// Copyright 2020 The Grin Developers
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! Provides a connection wrapper that handles the lower level tasks in sending
//! or receiving data from the TCP socket, as well as dealing with timeouts.
//!
//! Because of a few idiosyncracies in the Rust `TcpStream`, this has to use
//! async I/O to be able to both read *and* write on the connection. Which
//! forces us to go through some additional gymnastic to loop over the async
//! stream and make sure we get the right number of bytes out.
use crate::core::ser;
use crate::core::ser::ProtocolVersion;
use crate::msg::{
read_body, read_discard, read_header, read_item, write_message, Msg, MsgHeader,
MsgHeaderWrapper,
};
use crate::types::Error;
use crate::util::{RateCounter, RwLock};
use std::io::{self, Read, Write};
use std::net::{Shutdown, TcpStream};
use std::sync::atomic::{AtomicBool, Ordering};
use std::sync::{mpsc, Arc};
use std::time::Duration;
use std::{
cmp,
thread::{self, JoinHandle},
};
pub const SEND_CHANNEL_CAP: usize = 100;
const HEADER_IO_TIMEOUT: Duration = Duration::from_millis(2000);
const CHANNEL_TIMEOUT: Duration = Duration::from_millis(1000);
const BODY_IO_TIMEOUT: Duration = Duration::from_millis(60000);
/// A trait to be implemented in order to receive messages from the
/// connection. Allows providing an optional response.
pub trait MessageHandler: Send + 'static {
fn consume<'a>(
&self,
msg: Message<'a>,
stopped: Arc<AtomicBool>,
tracker: Arc<Tracker>,
) -> Result<Option<Msg>, Error>;
}
// Macro to simplify the boilerplate around I/O and Grin error handling
macro_rules! try_break {
($inner:expr) => {
match $inner {
Ok(v) => Some(v),
Err(Error::Connection(ref e)) if e.kind() == io::ErrorKind::TimedOut => None,
Err(Error::Connection(ref e)) if e.kind() == io::ErrorKind::WouldBlock => {
// to avoid the heavy polling which will consume CPU 100%
thread::sleep(Duration::from_millis(10));
None
}
Err(Error::Store(_))
| Err(Error::Chain(_))
| Err(Error::Internal)
| Err(Error::NoDandelionRelay) => None,
Err(ref e) => {
debug!("try_break: exit the loop: {:?}", e);
break;
}
}
};
}
macro_rules! try_header {
($res:expr, $conn: expr) => {{
$conn
.set_read_timeout(Some(HEADER_IO_TIMEOUT))
.expect("set timeout");
try_break!($res)
}};
}
/// A message as received by the connection. Provides access to the message
/// header lazily consumes the message body, handling its deserialization.
pub struct Message<'a> {
pub header: MsgHeader,
stream: &'a mut dyn Read,
version: ProtocolVersion,
}
impl<'a> Message<'a> {
fn from_header(
header: MsgHeader,
stream: &'a mut dyn Read,
version: ProtocolVersion,
) -> Message<'a> {
Message {
header,
stream,
version,
}
}
/// Read the message body from the underlying connection
pub fn body<T: ser::Readable>(&mut self) -> Result<T, Error> {
read_body(&self.header, self.stream, self.version)
}
/// Read a single "thing" from the underlying connection.
/// Return the thing and the total bytes read.
pub fn streaming_read<T: ser::Readable>(&mut self) -> Result<(T, u64), Error> {
read_item(self.stream, self.version)
}
pub fn copy_attachment(&mut self, len: usize, writer: &mut dyn Write) -> Result<usize, Error> {
let mut written = 0;
while written < len {
let read_len = cmp::min(8000, len - written);
let mut buf = vec![0u8; read_len];
self.stream.read_exact(&mut buf[..])?;
writer.write_all(&buf)?;
written += read_len;
}
Ok(written)
}
}
pub struct StopHandle {
/// Channel to close the connection
stopped: Arc<AtomicBool>,
// we need Option to take ownhership of the handle in stop()
reader_thread: Option<JoinHandle<()>>,
writer_thread: Option<JoinHandle<()>>,
}
impl StopHandle {
/// Schedule this connection to safely close via the async close_channel.
pub fn stop(&self) {
self.stopped.store(true, Ordering::Relaxed);
}
pub fn wait(&mut self) {
if let Some(reader_thread) = self.reader_thread.take() {
self.join_thread(reader_thread);
}
if let Some(writer_thread) = self.writer_thread.take() {
self.join_thread(writer_thread);
}
}
fn join_thread(&self, peer_thread: JoinHandle<()>) {
// wait only if other thread is calling us, eg shutdown
if thread::current().id() != peer_thread.thread().id() {
debug!("waiting for thread {:?} exit", peer_thread.thread().id());
if let Err(e) = peer_thread.join() {
error!("failed to stop peer thread: {:?}", e);
}
} else {
debug!(
"attempt to stop thread {:?} from itself",
peer_thread.thread().id()
);
}
}
}
#[derive(Clone)]
pub struct ConnHandle {
/// Channel to allow sending data through the connection
pub send_channel: mpsc::SyncSender<Msg>,
}
impl ConnHandle {
/// Send msg via the synchronous, bounded channel (sync_sender).
/// Two possible failure cases -
/// * Disconnected: Propagate this up to the caller so the peer connection can be closed.
/// * Full: Our internal msg buffer is full. This is not a problem with the peer connection
/// and we do not want to close the connection. We drop the msg rather than blocking here.
