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hbbft/examples/network/node.rs

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//! Networking controls of the consensus node.
//!
//! ## Example
//!
//! The following code could be run on host 192.168.1.1:
//!
//! ```ignore
//! use hbbft::node::Node;
//! use std::net::SocketAddr;
//! use std::vec::Vec;
//!
//! let bind_address = "127.0.0.1:10001".parse().unwrap();
//! let remote_addresses = vec!["192.168.1.2:10002",
//! "192.168.1.3:10003",
//! "192.168.1.4:10004"]
//! .iter()
//! .map(|s| s.parse().unwrap())
//! .collect();
//!
//! let value = "Value #1".as_bytes().to_vec();
//!
//! let result = Node::new(bind_address, remote_addresses, Some(value)).run();
//! println!("Consensus result {:?}", result);
//! ```
//!
//! Similar code shall then run on hosts 192.168.1.2, 192.168.1.3 and
//! 192.168.1.4 with appropriate changes in `bind_address` and
//! `remote_addresses`. Each host has it's own optional broadcast `value`. If
//! the consensus `result` is not an error then every successfully terminated
//! consensus node will be the same `result`.
use std::collections::HashSet;
use std::fmt::Debug;
use std::marker::{Send, Sync};
use std::net::SocketAddr;
use std::sync::Arc;
use std::{iter, process, thread, time};
use crossbeam;
use log::{debug, error};
use crate::network::messaging::Messaging;
use crate::network::{commst, connection};
use hbbft::broadcast::{Broadcast, Message};
use hbbft::{ConsensusProtocol, SourcedMessage};
/// This is a structure to start a consensus node.
pub struct Node<T> {
/// Incoming connection socket.
addr: SocketAddr,
/// Sockets of remote nodes.
remotes: HashSet<SocketAddr>,
/// Optionally, a value to be broadcast by this node.
value: Option<T>,
}
impl<T: Clone + Debug + AsRef<[u8]> + PartialEq + Send + Sync + From<Vec<u8>> + Into<Vec<u8>>>
Node<T>
{
/// Consensus node constructor. It only initialises initial parameters.
pub fn new(addr: SocketAddr, remotes: HashSet<SocketAddr>, value: Option<T>) -> Self {
Node {
addr,
remotes,
value,
}
}
/// Consensus node procedure implementing HoneyBadgerBFT.
pub fn run(&self) -> Result<T, Box<(dyn std::any::Any + Send + 'static)>> {
let value = &self.value;
let (our_str, connections) = connection::make(&self.addr, &self.remotes);
let mut node_strs: Vec<String> = iter::once(our_str.clone())
.chain(connections.iter().map(|c| c.node_str.clone()))
.collect();
node_strs.sort();
let our_id = node_strs.binary_search(&our_str).unwrap();
let num_nodes = node_strs.len();
if value.is_some() != (our_id == 0) {
panic!("Exactly the first node must propose a value.");
}
// Initialise the message delivery system and obtain TX and RX handles.
let messaging: Messaging<Message> = Messaging::new(num_nodes);
let rxs_to_comms = messaging.rxs_to_comms();
let tx_from_comms = messaging.tx_from_comms();
let rx_to_algo = messaging.rx_to_algo();
let tx_from_algo = messaging.tx_from_algo();
let stop_tx = messaging.stop_tx();
let mut rng = rand::rngs::OsRng::new().unwrap();
// All spawned threads will have exited by the end of the scope.
crossbeam::scope(|scope| {
// Start the centralised message delivery system.
let _msg_handle = messaging.spawn(scope);
// Associate a broadcast instance with this node. This instance will
// broadcast the proposed value. There is no remote node
// corresponding to this instance, and no dedicated comms task. The
// node index is 0.
let broadcast_handle = scope.spawn(move |_| {
let validators = (0..num_nodes).into();
let mut broadcast = Broadcast::new(our_id, Arc::new(validators), 0)
.expect("failed to instantiate broadcast");
if let Some(v) = value {
// FIXME: Use the output.
let step = broadcast
.handle_input(v.clone().into(), &mut rng)
.expect("propose value");
for msg in step.messages {
tx_from_algo.send(msg).expect("send from algo");
}
}
loop {
// Receive a message from the socket IO task.
let message = rx_to_algo.recv().expect("receive from algo");
let SourcedMessage { source: i, message } = message;
debug!("{} received from {}: {:?}", our_id, i, message);
let step = broadcast
.handle_message(&i, message)
.expect("handle broadcast message");
for msg in step.messages {
debug!("{} sending to {:?}: {:?}", our_id, msg.target, msg.message);
tx_from_algo.send(msg).expect("send from algo");
}
if let Some(output) = step.output.into_iter().next() {
println!(
"Broadcast succeeded! Node {} output: {}",
our_id,
String::from_utf8(output).unwrap()
);
break;
}
}
});
// Start a comms task for each connection. Node indices of those
// tasks are 1 through N where N is the number of connections.
for (i, c) in connections.iter().enumerate() {
// Receive side of a single-consumer channel from algorithm
// actor tasks to the comms task.
let node_index = if c.node_str < our_str { i } else { i + 1 };
let rx_to_comms = &rxs_to_comms[node_index];
scope.spawn(move |_| {
match commst::CommsTask::<Message>::new(
tx_from_comms,
rx_to_comms,
// FIXME: handle error
c.stream.try_clone().unwrap(),
node_index,
)
.run()
{
Ok(_) => debug!("Comms task {} succeeded", node_index),
Err(e) => error!("Comms task {}: {:?}", node_index, e),
}
});
}
// Wait for the broadcast instances to finish before stopping the
// messaging task.
let _ = broadcast_handle.join();
// Wait another second so that pending messages get sent out.
thread::sleep(time::Duration::from_secs(1));
// Stop the messaging task.
stop_tx
.send(())
.map_err(|e| {
error!("{}", e);
})
.unwrap();
process::exit(0);
}) // end of thread scope
}
}
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