405 lines
13 KiB
Rust
405 lines
13 KiB
Rust
use std::any::Any;
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use std::collections::HashMap;
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use std::net::SocketAddr;
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use std::pin::Pin;
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use std::sync::{Arc, RwLock};
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use std::future::Future;
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use log::{debug, info};
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use arc_swap::{ArcSwap, ArcSwapOption};
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use bytes::Bytes;
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use sodiumoxide::crypto::auth;
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use sodiumoxide::crypto::sign::ed25519;
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use tokio::net::{TcpListener, TcpStream};
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use crate::conn::*;
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use crate::error::*;
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use crate::message::*;
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use crate::proto::*;
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use crate::util::*;
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type DynMsg = Box<dyn Any + Send + Sync + 'static>;
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pub(crate) struct Handler {
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pub(crate) local_handler:
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Box<dyn Fn(DynMsg) -> Pin<Box<dyn Future<Output = DynMsg> + Sync + Send>> + Sync + Send>,
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pub(crate) net_handler: Box<
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dyn Fn(ed25519::PublicKey, Bytes) -> Pin<Box<dyn Future<Output = Vec<u8>> + Sync + Send>>
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+ Sync
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+ Send,
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>,
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}
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/// NetApp is the main class that handles incoming and outgoing connections.
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///
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/// The `request()` method can be used to send a message to any peer to which we have
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/// an outgoing connection, or to ourself. On the server side, these messages are
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/// processed by the handlers that have been defined using `add_msg_handler()`.
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///
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/// NetApp can be used in a stand-alone fashion or together with a peering strategy.
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/// If using it alone, you will want to set `on_connect` and `on_disconnect` events
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/// in order to manage information about the current peer list.
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///
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/// It is generally not necessary to use NetApp stand-alone, as the provided full mesh
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/// and RPS peering strategies take care of the most common use cases.
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pub struct NetApp {
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pub listen_addr: SocketAddr,
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pub netid: auth::Key,
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pub pubkey: ed25519::PublicKey,
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pub privkey: ed25519::SecretKey,
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server_conns: RwLock<HashMap<ed25519::PublicKey, Arc<ServerConn>>>,
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client_conns: RwLock<HashMap<ed25519::PublicKey, Arc<ClientConn>>>,
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pub(crate) msg_handlers: ArcSwap<HashMap<MessageKind, Arc<Handler>>>,
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on_connected_handler:
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ArcSwapOption<Box<dyn Fn(ed25519::PublicKey, SocketAddr, bool) + Send + Sync>>,
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on_disconnected_handler: ArcSwapOption<Box<dyn Fn(ed25519::PublicKey, bool) + Send + Sync>>,
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}
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async fn net_handler_aux<M, F, R>(
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handler: Arc<F>,
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remote: ed25519::PublicKey,
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bytes: Bytes,
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) -> Vec<u8>
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where
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M: Message + 'static,
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F: Fn(ed25519::PublicKey, M) -> R + Send + Sync + 'static,
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R: Future<Output = <M as Message>::Response> + Send + Sync,
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{
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debug!(
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"Handling message of kind {:08x} from {}",
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M::KIND,
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hex::encode(remote)
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);
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let res = match rmp_serde::decode::from_read_ref::<_, M>(&bytes[..]) {
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Ok(msg) => Ok(handler(remote, msg).await),
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Err(e) => Err(e.to_string()),
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};
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rmp_to_vec_all_named(&res).unwrap_or(vec![])
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}
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async fn local_handler_aux<M, F, R>(
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handler: Arc<F>,
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remote: ed25519::PublicKey,
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msg: DynMsg,
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) -> DynMsg
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where
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M: Message + 'static,
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F: Fn(ed25519::PublicKey, M) -> R + Send + Sync + 'static,
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R: Future<Output = <M as Message>::Response> + Send + Sync,
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{
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debug!("Handling message of kind {:08x} from ourself", M::KIND);
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let msg = (msg as Box<dyn Any + 'static>).downcast::<M>().unwrap();
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let res = handler(remote, *msg).await;
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Box::new(res)
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}
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impl NetApp {
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/// Creates a new instance of NetApp. No background process is
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pub fn new(
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listen_addr: SocketAddr,
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netid: auth::Key,
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privkey: ed25519::SecretKey,
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) -> Arc<Self> {
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let pubkey = privkey.public_key();
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let netapp = Arc::new(Self {
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listen_addr,
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netid,
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pubkey,
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privkey,
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server_conns: RwLock::new(HashMap::new()),
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client_conns: RwLock::new(HashMap::new()),
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msg_handlers: ArcSwap::new(Arc::new(HashMap::new())),
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on_connected_handler: ArcSwapOption::new(None),
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on_disconnected_handler: ArcSwapOption::new(None),
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});
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let netapp2 = netapp.clone();
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netapp.add_msg_handler::<HelloMessage, _, _>(
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move |from: ed25519::PublicKey, msg: HelloMessage| {
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netapp2.handle_hello_message(from, msg);
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async { () }
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},
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);
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netapp
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}
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/// Set the handler to be called when a new connection (incoming or outgoing) has
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/// been successfully established. Do not set this if using a peering strategy,
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/// as the peering strategy will need to set this itself.