/// If the buffer is full because there is an underlying issue with the peer
/// and potentially the peer connection. We assume this will be handled at the peer level.
pub fn send(&self, msg: Msg) -> Result<(), Error> {
match self.send_channel.try_send(msg) {
Ok(()) => Ok(()),
Err(mpsc::TrySendError::Disconnected(_)) => {
Err(Error::Send("try_send disconnected".to_owned()))
}
Err(mpsc::TrySendError::Full(_)) => {
debug!("conn_handle: try_send but buffer is full, dropping msg");
Ok(())
}
}
}
}
pub struct Tracker {
/// Bytes we've sent.
pub sent_bytes: Arc<RwLock<RateCounter>>,
/// Bytes we've received.
pub received_bytes: Arc<RwLock<RateCounter>>,
}
impl Tracker {
pub fn new() -> Tracker {
let received_bytes = Arc::new(RwLock::new(RateCounter::new()));
let sent_bytes = Arc::new(RwLock::new(RateCounter::new()));
Tracker {
received_bytes,
sent_bytes,
}
}
pub fn inc_received(&self, size: u64) {
self.received_bytes.write().inc(size);
}
pub fn inc_sent(&self, size: u64) {
self.sent_bytes.write().inc(size);
}
pub fn inc_quiet_received(&self, size: u64) {
self.received_bytes.write().inc_quiet(size);
}
pub fn inc_quiet_sent(&self, size: u64) {
self.sent_bytes.write().inc_quiet(size);
}
}
/// Start listening on the provided connection and wraps it. Does not hang
/// the current thread, instead just returns a future and the Connection
/// itself.
pub fn listen<H>(
stream: TcpStream,
version: ProtocolVersion,
tracker: Arc<Tracker>,
handler: H,
) -> io::Result<(ConnHandle, StopHandle)>
where
H: MessageHandler,
{
let (send_tx, send_rx) = mpsc::sync_channel(SEND_CHANNEL_CAP);
let stopped = Arc::new(AtomicBool::new(false));
let conn_handle = ConnHandle {
send_channel: send_tx,
};
let (reader_thread, writer_thread) = poll(
stream,
conn_handle.clone(),
version,
handler,
send_rx,
stopped.clone(),
tracker,
)?;
Ok((
conn_handle,
StopHandle {
stopped,
reader_thread: Some(reader_thread),
writer_thread: Some(writer_thread),
},
))
}
fn poll<H>(
conn: TcpStream,
conn_handle: ConnHandle,
version: ProtocolVersion,
handler: H,
send_rx: mpsc::Receiver<Msg>,
stopped: Arc<AtomicBool>,
tracker: Arc<Tracker>,
) -> io::Result<(JoinHandle<()>, JoinHandle<()>)>
where
H: MessageHandler,
{
// Split out tcp stream out into separate reader/writer halves.
let mut reader = conn.try_clone().expect("clone conn for reader failed");
let mut writer = conn.try_clone().expect("clone conn for writer failed");
let reader_stopped = stopped.clone();
let reader_tracker = tracker.clone();
let writer_tracker = tracker;
let reader_thread = thread::Builder::new()
.name("peer_read".to_string())
.spawn(move || {
loop {
// check the read end
match try_header!(read_header(&mut reader, version), &reader) {
Some(MsgHeaderWrapper::Known(header)) => {
reader
.set_read_timeout(Some(BODY_IO_TIMEOUT))
.expect("set timeout");
let msg = Message::from_header(header, &mut reader, version);
trace!(
"Received message header, type {:?}, len {}.",
msg.header.msg_type,
msg.header.msg_len
);
// Increase received bytes counter
reader_tracker.inc_received(MsgHeader::LEN as u64 + msg.header.msg_len);
let resp_msg = try_break!(handler.consume(
msg,
reader_stopped.clone(),
reader_tracker.clone()
));
if let Some(Some(resp_msg)) = resp_msg {
try_break!(conn_handle.send(resp_msg));
}
}
Some(MsgHeaderWrapper::Unknown(msg_len, type_byte)) => {
debug!(
"Received unknown message header, type {:?}, len {}.",
type_byte, msg_len
);
// Increase received bytes counter
reader_tracker.inc_received(MsgHeader::LEN as u64 + msg_len);
try_break!(read_discard(msg_len, &mut reader));
}
None => {}
}
// check the close channel
if reader_stopped.load(Ordering::Relaxed) {
break;
}
}
debug!(
"Shutting down reader connection with {}",
reader
.peer_addr()
.map(|a| a.to_string())
.unwrap_or_else(|_| "?".to_owned())
);
let _ = reader.shutdown(Shutdown::Both);
})?;
let writer_thread = thread::Builder::new()
.name("peer_write".to_string())
.spawn(move || {
let mut retry_send = Err(());
writer
.set_write_timeout(Some(BODY_IO_TIMEOUT))
.expect("set timeout");
loop {
let maybe_data = retry_send.or_else(|_| send_rx.recv_timeout(CHANNEL_TIMEOUT));
retry_send = Err(());
if let Ok(data) = maybe_data {
let written =
try_break!(write_message(&mut writer, &data, writer_tracker.clone()));
if written.is_none() {
retry_send = Ok(data);
}
}
// check the close channel
if stopped.load(Ordering::Relaxed) {
break;
}
}
debug!(
"Shutting down writer connection with {}",
writer
.peer_addr()
.map(|a| a.to_string())
.unwrap_or_else(|_| "?".to_owned())
);
})?;
Ok((reader_thread, writer_thread))
}