use bitcoin::secp256k1::PublicKey;
use tokio::net::TcpStream;
-use tokio::{io, time};
+use tokio::time;
use tokio::sync::mpsc;
-use tokio::io::{AsyncReadExt, AsyncWrite, AsyncWriteExt};
use lightning::ln::peer_handler;
use lightning::ln::peer_handler::SocketDescriptor as LnSocketTrait;
use lightning::ln::peer_handler::APeerManager;
-use lightning::ln::msgs::NetAddress;
+use lightning::ln::msgs::SocketAddress;
use std::ops::Deref;
-use std::task;
+use std::task::{self, Poll};
+use std::future::Future;
use std::net::SocketAddr;
use std::net::TcpStream as StdTcpStream;
use std::sync::{Arc, Mutex};
use std::sync::atomic::{AtomicU64, Ordering};
use std::time::Duration;
+use std::pin::Pin;
use std::hash::Hash;
static ID_COUNTER: AtomicU64 = AtomicU64::new(0);
+// We only need to select over multiple futures in one place, and taking on the full `tokio/macros`
+// dependency tree in order to do so (which has broken our MSRV before) is excessive. Instead, we
+// define a trivial two- and three- select macro with the specific types we need and just use that.
+
+pub(crate) enum SelectorOutput {
+ A(Option<()>), B(Option<()>), C(tokio::io::Result<()>),
+}
+
+pub(crate) struct TwoSelector<
+ A: Future<Output=Option<()>> + Unpin, B: Future<Output=Option<()>> + Unpin
+> {
+ pub a: A,
+ pub b: B,
+}
+
+impl<
+ A: Future<Output=Option<()>> + Unpin, B: Future<Output=Option<()>> + Unpin
+> Future for TwoSelector<A, B> {
+ type Output = SelectorOutput;
+ fn poll(mut self: Pin<&mut Self>, ctx: &mut task::Context<'_>) -> Poll<SelectorOutput> {
+ match Pin::new(&mut self.a).poll(ctx) {
+ Poll::Ready(res) => { return Poll::Ready(SelectorOutput::A(res)); },
+ Poll::Pending => {},
+ }
+ match Pin::new(&mut self.b).poll(ctx) {
+ Poll::Ready(res) => { return Poll::Ready(SelectorOutput::B(res)); },
+ Poll::Pending => {},
+ }
+ Poll::Pending
+ }
+}
+
+pub(crate) struct ThreeSelector<
+ A: Future<Output=Option<()>> + Unpin, B: Future<Output=Option<()>> + Unpin, C: Future<Output=tokio::io::Result<()>> + Unpin
+> {
+ pub a: A,
+ pub b: B,
+ pub c: C,
+}
+
+impl<
+ A: Future<Output=Option<()>> + Unpin, B: Future<Output=Option<()>> + Unpin, C: Future<Output=tokio::io::Result<()>> + Unpin
+> Future for ThreeSelector<A, B, C> {
+ type Output = SelectorOutput;
+ fn poll(mut self: Pin<&mut Self>, ctx: &mut task::Context<'_>) -> Poll<SelectorOutput> {
+ match Pin::new(&mut self.a).poll(ctx) {
+ Poll::Ready(res) => { return Poll::Ready(SelectorOutput::A(res)); },
+ Poll::Pending => {},
+ }
+ match Pin::new(&mut self.b).poll(ctx) {
+ Poll::Ready(res) => { return Poll::Ready(SelectorOutput::B(res)); },
+ Poll::Pending => {},
+ }
+ match Pin::new(&mut self.c).poll(ctx) {
+ Poll::Ready(res) => { return Poll::Ready(SelectorOutput::C(res)); },
+ Poll::Pending => {},
+ }
+ Poll::Pending
+ }
+}
+
/// Connection contains all our internal state for a connection - we hold a reference to the
/// Connection object (in an Arc<Mutex<>>) in each SocketDescriptor we create as well as in the
/// read future (which is returned by schedule_read).
struct Connection {
- writer: Option<io::WriteHalf<TcpStream>>,
+ writer: Option<Arc<TcpStream>>,
// Because our PeerManager is templated by user-provided types, and we can't (as far as I can
// tell) have a const RawWakerVTable built out of templated functions, we need some indirection
// between being woken up with write-ready and calling PeerManager::write_buffer_space_avail.
async fn schedule_read<PM: Deref + 'static + Send + Sync + Clone>(
peer_manager: PM,
us: Arc<Mutex<Self>>,
- mut reader: io::ReadHalf<TcpStream>,
+ reader: Arc<TcpStream>,
mut read_wake_receiver: mpsc::Receiver<()>,
mut write_avail_receiver: mpsc::Receiver<()>,
) where PM::Target: APeerManager<Descriptor = SocketDescriptor> {
}
us_lock.read_paused
};
- tokio::select! {
- v = write_avail_receiver.recv() => {
+ // TODO: Drop the Box'ing of the futures once Rust has pin-on-stack support.
