// Copyright 2015-2018 Parity Technologies (UK) Ltd. // This file is part of Parity. // Parity is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // Parity is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // You should have received a copy of the GNU General Public License // along with Parity. If not, see . use std::io; use std::time::{Duration, Instant}; use std::sync::Arc; use std::collections::{BTreeMap, BTreeSet}; use std::collections::btree_map::Entry; use std::net::{SocketAddr, IpAddr}; use futures::{finished, failed, Future, Stream}; use futures_cpupool::CpuPool; use parking_lot::{RwLock, Mutex}; use tokio_io::IoFuture; use tokio_core::reactor::{Handle, Remote, Interval}; use tokio_core::net::{TcpListener, TcpStream}; use ethkey::{Public, KeyPair, Signature, Random, Generator}; use ethereum_types::{Address, H256}; use key_server_cluster::{Error, NodeId, SessionId, Requester, AclStorage, KeyStorage, KeyServerSet, NodeKeyPair}; use key_server_cluster::cluster_sessions::{ClusterSession, AdminSession, ClusterSessions, SessionIdWithSubSession, ClusterSessionsContainer, SERVERS_SET_CHANGE_SESSION_ID, create_cluster_view, AdminSessionCreationData, ClusterSessionsListener}; use key_server_cluster::cluster_sessions_creator::{ClusterSessionCreator, IntoSessionId}; use key_server_cluster::message::{self, Message, ClusterMessage}; use key_server_cluster::generation_session::{SessionImpl as GenerationSession}; use key_server_cluster::decryption_session::{SessionImpl as DecryptionSession}; use key_server_cluster::encryption_session::{SessionImpl as EncryptionSession}; use key_server_cluster::signing_session_ecdsa::{SessionImpl as EcdsaSigningSession}; use key_server_cluster::signing_session_schnorr::{SessionImpl as SchnorrSigningSession}; use key_server_cluster::key_version_negotiation_session::{SessionImpl as KeyVersionNegotiationSession, IsolatedSessionTransport as KeyVersionNegotiationSessionTransport, ContinueAction}; use key_server_cluster::io::{DeadlineStatus, ReadMessage, SharedTcpStream, read_encrypted_message, WriteMessage, write_encrypted_message}; use key_server_cluster::net::{accept_connection as net_accept_connection, connect as net_connect, Connection as NetConnection}; use key_server_cluster::connection_trigger::{Maintain, ConnectionTrigger, SimpleConnectionTrigger, ServersSetChangeSessionCreatorConnector}; use key_server_cluster::connection_trigger_with_migration::ConnectionTriggerWithMigration; /// Maintain interval (seconds). Every MAINTAIN_INTERVAL seconds node: /// 1) checks if connected nodes are responding to KeepAlive messages /// 2) tries to connect to disconnected nodes /// 3) checks if enc/dec sessions are time-outed const MAINTAIN_INTERVAL: u64 = 10; /// When no messages have been received from node within KEEP_ALIVE_SEND_INTERVAL seconds, /// we must send KeepAlive message to the node to check if it still responds to messages. const KEEP_ALIVE_SEND_INTERVAL: Duration = Duration::from_secs(30); /// When no messages have been received from node within KEEP_ALIVE_DISCONNECT_INTERVAL seconds, /// we must treat this node as non-responding && disconnect from it. const KEEP_ALIVE_DISCONNECT_INTERVAL: Duration = Duration::from_secs(60); /// Empty future. pub type BoxedEmptyFuture = Box + Send>; /// Cluster interface for external clients. pub trait ClusterClient: Send + Sync { /// Get cluster state. fn cluster_state(&self) -> ClusterState; /// Start new generation session. fn new_generation_session(&self, session_id: SessionId, origin: Option
, author: Address, threshold: usize) -> Result, Error>; /// Start new encryption session. fn new_encryption_session(&self, session_id: SessionId, author: Requester, common_point: Public, encrypted_point: Public) -> Result, Error>; /// Start new decryption session. fn new_decryption_session(&self, session_id: SessionId, origin: Option
, requester: Requester, version: Option, is_shadow_decryption: bool, is_broadcast_decryption: bool) -> Result, Error>; /// Start new Schnorr signing session. fn new_schnorr_signing_session(&self, session_id: SessionId, requester: Requester, version: Option, message_hash: H256) -> Result, Error>; /// Start new ECDSA session. fn new_ecdsa_signing_session(&self, session_id: SessionId, requester: Requester, version: Option, message_hash: H256) -> Result, Error>; /// Start new key version negotiation session. fn new_key_version_negotiation_session(&self, session_id: SessionId) -> Result>, Error>; /// Start new servers set change session. fn new_servers_set_change_session(&self, session_id: Option, migration_id: Option, new_nodes_set: BTreeSet, old_set_signature: Signature, new_set_signature: Signature) -> Result, Error>; /// Listen for new generation sessions. fn add_generation_listener(&self, listener: Arc>); /// Listen for new decryption sessions. fn add_decryption_listener(&self, listener: Arc>); /// Ask node to make 'faulty' generation sessions. #[cfg(test)] fn make_faulty_generation_sessions(&self); /// Get active generation session with given