {
warn!("Aborted connect. Node already connecting.");
return;
}
let socket = {
let node = self.nodes.get_mut(id).unwrap();
let address = {
let mut nodes = self.nodes.write().unwrap();
let node = nodes.get_mut(id).unwrap();
node.last_attempted = Some(::time::now());
match TcpStream::connect(&node.endpoint.address) {
node.endpoint.address
};
match TcpStream::connect(&address) {
Ok(socket) => socket,
Err(_) => {
warn!("Cannot connect to node");
@ -353,224 +394,186 @@ impl<Message> Host<Message> where Message: Send {
}
};
let nonce = self.info.next_nonce();
match self.connections.insert_with(|token| ConnectionEntry::Handshake(Handshake::new(Token(token), id, socket, &nonce).expect("Can't create handshake"))) {
Some(token) => {
match self.connections.get_mut(token) {
Some(&mut ConnectionEntry::Handshake(ref mut h)) => {
h.start(&self.info, true)
.and_then(|_| h.register(io.event_loop))
.unwrap_or_else (|e| {
let nonce = self.info.write().unwrap().next_nonce();
if self.connections.write().unwrap().insert_with(|token| {
let mut handshake = Handshake::new(token, id, socket, &nonce).expect("Can't create handshake");
handshake.start(io, &self.info.read().unwrap(), true).and_then(|_| io.register_stream(token)).unwrap_or_else (|e| {
debug!(target: "net", "Handshake create error: {:?}", e);
});
},
_ => {}
}
},
None => { warn!("Max connections reached") }
Arc::new(Mutex::new(ConnectionEntry::Handshake(handshake)))
}).is_none() {
warn!("Max connections reached");
}
}
fn accept(&mut self, _io: &mut IoContext<NetworkIoMessage<Message>>) {
fn accept(&self, _io: &IoContext<NetworkIoMessage<Message>>) {
trace!(target: "net", "accept");
}
fn connection_writable<'s>(&'s mut self, token: StreamToken, io: &mut IoContext<'s, NetworkIoMessage<Message>>) {
let mut kill = false;
fn connection_writable(&self, token: StreamToken, io: &IoContext<NetworkIoMessage<Message>>) {
let mut create_session = false;
match self.connections.get_mut(token) {
Some(&mut ConnectionEntry::Handshake(ref mut h)) => {
h.writable(io.event_loop, &self.info).unwrap_or_else(|e| {
let mut kill = false;
if let Some(connection) = self.connections.read().unwrap().get(token).map(|c| c.clone()) {
match connection.lock().unwrap().deref_mut() {
&mut ConnectionEntry::Handshake(ref mut h) => {
match h.writable(io, &self.info.read().unwrap()) {
Err(e) => {
debug!(target: "net", "Handshake write error: {:?}", e);
kill = true;
});
create_session = h.done();
},
Some(&mut ConnectionEntry::Session(ref mut s)) => {
s.writable(io.event_loop, &self.info).unwrap_or_else(|e| {
Ok(_) => ()
}
if h.done() {
create_session = true;
}
},
&mut ConnectionEntry::Session(ref mut s) => {
match s.writable(io, &self.info.read().unwrap()) {
Err(e) => {
debug!(target: "net", "Session write error: {:?}", e);
kill = true;
});
},
Ok(_) => ()
}
_ => {
warn!(target: "net", "Received event for unknown connection");
io.update_registration(token).unwrap_or_else(|e| debug!(target: "net", "Session registration error: {:?}", e));
}
}
} else { warn!(target: "net", "Received event for unknown connection") }
if kill {
self.kill_connection(token, io);
self.kill_connection(token, io); //TODO: mark connection as dead an check in kill_connection
return;
} else if create_session {
self.start_session(token, io);
}
match self.connections.get_mut(token) {
Some(&mut ConnectionEntry::Session(ref mut s)) => {
s.reregister(io.event_loop).unwrap_or_else(|e| debug!(target: "net", "Session registration error: {:?}", e));
},
_ => (),
io.update_registration(token).unwrap_or_else(|e| debug!(target: "net", "Session registration error: {:?}", e));
}
}
fn connection_closed<'s>(&'s mut self, token: TimerToken, io: &mut IoContext<'s, NetworkIoMessage<Message>>) {