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pub fn on_connected<F>(&self, handler: F)
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where F: Fn(ed25519::PublicKey, SocketAddr, bool) + Sized + Send + Sync + 'static
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{
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self.on_connected_handler.store(Some(Arc::new(Box::new(handler))));
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}
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/// Set the handler to be called when an existing connection (incoming or outgoing) has
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/// been closed by either party. Do not set this if using a peering strategy,
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/// as the peering strategy will need to set this itself.
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pub fn on_disconnected<F>(&self, handler: F)
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where F: Fn(ed25519::PublicKey, bool) + Sized + Send + Sync + 'static
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{
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self.on_disconnected_handler.store(Some(Arc::new(Box::new(handler))));
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}
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/// Add a handler for a certain message type. Note that only one handler
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/// can be specified for each message type.
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pub fn add_msg_handler<M, F, R>(&self, handler: F)
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where
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M: Message + 'static,
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F: Fn(ed25519::PublicKey, M) -> R + Send + Sync + 'static,
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R: Future<Output = <M as Message>::Response> + Send + Sync + 'static,
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{
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let handler = Arc::new(handler);
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let handler2 = handler.clone();
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let net_handler = Box::new(move |remote: ed25519::PublicKey, bytes: Bytes| {
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let fun: Pin<Box<dyn Future<Output = Vec<u8>> + Sync + Send>> =
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Box::pin(net_handler_aux(handler2.clone(), remote, bytes));
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fun
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});
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let self_id = self.pubkey.clone();
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let local_handler = Box::new(move |msg: DynMsg| {
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let fun: Pin<Box<dyn Future<Output = DynMsg> + Sync + Send>> =
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Box::pin(local_handler_aux(handler.clone(), self_id, msg));
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fun
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});
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let funs = Arc::new(Handler {
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net_handler,
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local_handler,
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});
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let mut handlers = self.msg_handlers.load().as_ref().clone();
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handlers.insert(M::KIND, funs);
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self.msg_handlers.store(Arc::new(handlers));
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}
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/// Main listening process for our app. This future runs during the whole
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/// run time of our application.
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pub async fn listen(self: Arc<Self>) {
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let mut listener = TcpListener::bind(self.listen_addr).await.unwrap();
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info!("Listening on {}", self.listen_addr);
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loop {
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// The second item contains the IP and port of the new connection.
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let (socket, _) = listener.accept().await.unwrap();
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info!(
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"Incoming connection from {}, negotiating handshake...",
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socket.peer_addr().unwrap()
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);
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let self2 = self.clone();
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tokio::spawn(async move {
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ServerConn::run(self2, socket)
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.await
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.log_err("ServerConn::run");
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});
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}
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}
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/// Attempt to connect to a peer, given by its ip:port and its public key.
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/// The public key will be checked during the secret handshake process.
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/// This function returns once the connection has been established and a
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/// successfull handshake was made. At this point we can send messages to
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/// the other node with `Netapp::request`
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pub async fn try_connect(
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self: Arc<Self>,
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ip: SocketAddr,
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pk: ed25519::PublicKey,
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) -> Result<(), Error> {
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// Don't connect to ourself, we don't care
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// but pretend we did
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if pk == self.pubkey {
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tokio::spawn(async move {
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if let Some(h) = self.on_connected_handler.load().as_ref() {
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h(pk, ip, false);
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}
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});
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return Ok(());
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}
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// Don't connect if already connected
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if self.client_conns.read().unwrap().contains_key(&pk) {
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return Ok(());
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}
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let socket = TcpStream::connect(ip).await?;
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info!("Connected to {}, negotiating handshake...", ip);
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ClientConn::init(self, socket, pk.clone()).await?;
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Ok(())
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}
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/// Close the outgoing connection we have to a node specified by its public key,
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/// if such a connection is currently open.
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pub fn disconnect(self: &Arc<Self>, pk: &ed25519::PublicKey) {
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// Don't disconnect from ourself (we aren't connected anyways)
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// but pretend we did
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if *pk == self.pubkey {
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let pk = *pk;
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let self2 = self.clone();
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tokio::spawn(async move {
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if let Some(h) = self2.on_disconnected_handler.load().as_ref() {
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h(pk, false);
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}
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});
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return;
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}
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let conn = self.client_conns.read().unwrap().get(pk).cloned();
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if let Some(c) = conn {
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debug!("Closing connection to {} ({})",
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hex::encode(c.peer_pk),
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c.remote_addr);
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c.close();
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}
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}
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/// Close the incoming connection from a certain client to us,
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/// if such a connection is currently open.