id. #[cfg(test)] fn generation_session(&self, session_id: &SessionId) -> Option>; /// Try connect to disconnected nodes. #[cfg(test)] fn connect(&self); /// Get key storage. #[cfg(test)] fn key_storage(&self) -> Arc; } /// Cluster access for single session participant. pub trait Cluster: Send + Sync { /// Broadcast message to all other nodes. fn broadcast(&self, message: Message) -> Result<(), Error>; /// Send message to given node. fn send(&self, to: &NodeId, message: Message) -> Result<(), Error>; /// Is connected to given node? fn is_connected(&self, node: &NodeId) -> bool; /// Get a set of connected nodes. fn nodes(&self) -> BTreeSet; /// Get total count of configured key server nodes (valid at the time of ClusterView creation). fn configured_nodes_count(&self) -> usize; /// Get total count of connected key server nodes (valid at the time of ClusterView creation). fn connected_nodes_count(&self) -> usize; } /// Cluster initialization parameters. #[derive(Clone)] pub struct ClusterConfiguration { /// Number of threads reserved by cluster. pub threads: usize, /// Allow connecting to 'higher' nodes. pub allow_connecting_to_higher_nodes: bool, /// KeyPair this node holds. pub self_key_pair: Arc, /// Interface to listen to. pub listen_address: (String, u16), /// Cluster nodes set. pub key_server_set: Arc, /// Reference to key storage pub key_storage: Arc, /// Reference to ACL storage pub acl_storage: Arc, /// Administrator public key. pub admin_public: Option, /// Should key servers set change session should be started when servers set changes. /// This will only work when servers set is configured using KeyServerSet contract. pub auto_migrate_enabled: bool, } /// Cluster state. pub struct ClusterState { /// Nodes, to which connections are established. pub connected: BTreeSet, } /// Network cluster implementation. pub struct ClusterCore { /// Handle to the event loop. handle: Handle, /// Listen address. listen_address: SocketAddr, /// Cluster data. data: Arc, } /// Network cluster client interface implementation. pub struct ClusterClientImpl { /// Cluster data. data: Arc, } /// Network cluster view. It is a communication channel, required in single session. pub struct ClusterView { core: Arc>, configured_nodes_count: usize, connected_nodes_count: usize, } /// Cross-thread shareable cluster data. pub struct ClusterData { /// Cluster configuration. pub config: ClusterConfiguration, /// Handle to the event loop. pub handle: Remote, /// Handle to the cpu thread pool. pub pool: CpuPool, /// KeyPair this node holds. pub self_key_pair: Arc, /// Connections data. pub connections: ClusterConnections, /// Active sessions data. pub sessions: ClusterSessions, } /// Connections that are forming the cluster. Lock order: trigger.lock() -> data.lock(). pub struct ClusterConnections { /// Self node id. pub self_node_id: NodeId, /// All known other key servers. pub key_server_set: Arc, /// Connections trigger. pub trigger: Mutex>, /// Servers set change session creator connector. pub connector: Arc, /// Connections data. pub data: RwLock, } #[derive(Default)] /// Cluster connections data. pub struct ClusterConnectionsData { /// Active key servers set. pub nodes: BTreeMap, /// Active connections to key servers. pub connections: BTreeMap>, } /// Cluster view core. struct ClusterViewCore { /// Cluster reference. cluster: Arc, /// Subset of nodes, required for this session. nodes: BTreeSet, } /// Connection to single node. pub struct Connection { /// Node id. node_id: NodeId, /// Node address. node_address: SocketAddr, /// Is inbound connection? is_inbound: bool, /// Tcp stream. stream: SharedTcpStream, /// Connection key. key: KeyPair, /// Last message time. last_message_time: Mutex, } impl ClusterCore { pub fn new(handle: Handle, config: ClusterConfiguration) -> Result, Error> { let listen_address = make_socket_address(&config.listen_address.0, config.listen_address.1)?; let connections = ClusterConnections::new(&config)?; let servers_set_change_creator_connector = connections.connector.clone(); let sessions = ClusterSessions::new(&config, servers_set_change_creator_connector); let data = ClusterData::new(&handle, config, connections, sessions); Ok(Arc::new(ClusterCore { handle: handle, listen_address: listen_address, data: data, })) } /// Create new client interface. pub fn client(&self) -> Arc { Arc::new(ClusterClientImpl::new(self.data.clone())) } /// Get cluster configuration. #[cfg(test)] pub fn config(&self) -> &ClusterConfiguration { &self.data.config } /// Get connection to given node. #[cfg(test)] pub fn connection(&self, node: &NodeId) -> Option> { self.data.connection(node) } /// Run cluster. pub fn run(&self) -> Result<(), Error> { self.run_listener() .and_then(|_| self.run_connections())?; // schedule maintain procedures ClusterCore::schedule_maintain(&self.handle, self.data.clone()); Ok(()) } /// Start listening for incoming connections. pub fn run_listener(&self) -> Result<(), Error> { // start listeining for incoming connections