fn connection_closed(&self, token: TimerToken, io: &IoContext<NetworkIoMessage<Message>>) {
self.kill_connection(token, io);
}
fn connection_readable<'s>(&'s mut self, token: StreamToken, io: &mut IoContext<'s, NetworkIoMessage<Message>>) {
let mut kill = false;
let mut create_session = false;
fn connection_readable(&self, token: StreamToken, io: &IoContext<NetworkIoMessage<Message>>) {
let mut ready_data: Vec<ProtocolId> = Vec::new();
let mut packet_data: Option<(ProtocolId, PacketId, Vec<u8>)> = None;
match self.connections.get_mut(token) {
Some(&mut ConnectionEntry::Handshake(ref mut h)) => {
h.readable(io.event_loop, &self.info).unwrap_or_else(|e| {
let mut create_session = false;
let mut kill = false;
if let Some(connection) = self.connections.read().unwrap().get(token).map(|c| c.clone()) {
match connection.lock().unwrap().deref_mut() {
&mut ConnectionEntry::Handshake(ref mut h) => {
match h.readable(io, &self.info.read().unwrap()) {
Err(e) => {
debug!(target: "net", "Handshake read error: {:?}", e);
kill = true;
});
create_session = h.done();
},
Some(&mut ConnectionEntry::Session(ref mut s)) => {
let sd = { s.readable(io.event_loop, &self.info).unwrap_or_else(|e| {
debug!(target: "net", "Session read error: {:?}", e);
Ok(_) => ()
}
if h.done() {
create_session = true;
}
},
&mut ConnectionEntry::Session(ref mut s) => {
match s.readable(io, &self.info.read().unwrap()) {
Err(e) => {
debug!(target: "net", "Handshake read error: {:?}", e);
kill = true;
SessionData::None
}) };
match sd {
SessionData::Ready => {
for (p, _) in self.handlers.iter_mut() {
},
Ok(SessionData::Ready) => {
for (p, _) in self.handlers.read().unwrap().iter() {
if s.have_capability(p) {
ready_data.push(p);
}
}
},
SessionData::Packet {
Ok(SessionData::Packet {
data,
protocol,
packet_id,
} => {
match self.handlers.get_mut(protocol) {
}) => {
match self.handlers.read().unwrap().get(protocol) {
None => { warn!(target: "net", "No handler found for protocol: {:?}", protocol) },
Some(_) => packet_data = Some((protocol, packet_id, data)),
}
},
SessionData::None => {},
Ok(SessionData::None) => {},
}
}
_ => {
}
} else {
warn!(target: "net", "Received event for unknown connection");
}
}
if kill {
self.kill_connection(token, io);
self.kill_connection(token, io); //TODO: mark connection as dead an check in kill_connection
return;
}
if create_session {
} else if create_session {
self.start_session(token, io);
io.update_registration(token).unwrap_or_else(|e| debug!(target: "net", "Session registration error: {:?}", e));
}
for p in ready_data {
let mut h = self.handlers.get_mut(p).unwrap();
h.connected(&mut NetworkContext::new(io, p, Some(token), &mut self.connections, &mut self.timers), &token);
let h = self.handlers.read().unwrap().get(p).unwrap().clone();
h.connected(&mut NetworkContext::new(io, p, Some(token), self.connections.clone()), &token);
}
if let Some((p, packet_id, data)) = packet_data {
let mut h = self.handlers.get_mut(p).unwrap();
h.read(&mut NetworkContext::new(io, p, Some(token), &mut self.connections, &mut self.timers), &token, packet_id, &data[1..]);
let h = self.handlers.read().unwrap().get(p).unwrap().clone();
h.read(&mut NetworkContext::new(io, p, Some(token), self.connections.clone()), &token, packet_id, &data[1..]);
}
io.update_registration(token).unwrap_or_else(|e| debug!(target: "net", "Token registration error: {:?}", e));
}
match self.connections.get_mut(token) {
Some(&mut ConnectionEntry::Session(ref mut s)) => {
s.reregister(io.event_loop).unwrap_or_else(|e| debug!(target: "net", "Session registration error: {:?}", e));
fn start_session(&self, token: StreamToken, io: &IoContext<NetworkIoMessage<Message>>) {
self.connections.write().unwrap().replace_with(token, |c| {