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pub fn server_disconnect(self: &Arc<Self>, pk: &ed25519::PublicKey) {
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let conn = self.server_conns.read().unwrap().get(pk).cloned();
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if let Some(c) = conn {
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debug!("Closing incoming connection from {} ({})",
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hex::encode(c.peer_pk),
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c.remote_addr);
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c.close();
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}
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}
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// Called from conn.rs when an incoming connection is successfully established
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// Registers the connection in our list of connections
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// Do not yet call the on_connected handler, because we don't know if the remote
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// has an actual IP address and port we can call them back on.
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// We will know this when they send a Hello message, which is handled below.
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pub(crate) fn connected_as_server(&self, id: ed25519::PublicKey, conn: Arc<ServerConn>) {
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info!("Accepted connection from {}", hex::encode(id));
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let mut conn_list = self.server_conns.write().unwrap();
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conn_list.insert(id.clone(), conn);
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}
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// Handle hello message from a client. This message is used for them to tell us
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// that they are listening on a certain port number on which we can call them back.
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// At this point we know they are a full network member, and not just a client,
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// and we call the on_connected handler so that the peering strategy knows
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// we have a new potential peer
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fn handle_hello_message(&self, id: ed25519::PublicKey, msg: HelloMessage) {
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if let Some(h) = self.on_connected_handler.load().as_ref() {
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if let Some(c) = self.server_conns.read().unwrap().get(&id) {
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let remote_addr = SocketAddr::new(c.remote_addr.ip(), msg.server_port);
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h(id, remote_addr, true);
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}
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}
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}
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// Called from conn.rs when an incoming connection is closed.
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// We deregister the connection from server_conns and call the
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// handler registered by on_disconnected
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pub(crate) fn disconnected_as_server(&self, id: &ed25519::PublicKey, conn: Arc<ServerConn>) {
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info!("Connection from {} closed", hex::encode(id));
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let mut conn_list = self.server_conns.write().unwrap();
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if let Some(c) = conn_list.get(id) {
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if Arc::ptr_eq(c, &conn) {
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conn_list.remove(id);
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}
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if let Some(h) = self.on_disconnected_handler.load().as_ref() {
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h(conn.peer_pk, true);
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}
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}
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}
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// Called from conn.rs when an outgoinc connection is successfully established.
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// The connection is registered in self.client_conns, and the
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// on_connected handler is called.
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//
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// Since we are ourself listening, we send them a Hello message so that
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// they know on which port to call us back. (TODO: don't do this if we are
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// just a simple client and not a full p2p node)
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pub(crate) fn connected_as_client(&self, id: ed25519::PublicKey, conn: Arc<ClientConn>) {
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info!("Connection established to {}", hex::encode(id));
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{
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let mut conn_list = self.client_conns.write().unwrap();
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if let Some(old_c) = conn_list.insert(id.clone(), conn.clone()) {
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tokio::spawn(async move { old_c.close() });
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}
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}
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if let Some(h) = self.on_connected_handler.load().as_ref() {
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h(conn.peer_pk, conn.remote_addr, false);
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}
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let server_port = self.listen_addr.port();
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tokio::spawn(async move {
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conn.request(HelloMessage { server_port }, PRIO_NORMAL)
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.await
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.log_err("Sending hello message");
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});
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}
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// Called from conn.rs when an outgoinc connection is closed.
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// The connection is removed from conn_list, and the on_disconnected handler
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// is called.
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pub(crate) fn disconnected_as_client(&self, id: &ed25519::PublicKey, conn: Arc<ClientConn>) {
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info!("Connection to {} closed", hex::encode(id));
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let mut conn_list = self.client_conns.write().unwrap();
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if let Some(c) = conn_list.get(id) {
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if Arc::ptr_eq(c, &conn) {
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conn_list.remove(id);
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if let Some(h) = self.on_disconnected_handler.load().as_ref() {
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h(conn.peer_pk, false);
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}
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}
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}
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}
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/// Send a message to a remote host to which a client connection is already
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/// established, and await their response. The target is the id of the peer we
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/// want to send the message to.
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/// The priority is an `u8`, with lower numbers meaning highest priority.
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pub async fn request<T>(
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&self,
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target: &ed25519::PublicKey,
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rq: T,
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prio: RequestPriority,
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) -> Result<<T as Message>::Response, Error>
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where
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T: Message + 'static,
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{
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if *target == self.pubkey {
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let handler = self.msg_handlers.load().get(&T::KIND).cloned();
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match handler {
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None => Err(Error::Message(format!(
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"No handler registered for message kind {:08x}",
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T::KIND
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))),
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Some(h) => {
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let local_handler = &h.local_handler;
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let res = local_handler(Box::new(rq)).await;
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let res_t = (res as Box<dyn Any + 'static>)
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.downcast::<<T as Message>::Response>()
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.unwrap();
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Ok(*res_t)
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}
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}
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} else {
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let conn = self.client_conns.read().unwrap().get(target).cloned();
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match conn {
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None => Err(Error::Message(format!(
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"Not connected: {}",
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hex::encode(target)
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))),
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Some(c) => c.request(rq, prio).await,
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}
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}
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}
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}
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