self.handle.spawn(ClusterCore::listen(&self.handle, self.data.clone(), self.listen_address.clone())?); Ok(()) } /// Start connecting to other nodes. pub fn run_connections(&self) -> Result<(), Error> { // try to connect to every other peer ClusterCore::connect_disconnected_nodes(self.data.clone()); Ok(()) } /// Connect to peer. fn connect(data: Arc, node_address: SocketAddr) { data.handle.clone().spawn(move |handle| { data.pool.clone().spawn(ClusterCore::connect_future(handle, data, node_address)) }) } /// Connect to socket using given context and handle. fn connect_future(handle: &Handle, data: Arc, node_address: SocketAddr) -> BoxedEmptyFuture { let disconnected_nodes = data.connections.disconnected_nodes().keys().cloned().collect(); Box::new(net_connect(&node_address, handle, data.self_key_pair.clone(), disconnected_nodes) .then(move |result| ClusterCore::process_connection_result(data, Some(node_address), result)) .then(|_| finished(()))) } /// Start listening for incoming connections. fn listen(handle: &Handle, data: Arc, listen_address: SocketAddr) -> Result { Ok(Box::new(TcpListener::bind(&listen_address, &handle)? .incoming() .and_then(move |(stream, node_address)| { ClusterCore::accept_connection(data.clone(), stream, node_address); Ok(()) }) .for_each(|_| Ok(())) .then(|_| finished(())))) } /// Accept connection. fn accept_connection(data: Arc, stream: TcpStream, node_address: SocketAddr) { data.handle.clone().spawn(move |handle| { data.pool.clone().spawn(ClusterCore::accept_connection_future(handle, data, stream, node_address)) }) } /// Accept connection future. fn accept_connection_future(handle: &Handle, data: Arc, stream: TcpStream, node_address: SocketAddr) -> BoxedEmptyFuture { Box::new(net_accept_connection(node_address, stream, handle, data.self_key_pair.clone()) .then(move |result| ClusterCore::process_connection_result(data, None, result)) .then(|_| finished(()))) } /// Schedule mainatain procedures. fn schedule_maintain(handle: &Handle, data: Arc) { let d = data.clone(); let interval: BoxedEmptyFuture = Box::new(Interval::new(Duration::new(MAINTAIN_INTERVAL, 0), handle) .expect("failed to create interval") .and_then(move |_| Ok(ClusterCore::maintain(data.clone()))) .for_each(|_| Ok(())) .then(|_| finished(()))); d.spawn(interval); } /// Execute maintain procedures. fn maintain(data: Arc) { trace!(target: "secretstore_net", "{}: executing maintain procedures", data.self_key_pair.public()); ClusterCore::keep_alive(data.clone()); ClusterCore::connect_disconnected_nodes(data.clone()); data.sessions.stop_stalled_sessions(); } /// Called for every incomming mesage. fn process_connection_messages(data: Arc, connection: Arc) -> IoFuture> { Box::new(connection .read_message() .then(move |result| match result { Ok((_, Ok(message))) => { ClusterCore::process_connection_message(data.clone(), connection.clone(), message); // continue serving connection data.spawn(ClusterCore::process_connection_messages(data.clone(), connection)); Box::new(finished(Ok(()))) }, Ok((_, Err(err))) => { warn!(target: "secretstore_net", "{}: protocol error '{}' when reading message from node {}", data.self_key_pair.public(), err, connection.node_id()); // continue serving connection data.spawn(ClusterCore::process_connection_messages(data.clone(), connection)); Box::new(finished(Err(err))) }, Err(err) => { warn!(target: "secretstore_net", "{}: network error '{}' when reading message from node {}", data.self_key_pair.public(), err, connection.node_id()); // close connection data.connections.remove(data.clone(), connection.node_id(), connection.is_inbound()); Box::new(failed(err)) }, } )) } /// Send keepalive messages to every othe node. fn keep_alive(data: Arc) { data.sessions.sessions_keep_alive(); for connection in data.connections.active_connections() { let last_message_diff = Instant::now() - connection.last_message_time(); if last_message_diff > KEEP_ALIVE_DISCONNECT_INTERVAL { data.connections.remove(data.clone(), connection.node_id(), connection.is_inbound()); data.sessions.on_connection_timeout(connection.node_id()); } else if last_message_diff > KEEP_ALIVE_SEND_INTERVAL { data.spawn(connection.send_message(Message::Cluster(ClusterMessage::KeepAlive(message::KeepAlive {})))); } } } /// Try to connect to every disconnected node. fn connect_disconnected_nodes(data: Arc) { let r = data.connections.update_nodes_set(data.clone()); if let Some(r) = r { data.spawn(r); } // connect to disconnected nodes for (node_id, node_address) in data.connections.disconnected_nodes() { if data.config.allow_connecting_to_higher_nodes || data.self_key_pair.public() < &node_id { ClusterCore::connect(data.clone(), node_address); } } } /// Process connection future result. fn process_connection_result(data: Arc, outbound_addr: Option, result: Result>, io::Error>) -> IoFuture> { match result { Ok(DeadlineStatus::Meet(Ok(connection))) => { let connection = Connection::new(outbound_addr.is_none(), connection); if data.connections.insert(data.clone(), connection.clone()) { ClusterCore::process_connection_messages(data.clone(), connection) } else { Box::new(finished(Ok(()))) } }, Ok(DeadlineStatus::Meet(Err(err))) => { warn!