match Arc::try_unwrap(c).ok().unwrap().into_inner().unwrap() {
ConnectionEntry::Handshake(h) => {
let session = Session::new(h, io, &self.info.read().unwrap()).expect("Session creation error");
io.update_registration(token).expect("Error updating session registration");
Some(Arc::new(Mutex::new(ConnectionEntry::Session(session))))
},
_ => (),
_ => { None } // handshake expired
}
}).ok();
}
fn start_session(&mut self, token: StreamToken, io: &mut IoContext<NetworkIoMessage<Message>>) {
let info = &self.info;
// TODO: use slab::replace_with (currently broken)
/*
match self.connections.remove(token) {
Some(ConnectionEntry::Handshake(h)) => {
match Session::new(h, io.event_loop, info) {
Ok(session) => {
assert!(token == self.connections.insert(ConnectionEntry::Session(session)).ok().unwrap());
},
Err(e) => {
debug!(target: "net", "Session construction error: {:?}", e);
}
}
},
_ => panic!("Error updating slab with session")
}*/
self.connections.replace_with(token, |c| {
match c {
ConnectionEntry::Handshake(h) => Session::new(h, io.event_loop, info)
.map(|s| Some(ConnectionEntry::Session(s)))
.unwrap_or_else(|e| {
debug!(target: "net", "Session construction error: {:?}", e);
None
}),
_ => { panic!("No handshake to create a session from"); }
}
}).expect("Error updating slab with session");
}
fn connection_timeout<'s>(&'s mut self, token: StreamToken, io: &mut IoContext<'s, NetworkIoMessage<Message>>) {
fn connection_timeout(&self, token: StreamToken, io: &IoContext<NetworkIoMessage<Message>>) {
self.kill_connection(token, io)
}
fn kill_connection<'s>(&'s mut self, token: StreamToken, io: &mut IoContext<'s, NetworkIoMessage<Message>>) {
fn kill_connection(&self, token: StreamToken, io: &IoContext<NetworkIoMessage<Message>>) {
let mut to_disconnect: Vec<ProtocolId> = Vec::new();
let mut remove = true;
match self.connections.get_mut(token) {
Some(&mut ConnectionEntry::Handshake(_)) => (), // just abandon handshake
Some(&mut ConnectionEntry::Session(ref mut s)) if s.is_ready() => {
for (p, _) in self.handlers.iter_mut() {
{
let mut connections = self.connections.write().unwrap();
if let Some(connection) = connections.get(token).map(|c| c.clone()) {
match connection.lock().unwrap().deref_mut() {
&mut ConnectionEntry::Handshake(_) => {
connections.remove(token);
},
&mut ConnectionEntry::Session(ref mut s) if s.is_ready() => {
for (p, _) in self.handlers.read().unwrap().iter() {
if s.have_capability(p) {
to_disconnect.push(p);
}
}
connections.remove(token);
},
_ => {
remove = false;
},
_ => {},
}
}
}
for p in to_disconnect {
let mut h = self.handlers.get_mut(p).unwrap();
h.disconnected(&mut NetworkContext::new(io, p, Some(token), &mut self.connections, &mut self.timers), &token);
}
if remove {
self.connections.remove(token);
let h = self.handlers.read().unwrap().get(p).unwrap().clone();
h.disconnected(&mut NetworkContext::new(io, p, Some(token), self.connections.clone()), &token);
}
}
}
impl<Message> IoHandler<NetworkIoMessage<Message>> for Host<Message> where Message: Send + 'static {
impl<Message> IoHandler<NetworkIoMessage<Message>> for Host<Message> where Message: Send + Sync + Clone + 'static {
/// Initialize networking
fn initialize(&mut self, io: &mut IoContext<NetworkIoMessage<Message>>) {
/*
match ::ifaces::Interface::get_all().unwrap().into_iter().filter(|x| x.kind == ::ifaces::Kind::Packet && x.addr.is_some()).next() {
Some(iface) => config.public_address = iface.addr.unwrap(),
None => warn!("No public network interface"),
*/
// Start listening for incoming connections
io.event_loop.register(&self.listener, Token(TCP_ACCEPT), EventSet::readable(), PollOpt::edge()).unwrap();
io.event_loop.timeout_ms(Token(IDLE), MAINTENANCE_TIMEOUT).unwrap();