+ let select_result = if read_paused {
+ TwoSelector {
+ a: Box::pin(write_avail_receiver.recv()),
+ b: Box::pin(read_wake_receiver.recv()),
+ }.await
+ } else {
+ ThreeSelector {
+ a: Box::pin(write_avail_receiver.recv()),
+ b: Box::pin(read_wake_receiver.recv()),
+ c: Box::pin(reader.readable()),
+ }.await
+ };
+ match select_result {
+ SelectorOutput::A(v) => {
assert!(v.is_some()); // We can't have dropped the sending end, its in the us Arc!
if peer_manager.as_ref().write_buffer_space_avail(&mut our_descriptor).is_err() {
break Disconnect::CloseConnection;
}
},
- _ = read_wake_receiver.recv() => {},
- read = reader.read(&mut buf), if !read_paused => match read {
- Ok(0) => break Disconnect::PeerDisconnected,
- Ok(len) => {
- let read_res = peer_manager.as_ref().read_event(&mut our_descriptor, &buf[0..len]);
- let mut us_lock = us.lock().unwrap();
- match read_res {
- Ok(pause_read) => {
- if pause_read {
- us_lock.read_paused = true;
- }
- },
- Err(_) => break Disconnect::CloseConnection,
- }
- },
- Err(_) => break Disconnect::PeerDisconnected,
+ SelectorOutput::B(_) => {},
+ SelectorOutput::C(res) => {
+ if res.is_err() { break Disconnect::PeerDisconnected; }
+ match reader.try_read(&mut buf) {
+ Ok(0) => break Disconnect::PeerDisconnected,
+ Ok(len) => {
+ let read_res = peer_manager.as_ref().read_event(&mut our_descriptor, &buf[0..len]);
+ let mut us_lock = us.lock().unwrap();
+ match read_res {
+ Ok(pause_read) => {
+ if pause_read {
+ us_lock.read_paused = true;
+ }
+ },
+ Err(_) => break Disconnect::CloseConnection,
+ }
+ },
+ Err(e) if e.kind() == std::io::ErrorKind::WouldBlock => {
+ // readable() is allowed to spuriously wake, so we have to handle
+ // WouldBlock here.
+ },
+ Err(_) => break Disconnect::PeerDisconnected,
+ }
},
}
let _ = event_waker.try_send(());
// here.
let _ = tokio::task::yield_now().await;
};
- let writer_option = us.lock().unwrap().writer.take();
- if let Some(mut writer) = writer_option {
- // If the socket is already closed, shutdown() will fail, so just ignore it.
- let _ = writer.shutdown().await;
- }
+ us.lock().unwrap().writer.take();
if let Disconnect::PeerDisconnected = disconnect_type {
peer_manager.as_ref().socket_disconnected(&our_descriptor);
peer_manager.as_ref().process_events();
}
}
- fn new(stream: StdTcpStream) -> (io::ReadHalf<TcpStream>, mpsc::Receiver<()>, mpsc::Receiver<()>, Arc<Mutex<Self>>) {
+ fn new(stream: StdTcpStream) -> (Arc<TcpStream>, mpsc::Receiver<()>, mpsc::Receiver<()>, Arc<Mutex<Self>>) {
// We only ever need a channel of depth 1 here: if we returned a non-full write to the
// PeerManager, we will eventually get notified that there is room in the socket to write
// new bytes, which will generate an event. That event will be popped off the queue before
// false.
let (read_waker, read_receiver) = mpsc::channel(1);
stream.set_nonblocking(true).unwrap();
- let (reader, writer) = io::split(TcpStream::from_std(stream).unwrap());
+ let tokio_stream = Arc::new(TcpStream::from_std(stream).unwrap());
- (reader, write_receiver, read_receiver,
+ (Arc::clone(&tokio_stream), write_receiver, read_receiver,
Arc::new(Mutex::new(Self {
- writer: Some(writer), write_avail, read_waker, read_paused: false,
+ writer: Some(tokio_stream), write_avail, read_waker, read_paused: false,
rl_requested_disconnect: false,
id: ID_COUNTER.fetch_add(1, Ordering::AcqRel)
})))
}
}
-fn get_addr_from_stream(stream: &StdTcpStream) -> Option<NetAddress> {
+fn get_addr_from_stream(stream: &StdTcpStream) -> Option<SocketAddress> {
match stream.peer_addr() {
- Ok(SocketAddr::V4(sockaddr)) => Some(NetAddress::IPv4 {
+ Ok(SocketAddr::V4(sockaddr)) => Some(SocketAddress::TcpIpV4 {
addr: sockaddr.ip().octets(),
port: sockaddr.port(),
}),
- Ok(SocketAddr::V6(sockaddr)) => Some(NetAddress::IPv6 {
+ Ok(SocketAddr::V6(sockaddr)) => Some(SocketAddress::TcpIpV6 {
addr: sockaddr.ip().octets(),
port: sockaddr.port(),
}),
}
impl peer_handler::SocketDescriptor for SocketDescriptor {
fn send_data(&mut self, data: &[u8], resume_read: bool) -> usize {
- // To send data, we take a lock on our Connection to access the WriteHalf of the TcpStream,
- // writing to it if there's room in the kernel buffer, or otherwise create a new Waker with
- // a SocketDescriptor in it which can wake up the write_avail Sender, waking up the
+ // To send data, we take a lock on our Connection to access the TcpStream, writing to it if
+ // there's room in the kernel buffer, or otherwise create a new Waker with a
+ // SocketDescriptor in it which can wake up the write_avail Sender, waking up the
// processing future which will call write_buffer_space_avail and we'll end up back here.