(target: "secretstore_net", "{}: protocol error '{}' when establishing {} connection{}", data.self_key_pair.public(), err, if outbound_addr.is_some() { "outbound" } else { "inbound" }, outbound_addr.map(|a| format!(" with {}", a)).unwrap_or_default()); Box::new(finished(Ok(()))) }, Ok(DeadlineStatus::Timeout) => { warn!(target: "secretstore_net", "{}: timeout when establishing {} connection{}", data.self_key_pair.public(), if outbound_addr.is_some() { "outbound" } else { "inbound" }, outbound_addr.map(|a| format!(" with {}", a)).unwrap_or_default()); Box::new(finished(Ok(()))) }, Err(err) => { warn!(target: "secretstore_net", "{}: network error '{}' when establishing {} connection{}", data.self_key_pair.public(), err, if outbound_addr.is_some() { "outbound" } else { "inbound" }, outbound_addr.map(|a| format!(" with {}", a)).unwrap_or_default()); Box::new(finished(Ok(()))) }, } } /// Process single message from the connection. fn process_connection_message(data: Arc, connection: Arc, message: Message) { connection.set_last_message_time(Instant::now()); trace!(target: "secretstore_net", "{}: received message {} from {}", data.self_key_pair.public(), message, connection.node_id()); // error is ignored as we only process errors on session level match message { Message::Generation(message) => Self::process_message(&data, &data.sessions.generation_sessions, connection, Message::Generation(message)) .map(|_| ()).unwrap_or_default(), Message::Encryption(message) => Self::process_message(&data, &data.sessions.encryption_sessions, connection, Message::Encryption(message)) .map(|_| ()).unwrap_or_default(), Message::Decryption(message) => Self::process_message(&data, &data.sessions.decryption_sessions, connection, Message::Decryption(message)) .map(|_| ()).unwrap_or_default(), Message::SchnorrSigning(message) => Self::process_message(&data, &data.sessions.schnorr_signing_sessions, connection, Message::SchnorrSigning(message)) .map(|_| ()).unwrap_or_default(), Message::EcdsaSigning(message) => Self::process_message(&data, &data.sessions.ecdsa_signing_sessions, connection, Message::EcdsaSigning(message)) .map(|_| ()).unwrap_or_default(), Message::ServersSetChange(message) => { let message = Message::ServersSetChange(message); let is_initialization_message = message.is_initialization_message(); let session = Self::process_message(&data, &data.sessions.admin_sessions, connection, message); if is_initialization_message { if let Some(session) = session { data.connections.servers_set_change_creator_connector().set_key_servers_set_change_session(session.clone()); } } } Message::KeyVersionNegotiation(message) => { let session = Self::process_message(&data, &data.sessions.negotiation_sessions, connection, Message::KeyVersionNegotiation(message)); Self::try_continue_session(&data, session); }, Message::ShareAdd(message) => Self::process_message(&data, &data.sessions.admin_sessions, connection, Message::ShareAdd(message)) .map(|_| ()).unwrap_or_default(), Message::Cluster(message) => ClusterCore::process_cluster_message(data, connection, message), } } /// Try to contnue session. fn try_continue_session(data: &Arc, session: Option>>) { if let Some(session) = session { let meta = session.meta(); let is_master_node = meta.self_node_id == meta.master_node_id; if is_master_node && session.is_finished() { data.sessions.negotiation_sessions.remove(&session.id()); match session.wait() { Ok((version, master)) => match session.take_continue_action() { Some(ContinueAction::Decrypt(session, origin, is_shadow_decryption, is_broadcast_decryption)) => { let initialization_error = if data.self_key_pair.public() == &master { session.initialize(origin, version, is_shadow_decryption, is_broadcast_decryption) } else { session.delegate(master, origin, version, is_shadow_decryption, is_broadcast_decryption) }; if let Err(error) = initialization_error { session.on_session_error(&meta.self_node_id, error); data.sessions.decryption_sessions.remove(&session.id()); } }, Some(ContinueAction::SchnorrSign(session, message_hash)) => { let initialization_error = if data.self_key_pair.public() == &master { session.initialize(version, message_hash) } else { session.delegate(master, version, message_hash) }; if let Err(error) = initialization_error { session.on_session_error(&meta.self_node_id, error); data.sessions.schnorr_signing_sessions.remove(&session.id()); } }, Some(ContinueAction::EcdsaSign(session, message_hash)) => { let initialization_error = if data.self_key_pair.public() == &master { session.initialize(version, message_hash) } else { session.delegate(master, version, message_hash) }; if let Err(error) = initialization_error { session.on_session_error(&meta.self_node_id, error); data.sessions.ecdsa_signing_sessions.remove(&session.id()); } }, None => (), }, Err(error) => match