// open the udp socket
io.event_loop.register(&self.udp_socket, Token(NODETABLE_RECEIVE), EventSet::readable(), PollOpt::edge()).unwrap();
io.event_loop.timeout_ms(Token(NODETABLE_MAINTAIN), 7200).unwrap();
let port = self.info.config.listen_address.port();
self.info.listen_port = port;
self.add_node("enode://a9a921de2ff09a9a4d38b623c67b2d6b477a8e654ae95d874750cbbcb31b33296496a7b4421934e2629269e180823e52c15c2b19fc59592ec51ffe4f2de76ed7@127.0.0.1:30303");
/* // GO bootnodes
self.add_node("enode://a979fb575495b8d6db44f750317d0f4622bf4c2aa3365d6af7c284339968eef29b69ad0dce72a4d8db5ebb4968de0e3bec910127f134779fbcb0cb6d3331163c@52.16.188.185:30303"); // IE
self.add_node("enode://de471bccee3d042261d52e9bff31458daecc406142b401d4cd848f677479f73104b9fdeb090af9583d3391b7f10cb2ba9e26865dd5fca4fcdc0fb1e3b723c786@54.94.239.50:30303"); // BR
self.add_node("enode://1118980bf48b0a3640bdba04e0fe78b1add18e1cd99bf22d53daac1fd9972ad650df52176e7c7d89d1114cfef2bc23a2959aa54998a46afcf7d91809f0855082@52.74.57.123:30303"); // SG
// ETH/DEV cpp-ethereum (poc-9.ethdev.com)
self.add_node("enode://979b7fa28feeb35a4741660a16076f1943202cb72b6af70d327f053e248bab9ba81760f39d0701ef1d8f89cc1fbd2cacba0710a12cd5314d5e0c9021aa3637f9@5.1.83.226:30303");*/
fn initialize(&self, io: &IoContext<NetworkIoMessage<Message>>) {
io.register_stream(TCP_ACCEPT).expect("Error registering TCP listener");
io.register_stream(NODETABLE_RECEIVE).expect("Error registering UDP listener");
io.register_timer(IDLE, MAINTENANCE_TIMEOUT).expect("Error registering Network idle timer");
//io.register_timer(NODETABLE_MAINTAIN, 7200);
}
fn stream_hup<'s>(&'s mut self, io: &mut IoContext<'s, NetworkIoMessage<Message>>, stream: StreamToken) {
fn stream_hup(&self, io: &IoContext<NetworkIoMessage<Message>>, stream: StreamToken) {
trace!(target: "net", "Hup: {}", stream);
match stream {
FIRST_CONNECTION ... LAST_CONNECTION => self.connection_closed(stream, io),
@ -578,7 +581,7 @@ impl<Message> IoHandler<NetworkIoMessage<Message>> for Host<Message> where Messa
};
}
fn stream_readable<'s>(&'s mut self, io: &mut IoContext<'s, NetworkIoMessage<Message>>, stream: StreamToken) {
fn stream_readable(&self, io: &IoContext<NetworkIoMessage<Message>>, stream: StreamToken) {
match stream {
FIRST_CONNECTION ... LAST_CONNECTION => self.connection_readable(stream, io),
NODETABLE_RECEIVE => {},
@ -587,65 +590,114 @@ impl<Message> IoHandler<NetworkIoMessage<Message>> for Host<Message> where Messa
}
}
fn stream_writable<'s>(&'s mut self, io: &mut IoContext<'s, NetworkIoMessage<Message>>, stream: StreamToken) {
fn stream_writable(&self, io: &IoContext<NetworkIoMessage<Message>>, stream: StreamToken) {
match stream {
FIRST_CONNECTION ... LAST_CONNECTION => self.connection_writable(stream, io),
NODETABLE_RECEIVE => {},
_ => panic!("Received unknown writable token"),
}
}
fn timeout<'s>(&'s mut self, io: &mut IoContext<'s, NetworkIoMessage<Message>>, token: TimerToken) {
fn timeout(&self, io: &IoContext<NetworkIoMessage<Message>>, token: TimerToken) {
match token {
IDLE => self.maintain_network(io),
FIRST_CONNECTION ... LAST_CONNECTION => self.connection_timeout(token, io),
NODETABLE_DISCOVERY => {},
NODETABLE_MAINTAIN => {},
_ => match self.timers.get_mut(&token).map(|p| *p) {
Some(protocol) => match self.handlers.get_mut(protocol) {
None => { warn!(target: "net", "No handler found for protocol: {:?}", protocol) },
Some(h) => { h.timeout(&mut NetworkContext::new(io, protocol, Some(token), &mut self.connections, &mut self.timers), token); }
_ => match self.timers.read().unwrap().get(&token).map(|p| *p) {
Some(timer) => match self.handlers.read().unwrap().get(timer.protocol).map(|h| h.clone()) {