let mut us = self.conn.lock().unwrap();
if us.writer.is_none() {
let mut ctx = task::Context::from_waker(&waker);
let mut written_len = 0;
loop {
- match std::pin::Pin::new(us.writer.as_mut().unwrap()).poll_write(&mut ctx, &data[written_len..]) {
- task::Poll::Ready(Ok(res)) => {
- // The tokio docs *seem* to indicate this can't happen, and I certainly don't
- // know how to handle it if it does (cause it should be a Poll::Pending
- // instead):
- assert_ne!(res, 0);
- written_len += res;
- if written_len == data.len() { return written_len; }
- },
- task::Poll::Ready(Err(e)) => {
- // The tokio docs *seem* to indicate this can't happen, and I certainly don't
- // know how to handle it if it does (cause it should be a Poll::Pending
- // instead):
- assert_ne!(e.kind(), io::ErrorKind::WouldBlock);
- // Probably we've already been closed, just return what we have and let the
- // read thread handle closing logic.
- return written_len;
+ match us.writer.as_ref().unwrap().poll_write_ready(&mut ctx) {
+ task::Poll::Ready(Ok(())) => {
+ match us.writer.as_ref().unwrap().try_write(&data[written_len..]) {
+ Ok(res) => {
+ debug_assert_ne!(res, 0);
+ written_len += res;
+ if written_len == data.len() { return written_len; }
+ },
+ Err(_) => return written_len,
+ }
},
+ task::Poll::Ready(Err(_)) => return written_len,
task::Poll::Pending => {
// We're queued up for a write event now, but we need to make sure we also
// pause read given we're now waiting on the remote end to ACK (and in
use lightning::routing::gossip::NodeId;
use lightning::events::*;
use lightning::util::test_utils::TestNodeSigner;
+ use bitcoin::Network;
+ use bitcoin::blockdata::constants::ChainHash;
use bitcoin::secp256k1::{Secp256k1, SecretKey, PublicKey};
use tokio::sync::mpsc;
fn handle_update_fee(&self, _their_node_id: &PublicKey, _msg: &UpdateFee) {}
fn handle_announcement_signatures(&self, _their_node_id: &PublicKey, _msg: &AnnouncementSignatures) {}
fn handle_channel_update(&self, _their_node_id: &PublicKey, _msg: &ChannelUpdate) {}
+ fn handle_open_channel_v2(&self, _their_node_id: &PublicKey, _msg: &OpenChannelV2) {}
+ fn handle_accept_channel_v2(&self, _their_node_id: &PublicKey, _msg: &AcceptChannelV2) {}
+ fn handle_tx_add_input(&self, _their_node_id: &PublicKey, _msg: &TxAddInput) {}
+ fn handle_tx_add_output(&self, _their_node_id: &PublicKey, _msg: &TxAddOutput) {}
+ fn handle_tx_remove_input(&self, _their_node_id: &PublicKey, _msg: &TxRemoveInput) {}
+ fn handle_tx_remove_output(&self, _their_node_id: &PublicKey, _msg: &TxRemoveOutput) {}
+ fn handle_tx_complete(&self, _their_node_id: &PublicKey, _msg: &TxComplete) {}
+ fn handle_tx_signatures(&self, _their_node_id: &PublicKey, _msg: &TxSignatures) {}
+ fn handle_tx_init_rbf(&self, _their_node_id: &PublicKey, _msg: &TxInitRbf) {}
+ fn handle_tx_ack_rbf(&self, _their_node_id: &PublicKey, _msg: &TxAckRbf) {}
+ fn handle_tx_abort(&self, _their_node_id: &PublicKey, _msg: &TxAbort) {}
fn peer_disconnected(&self, their_node_id: &PublicKey) {
if *their_node_id == self.expected_pubkey {
self.disconnected_flag.store(true, Ordering::SeqCst);
fn handle_error(&self, _their_node_id: &PublicKey, _msg: &ErrorMessage) {}
fn provided_node_features(&self) -> NodeFeatures { NodeFeatures::empty() }
fn provided_init_features(&self, _their_node_id: &PublicKey) -> InitFeatures { InitFeatures::empty() }
+ fn get_genesis_hashes(&self) -> Option<Vec<ChainHash>> {
+ Some(vec![ChainHash::using_genesis_block(Network::Testnet)])
+ }
}
impl MessageSendEventsProvider for MsgHandler {
fn get_and_clear_pending_msg_events(&self) -> Vec<MessageSendEvent> {