session.take_continue_action() { Some(ContinueAction::Decrypt(session, _, _, _)) => { data.sessions.decryption_sessions.remove(&session.id()); session.on_session_error(&meta.self_node_id, error); }, Some(ContinueAction::SchnorrSign(session, _)) => { data.sessions.schnorr_signing_sessions.remove(&session.id()); session.on_session_error(&meta.self_node_id, error); }, Some(ContinueAction::EcdsaSign(session, _)) => { data.sessions.ecdsa_signing_sessions.remove(&session.id()); session.on_session_error(&meta.self_node_id, error); }, None => (), }, } } } } /// Get or insert new session. fn prepare_session, D>(data: &Arc, sessions: &ClusterSessionsContainer, sender: &NodeId, message: &Message) -> Result, Error> where Message: IntoSessionId { fn requires_all_connections(message: &Message) -> bool { match *message { Message::Generation(_) => true, Message::ShareAdd(_) => true, Message::ServersSetChange(_) => true, _ => false, } } // get or create new session, if required let session_id = message.into_session_id().expect("into_session_id fails for cluster messages only; only session messages are passed to prepare_session; qed"); let is_initialization_message = message.is_initialization_message(); let is_delegation_message = message.is_delegation_message(); match is_initialization_message || is_delegation_message { false => sessions.get(&session_id, true).ok_or(Error::NoActiveSessionWithId), true => { let creation_data = SC::creation_data_from_message(&message)?; let master = if is_initialization_message { sender.clone() } else { data.self_key_pair.public().clone() }; let cluster = create_cluster_view(data, requires_all_connections(&message))?; sessions.insert(cluster, master, session_id, Some(message.session_nonce().ok_or(Error::InvalidMessage)?), message.is_exclusive_session_message(), creation_data) }, } } /// Process single session message from connection. fn process_message, D>(data: &Arc, sessions: &ClusterSessionsContainer, connection: Arc, mut message: Message) -> Option> where Message: IntoSessionId { // get or create new session, if required let mut sender = connection.node_id().clone(); let session = Self::prepare_session(data, sessions, &sender, &message); // send error if session is not found, or failed to create let session = match session { Ok(session) => session, Err(error) => { // this is new session => it is not yet in container warn!(target: "secretstore_net", "{}: {} session read error '{}' when requested for session from node {}", data.self_key_pair.public(), S::type_name(), error, sender); if !message.is_error_message() { let session_id = message.into_session_id().expect("session_id only fails for cluster messages; only session messages are passed to process_message; qed"); let session_nonce = message.session_nonce().expect("session_nonce only fails for cluster messages; only session messages are passed to process_message; qed"); data.spawn(connection.send_message(SC::make_error_message(session_id, session_nonce, error))); } return None; }, }; let session_id = session.id(); let mut is_queued_message = false; loop { let message_result = session.on_message(&sender, &message); match message_result { Ok(_) => { // if session is completed => stop if session.is_finished() { info!(target: "secretstore_net", "{}: {} session completed", data.self_key_pair.public(), S::type_name()); sessions.remove(&session_id); return Some(session); } // try to dequeue message match sessions.dequeue_message(&session_id) { Some((msg_sender, msg)) => { is_queued_message = true; sender = msg_sender; message = msg; }, None => return Some(session), } }, Err(Error::TooEarlyForRequest) => { sessions.enqueue_message(&session_id, sender, message, is_queued_message); return Some(session); }, Err(err) => { warn!(target: "secretstore_net", "{}: {} session error '{}' when processing message {} from node {}", data.self_key_pair.public(), S::type_name(), err, message, sender); session.on_session_error(data.self_key_pair.public(), err); sessions.remove(&session_id); return Some(session); }, } } } /// Process single cluster message from the connection. fn process_cluster_message(data: Arc, connection: Arc, message: ClusterMessage) { match message { ClusterMessage::KeepAlive(_) => data.spawn(connection.send_message(Message::Cluster(ClusterMessage::KeepAliveResponse(message::KeepAliveResponse { session_id: None, })))), ClusterMessage::KeepAliveResponse(msg) => if let Some(session_id) = msg.session_id { data.sessions.on_session_keep_alive(connection.node_id(), session_id.into()); }, _ => warn!