None => { warn!(target: "net", "No handler found for protocol: {:?}", timer.protocol) },
Some(h) => { h.timeout(&NetworkContext::new(io, timer.protocol, None, self.connections.clone()), timer.token); }
},
None => {} // time not registerd through us
None => { warn!("Unknown timer token: {}", token); } // timer is not registerd through us
}
}
}
fn message<'s>(&'s mut self, io: &mut IoContext<'s, NetworkIoMessage<Message>>, message: &'s mut NetworkIoMessage<Message>) {
fn message(&self, io: &IoContext<NetworkIoMessage<Message>>, message: &NetworkIoMessage<Message>) {
match message {
&mut NetworkIoMessage::AddHandler {
ref mut handler,
&NetworkIoMessage::AddHandler {
ref handler,
ref protocol,
ref versions
} => {
let mut h = mem::replace(handler, None).unwrap();
h.initialize(&mut NetworkContext::new(io, protocol, None, &mut self.connections, &mut self.timers));
self.handlers.insert(protocol, h);
let h = handler.clone();
h.initialize(&NetworkContext::new(io, protocol, None, self.connections.clone()));
self.handlers.write().unwrap().insert(protocol, h);
let mut info = self.info.write().unwrap();
for v in versions {
self.info.capabilities.push(CapabilityInfo { protocol: protocol, version: *v, packet_count:0 });
info.capabilities.push(CapabilityInfo { protocol: protocol, version: *v, packet_count:0 });
}
},
&mut NetworkIoMessage::Send {
&NetworkIoMessage::AddTimer {
ref protocol,
ref delay,
ref token,
} => {
let handler_token = {
let mut timer_counter = self.timer_counter.write().unwrap();
let counter = timer_counter.deref_mut();
let handler_token = *counter;
*counter += 1;
handler_token
};
self.timers.write().unwrap().insert(handler_token, ProtocolTimer { protocol: protocol, token: *token });
io.register_timer(handler_token, *delay).expect("Error registering timer");
},
&NetworkIoMessage::Send {
ref peer,
ref packet_id,
ref protocol,
ref data,
} => {
match self.connections.get_mut(*peer as usize) {
Some(&mut ConnectionEntry::Session(ref mut s)) => {
if let Some(connection) = self.connections.read().unwrap().get(*peer).map(|c| c.clone()) {
match connection.lock().unwrap().deref_mut() {
&mut ConnectionEntry::Session(ref mut s) => {
s.send_packet(protocol, *packet_id as u8, &data).unwrap_or_else(|e| {
warn!(target: "net", "Send error: {:?}", e);
}); //TODO: don't copy vector data
},
_ => {
warn!(target: "net", "Send: Peer does not exist");
}
_ => { warn!(target: "net", "Send: Peer session not exist"); }
}
} else { warn!(target: "net", "Send: Peer does not exist"); }
},
&mut NetworkIoMessage::User(ref message) => {
for (p, h) in self.handlers.iter_mut() {
h.message(&mut NetworkContext::new(io, p, None, &mut self.connections, &mut self.timers), &message);
&NetworkIoMessage::User(ref message) => {
for (p, h) in self.handlers.read().unwrap().iter() {
h.message(&mut NetworkContext::new(io, p, None, self.connections.clone()), &message);
}
}
}
}
fn register_stream(&self, stream: StreamToken, reg: Token, event_loop: &mut EventLoop<IoManager<NetworkIoMessage<Message>>>) {
match stream {
FIRST_CONNECTION ... LAST_CONNECTION => {
if let Some(connection) = self.connections.read().unwrap().get(stream).map(|c| c.clone()) {
match connection.lock().unwrap().deref() {
&ConnectionEntry::Handshake(ref h) => h.register_socket(reg, event_loop).expect("Error registering socket"),
_ => warn!("Unexpected session stream registration")
}
} else { warn!("Unexpected stream registration")}
}
NODETABLE_RECEIVE => event_loop.register(self.udp_socket.lock().unwrap().deref(), Token(NODETABLE_RECEIVE), EventSet::all(), PollOpt::edge()).expect("Error registering stream"),
TCP_ACCEPT => event_loop.register(self.tcp_listener.lock().unwrap().deref(), Token(TCP_ACCEPT), EventSet::all(), PollOpt::edge()).expect("Error registering stream"),