(target: "secretstore_net", "{}: received unexpected message {} from node {} at {}", data.self_key_pair.public(), message, connection.node_id(), connection.node_address()), } } } impl ClusterConnections { pub fn new(config: &ClusterConfiguration) -> Result { let mut nodes = config.key_server_set.snapshot().current_set; nodes.remove(config.self_key_pair.public()); let trigger: Box = match config.auto_migrate_enabled { false => Box::new(SimpleConnectionTrigger::new(config.key_server_set.clone(), config.self_key_pair.clone(), config.admin_public.clone())), true if config.admin_public.is_none() => Box::new(ConnectionTriggerWithMigration::new(config.key_server_set.clone(), config.self_key_pair.clone())), true => return Err(Error::Internal("secret store admininstrator public key is specified with auto-migration enabled".into())), }; let connector = trigger.servers_set_change_creator_connector(); Ok(ClusterConnections { self_node_id: config.self_key_pair.public().clone(), key_server_set: config.key_server_set.clone(), trigger: Mutex::new(trigger), connector: connector, data: RwLock::new(ClusterConnectionsData { nodes: nodes, connections: BTreeMap::new(), }), }) } pub fn cluster_state(&self) -> ClusterState { ClusterState { connected: self.data.read().connections.keys().cloned().collect(), } } pub fn get(&self, node: &NodeId) -> Option> { self.data.read().connections.get(node).cloned() } pub fn insert(&self, data: Arc, connection: Arc) -> bool { { let mut data = self.data.write(); if !data.nodes.contains_key(connection.node_id()) { // incoming connections are checked here trace!(target: "secretstore_net", "{}: ignoring unknown connection from {} at {}", self.self_node_id, connection.node_id(), connection.node_address()); debug_assert!(connection.is_inbound()); return false; } if data.connections.contains_key(connection.node_id()) { // we have already connected to the same node // the agreement is that node with lower id must establish connection to node with higher id if (&self.self_node_id < connection.node_id() && connection.is_inbound()) || (&self.self_node_id > connection.node_id() && !connection.is_inbound()) { return false; } } let node = connection.node_id().clone(); trace!(target: "secretstore_net", "{}: inserting connection to {} at {}. Connected to {} of {} nodes", self.self_node_id, node, connection.node_address(), data.connections.len() + 1, data.nodes.len()); data.connections.insert(node.clone(), connection.clone()); } let maintain_action = self.trigger.lock().on_connection_established(connection.node_id()); self.maintain_connection_trigger(maintain_action, data); true } pub fn remove(&self, data: Arc, node: &NodeId, is_inbound: bool) { { let mut data = self.data.write(); if let Entry::Occupied(entry) = data.connections.entry(node.clone()) { if entry.get().is_inbound() != is_inbound { return; } trace!(target: "secretstore_net", "{}: removing connection to {} at {}", self.self_node_id, entry.get().node_id(), entry.get().node_address()); entry.remove_entry(); } else { return; } } let maintain_action = self.trigger.lock().on_connection_closed(node); self.maintain_connection_trigger(maintain_action, data); } pub fn connected_nodes(&self) -> BTreeSet { self.data.read().connections.keys().cloned().collect() } pub fn active_connections(&self)-> Vec> { self.data.read().connections.values().cloned().collect() } pub fn disconnected_nodes(&self) -> BTreeMap { let data = self.data.read(); data.nodes.iter() .filter(|&(node_id, _)| !data.connections.contains_key(node_id)) .map(|(node_id, node_address)| (node_id.clone(), node_address.clone())) .collect() } pub fn servers_set_change_creator_connector(&self) -> Arc { self.connector.clone() } pub fn update_nodes_set(&self, data: Arc) -> Option { let maintain_action = self.trigger.lock().on_maintain(); self.maintain_connection_trigger(maintain_action, data); None } fn maintain_connection_trigger(&self, maintain_action: Option, data: Arc) { if maintain_action == Some(Maintain::SessionAndConnections) || maintain_action == Some(Maintain::Session) { let client = ClusterClientImpl::new(data); self.trigger.lock().maintain_session(&client); } if maintain_action == Some(Maintain::SessionAndConnections) || maintain_action == Some(Maintain::Connections) { let mut trigger = self.trigger.lock(); let mut data = self.data.write(); trigger.maintain_connections(&mut *data); } } } impl ClusterData { pub fn new(handle: &Handle, config: ClusterConfiguration, connections: ClusterConnections, sessions: ClusterSessions) -> Arc { Arc::new(ClusterData { handle: handle.remote().clone(), pool: CpuPool::new(config.threads), self_key_pair: config.self_key_pair.clone(), connections: connections, sessions: sessions, config: config, }) } /// Get connection to given node. pub fn connection(&self, node: &NodeId) -> Option> { self.connections.get(node) } /// Spawns a future using thread pool and schedules execution of it with event loop handle. pub fn spawn(&self, f: F) where F: Future + Send + 'static, F::Item: Send + 'static, F::Error: Send + 'static { let pool_work = self.pool.spawn(f); self.handle.spawn(move |_handle| { pool_work.then(|_| finished(())) }) } } impl Connection { pub fn new(is_inbound: bool, connection: NetConnection) -> Arc { Arc::new(Connection { node_id: connection.node_id, node_address: connection.address, is_inbound: is_inbound, stream: connection.stream, key: connection.key, last_message_time: Mutex::new(Instant::now()), }) } pub fn is_inbound(&self) -> bool { self.is_inbound } pub fn node_id(&self) -> &NodeId { &self.node_id } pub fn last_message_time(&self) -> Instant { *self.last_message_time.lock() } pub fn set_last_message_time(&self, last_message_time: Instant) { *self.last_message_time.lock() = last_message_time; } pub fn node_address(&self) -> &SocketAddr { &self.node_address } pub fn send_message(&self, message: Message) -> WriteMessage { write_encrypted_message(self.stream.clone(), &self.key, message) } pub fn read_message(&self) -> ReadMessage { read_encrypted_message(self.stream.clone(), self.key.clone()) } } impl ClusterView { pub fn new(cluster: Arc, nodes: BTreeSet, configured_nodes_count: usize) -> Self { ClusterView { configured_nodes_count: configured_nodes_count, connected_nodes_count: nodes.len(), core: Arc::new(Mutex::new(ClusterViewCore { cluster: cluster, nodes: nodes, })), } } } impl Cluster for ClusterView { fn broadcast(&self, message: Message) -> Result<(), Error> { let core = self.core.lock(); for node in core.nodes.iter().filter(|n| *n != core.cluster.self_key_pair.public()) { trace!(target: "secretstore_net", "{}: sent message {} to {}", core.cluster.self_key_pair.public(), message, node); let connection = core.cluster.connection(node).ok_or(Error::NodeDisconnected)?; core.cluster.spawn(connection.send_message(message.clone())) } Ok(()) } fn send(&self, to: &NodeId, message: Message) -> Result<(), Error> { let core = self.core.lock(); trace!(target: "secretstore_net", "{}: sent message {} to {}", core.cluster.self_key_pair.public(), message, to); let connection = core.cluster.connection(to).ok_or(Error::NodeDisconnected)?; core.cluster.spawn(connection.send_message(message)); Ok(()) } fn is_connected(&self, node: &NodeId) -> bool { self.core.lock().nodes.contains(node) } fn nodes(&self) -> BTreeSet { self.core.lock().nodes.clone() } fn configured_nodes_count(&self) -> usize { self.configured_nodes_count } fn connected_nodes_count(&self) -> usize { self.connected_nodes_count } } impl ClusterClientImpl { pub fn new(data: Arc) -> Self { ClusterClientImpl { data: data, } } fn create_key_version_negotiation_session(&self, session_id: SessionId) -> Result>, Error> { let mut connected_nodes = self.data.connections.connected_nodes(); connected_nodes.insert(self.data.self_key_pair.public().clone()); let access_key = Random.generate()?.secret().clone(); let session_id = SessionIdWithSubSession::new(session_id, access_key); let cluster = create_cluster_view(&self.data, false)?; let session = self.data.sessions.negotiation_sessions.insert(cluster, self.data.self_key_pair.public().clone(), session_id.clone(), None, false, None)?; match session.initialize(connected_nodes) { Ok(()) => Ok(session), Err(error) => { self.data.sessions.negotiation_sessions.remove(&session.id()); Err(error) } } } fn process_initialization_result, D>(result: Result<(), Error>, session: Arc, sessions: &ClusterSessionsContainer) -> Result, Error> { match result { Ok(()) if session.is_finished() => { sessions.remove(&session.id()); Ok(session) }, Ok(()) => Ok(session), Err(error) => { sessions.remove(&session.id()); Err(error) }, } } } impl ClusterClient for ClusterClientImpl { fn cluster_state(&self) -> ClusterState { self.data.connections.cluster_state() } fn new_generation_session(&self, session_id: SessionId, origin: Option
, author: Address, threshold: usize) -> Result, Error> { let mut connected_nodes = self.data.connections.connected_nodes(); connected_nodes.insert(self.data.self_key_pair.public().clone()); let cluster = create_cluster_view(&self.data, true)?; let session = self.data.sessions.generation_sessions.insert(cluster, self.data.self_key_pair.public().clone(), session_id, None, false, None)?; Self::process_initialization_result( session.initialize(origin, author, false, threshold, connected_nodes.into()), session, &self.data.sessions.generation_sessions) } fn new_encryption_session(&self, session_id: SessionId, requester: Requester, common_point: Public, encrypted_point: Public) -> Result, Error> { let mut connected_nodes = self.data.connections.connected_nodes(); connected_nodes.insert(self.data.self_key_pair.public().clone()); let cluster = create_cluster_view(&self.data, true)?; let session = self.data.sessions.encryption_sessions.insert(cluster, self.data.self_key_pair.public().clone(), session_id, None, false, None)?; Self::process_initialization_result( session.initialize(requester, common_point, encrypted_point), session, &self.data.sessions.encryption_sessions) } fn new_decryption_session(&self, session_id: SessionId, origin: Option