_ => warn!("Unexpected stream regitration")
}
}
fn update_stream(&self, stream: StreamToken, reg: Token, event_loop: &mut EventLoop<IoManager<NetworkIoMessage<Message>>>) {
match stream {
FIRST_CONNECTION ... LAST_CONNECTION => {
if let Some(connection) = self.connections.read().unwrap().get(stream).map(|c| c.clone()) {
match connection.lock().unwrap().deref() {
&ConnectionEntry::Handshake(ref h) => h.update_socket(reg, event_loop).expect("Error updating socket"),
&ConnectionEntry::Session(ref s) => s.update_socket(reg, event_loop).expect("Error updating socket"),
}
} else { warn!("Unexpected stream update")}
}
NODETABLE_RECEIVE => event_loop.reregister(self.udp_socket.lock().unwrap().deref(), Token(NODETABLE_RECEIVE), EventSet::all(), PollOpt::edge()).expect("Error reregistering stream"),
TCP_ACCEPT => event_loop.reregister(self.tcp_listener.lock().unwrap().deref(), Token(TCP_ACCEPT), EventSet::all(), PollOpt::edge()).expect("Error reregistering stream"),
_ => warn!("Unexpected stream update")
}
}
}

View File

@ -56,31 +56,31 @@ mod service;
mod error;
mod node;
pub type PeerId = host::PeerId;
pub type PacketId = host::PacketId;
pub type NetworkContext<'s,'io, Message> = host::NetworkContext<'s, 'io, Message>;
pub type NetworkService<Message> = service::NetworkService<Message>;
pub type NetworkIoMessage<Message> = host::NetworkIoMessage<Message>;
pub use network::host::PeerId;
pub use network::host::PacketId;
pub use network::host::NetworkContext;
pub use network::service::NetworkService;
pub use network::host::NetworkIoMessage;
pub use network::host::NetworkIoMessage::User as UserMessage;
pub type NetworkError = error::NetworkError;
pub use network::error::NetworkError;
use io::*;
use io::TimerToken;
/// Network IO protocol handler. This needs to be implemented for each new subprotocol.
/// All the handler function are called from within IO event loop.
/// `Message` is the type for message data.
pub trait NetworkProtocolHandler<Message>: Send where Message: Send {
pub trait NetworkProtocolHandler<Message>: Sync + Send where Message: Send + Sync + Clone {
/// Initialize the handler
fn initialize(&mut self, _io: &mut NetworkContext<Message>) {}
fn initialize(&self, _io: &NetworkContext<Message>) {}
/// Called when new network packet received.
fn read(&mut self, io: &mut NetworkContext<Message>, peer: &PeerId, packet_id: u8, data: &[u8]);
fn read(&self, io: &NetworkContext<Message>, peer: &PeerId, packet_id: u8, data: &[u8]);
/// Called when new peer is connected. Only called when peer supports the same protocol.
fn connected(&mut self, io: &mut NetworkContext<Message>, peer: &PeerId);
fn connected(&self, io: &NetworkContext<Message>, peer: &PeerId);
/// Called when a previously connected peer disconnects.
fn disconnected(&mut self, io: &mut NetworkContext<Message>, peer: &PeerId);
fn disconnected(&self, io: &NetworkContext<Message>, peer: &PeerId);
/// Timer function called after a timeout created with `NetworkContext::timeout`.
fn timeout(&mut self, _io: &mut NetworkContext<Message>, _timer: TimerToken) {}
fn timeout(&self, _io: &NetworkContext<Message>, _timer: TimerToken) {}
/// Called when a broadcasted message is received. The message can only be sent from a different IO handler.
fn message(&mut self, _io: &mut NetworkContext<Message>, _message: &Message) {}
fn message(&self, _io: &NetworkContext<Message>, _message: &Message) {}
}

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@ -1,3 +1,4 @@
use std::sync::*;
use error::*;
use network::{NetworkProtocolHandler};
use network::error::{NetworkError};
@ -6,18 +7,18 @@ use io::*;
/// IO Service with networking
/// `Message` defines a notification data type.
pub struct NetworkService<Message> where Message: Send + 'static {
pub struct NetworkService<Message> where Message: Send + Sync + Clone + 'static {
io_service: IoService<NetworkIoMessage<Message>>,
host_info: String,
}
impl<Message> NetworkService<Message> where Message: Send + 'static {
impl<Message> NetworkService<Message> where Message: Send + Sync + Clone + 'static {
/// Starts IO event loop
pub fn start() -> Result<NetworkService<Message>, UtilError> {
let mut io_service = try!(IoService::<NetworkIoMessage<Message>>::start());
let host = Box::new(Host::new());
let host_info = host.info.client_version.clone();
info!("NetworkService::start(): id={:?}", host.info.id());
let host = Arc::new(Host::new());
let host_info = host.client_version();
info!("NetworkService::start(): id={:?}", host.client_id());
try!(io_service.register_handler(host));
Ok(NetworkService {
io_service: io_service,
@ -37,9 +38,9 @@ impl<Message> NetworkService<Message> where Message: Send + 'static {
}
/// Regiter a new protocol handler with the event loop.
pub fn register_protocol(&mut self, handler: Box<NetworkProtocolHandler<Message>+Send>, protocol: ProtocolId, versions: &[u8]) -> Result<(), NetworkError> {
pub fn register_protocol(&mut self, handler: Arc<NetworkProtocolHandler<Message>+Send + Sync>, protocol: ProtocolId, versions: &[u8]) -> Result<(), NetworkError> {
try!(self.io_service.send_message(NetworkIoMessage::AddHandler {
handler: Some(handler),
handler: handler,
protocol: protocol,
versions: versions.to_vec(),
}));
@ -55,7 +56,5 @@ impl<Message> NetworkService<Message> where Message: Send + 'static {
pub fn io(&mut self) -> &mut IoService<NetworkIoMessage<Message>> {
&mut self.io_service
}
}

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@ -4,6 +4,7 @@ use rlp::*;
use network::connection::{EncryptedConnection, Packet};
use network::handshake::Handshake;
use error::*;
use io::{IoContext};
use network::error::{NetworkError, DisconnectReason};
use network::host::*;
use network::node::NodeId;
@ -84,7 +85,7 @@ const PACKET_LAST: u8 = 0x7f;
impl Session {
/// Create a new session out of comepleted handshake. Consumes handshake object.
pub fn new<Host:Handler<Timeout=Token>>(h: Handshake, event_loop: &mut EventLoop<Host>, host: &HostInfo) -> Result<Session, UtilError> {
pub fn new<Message>(h: Handshake, _io: &IoContext<Message>, host: &HostInfo) -> Result<Session, UtilError> where Message: Send + Sync + Clone {
let id = h.id.clone();
let connection = try!(EncryptedConnection::new(h));
let mut session = Session {
@ -99,7 +100,6 @@ impl Session {
};
try!(session.write_hello(host));
try!(session.write_ping());
try!(session.connection.register(event_loop));
Ok(session)
}
@ -109,16 +109,16 @@ impl Session {
}
/// Readable IO handler. Returns packet data if available.
pub fn readable<Host:Handler>(&mut self, event_loop: &mut EventLoop<Host>, host: &HostInfo) -> Result<SessionData, UtilError> {
match try!(self.connection.readable(event_loop)) {
pub fn readable<Message>(&mut self, io: &IoContext<Message>, host: &HostInfo) -> Result<SessionData, UtilError> where Message: Send + Sync + Clone {
match try!(self.connection.readable(io)) {
Some(data) => Ok(try!(self.read_packet(data, host))),
None => Ok(SessionData::None)
}
}
/// Writable IO handler. Sends pending packets.
pub fn writable<Host:Handler>(&mut self, event_loop: &mut EventLoop<Host>, _host: &HostInfo) -> Result<(), UtilError> {
self.connection.writable(event_loop)
pub fn writable<Message>(&mut self, io: &IoContext<Message>, _host: &HostInfo) -> Result<(), UtilError> where Message: Send + Sync + Clone {
self.connection.writable(io)
}
/// Checks if peer supports given capability
@ -127,8 +127,8 @@ impl Session {
}
/// Update registration with the event loop. Should be called at the end of the IO handler.
pub fn reregister<Host:Handler>(&mut self, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
self.connection.reregister(event_loop)
pub fn update_socket<Host:Handler>(&self, reg:Token, event_loop: &mut EventLoop<Host>) -> Result<(), UtilError> {
self.connection.update_socket(reg, event_loop)
}
/// Send a protocol packet to peer.