, requester: Requester, version: Option, is_shadow_decryption: bool, is_broadcast_decryption: bool) -> Result, Error> { let mut connected_nodes = self.data.connections.connected_nodes(); connected_nodes.insert(self.data.self_key_pair.public().clone()); let access_key = Random.generate()?.secret().clone(); let session_id = SessionIdWithSubSession::new(session_id, access_key); let cluster = create_cluster_view(&self.data, false)?; let session = self.data.sessions.decryption_sessions.insert(cluster, self.data.self_key_pair.public().clone(), session_id.clone(), None, false, Some(requester))?; let initialization_result = match version { Some(version) => session.initialize(origin, version, is_shadow_decryption, is_broadcast_decryption), None => { self.create_key_version_negotiation_session(session_id.id.clone()) .map(|version_session| { version_session.set_continue_action(ContinueAction::Decrypt(session.clone(), origin, is_shadow_decryption, is_broadcast_decryption)); ClusterCore::try_continue_session(&self.data, Some(version_session)); }) }, }; Self::process_initialization_result( initialization_result, session, &self.data.sessions.decryption_sessions) } fn new_schnorr_signing_session(&self, session_id: SessionId, requester: Requester, version: Option, message_hash: H256) -> Result, Error> { let mut connected_nodes = self.data.connections.connected_nodes(); connected_nodes.insert(self.data.self_key_pair.public().clone()); let access_key = Random.generate()?.secret().clone(); let session_id = SessionIdWithSubSession::new(session_id, access_key); let cluster = create_cluster_view(&self.data, false)?; let session = self.data.sessions.schnorr_signing_sessions.insert(cluster, self.data.self_key_pair.public().clone(), session_id.clone(), None, false, Some(requester))?; let initialization_result = match version { Some(version) => session.initialize(version, message_hash), None => { self.create_key_version_negotiation_session(session_id.id.clone()) .map(|version_session| { version_session.set_continue_action(ContinueAction::SchnorrSign(session.clone(), message_hash)); ClusterCore::try_continue_session(&self.data, Some(version_session)); }) }, }; Self::process_initialization_result( initialization_result, session, &self.data.sessions.schnorr_signing_sessions) } fn new_ecdsa_signing_session(&self, session_id: SessionId, requester: Requester, version: Option, message_hash: H256) -> Result, Error> { let mut connected_nodes = self.data.connections.connected_nodes(); connected_nodes.insert(self.data.self_key_pair.public().clone()); let access_key = Random.generate()?.secret().clone(); let session_id = SessionIdWithSubSession::new(session_id, access_key); let cluster = create_cluster_view(&self.data, false)?; let session = self.data.sessions.ecdsa_signing_sessions.insert(cluster, self.data.self_key_pair.public().clone(), session_id.clone(), None, false, Some(requester))?; let initialization_result = match version { Some(version) => session.initialize(version, message_hash), None => { self.create_key_version_negotiation_session(session_id.id.clone()) .map(|version_session| { version_session.set_continue_action(ContinueAction::EcdsaSign(session.clone(), message_hash)); ClusterCore::try_continue_session(&self.data, Some(version_session)); }) }, }; Self::process_initialization_result( initialization_result, session, &self.data.sessions.ecdsa_signing_sessions) } fn new_key_version_negotiation_session(&self, session_id: SessionId) -> Result>, Error> { let session = self.create_key_version_negotiation_session(session_id)?; Ok(session) } fn new_servers_set_change_session(&self, session_id: Option, migration_id: Option, new_nodes_set: BTreeSet, old_set_signature: Signature, new_set_signature: Signature) -> Result, Error> { let mut connected_nodes = self.data.connections.connected_nodes(); connected_nodes.insert(self.data.self_key_pair.public().clone()); let session_id = match session_id { Some(session_id) if session_id == *SERVERS_SET_CHANGE_SESSION_ID => session_id, Some(_) => return Err(Error::InvalidMessage), None => *SERVERS_SET_CHANGE_SESSION_ID, }; let cluster = create_cluster_view(&self.data, true)?; let creation_data = Some(AdminSessionCreationData::ServersSetChange(migration_id, new_nodes_set.clone())); let session = self.data.sessions.admin_sessions.insert(cluster, self.data.self_key_pair.public().clone(), session_id, None, true, creation_data)?; let initialization_result = session.as_servers_set_change().expect("servers set change session is created; qed") .initialize(new_nodes_set, old_set_signature, new_set_signature); if initialization_result.is_ok() { self.data.connections.servers_set_change_creator_connector().set_key_servers_set_change_session(session.clone()); } Self::process_initialization_result( initialization_result, session, &self.data.sessions.admin_sessions) } fn add_generation_listener(&self, listener: Arc>) { self.data.sessions.generation_sessions.add_listener(listener); } fn add_decryption_listener(&self, listener: Arc>) { self.data.sessions.decryption_sessions.add_listener(listener); } #[cfg(test)] fn connect(&self) { ClusterCore::connect_disconnected_nodes(self.data.clone()); } #[cfg(test)] fn make_faulty_generation_sessions(&self) { self.data.sessions.make_faulty_generation_sessions(); } #[cfg(test)] fn generation_session(&self, session_id: &SessionId) -> Option> { self.data.sessions.generation_sessions.get(session_id, false) } #[cfg(test)] fn key_storage(&self) -> Arc { self.data.config.key_storage.clone() } } fn make_socket_address(address: &str, port: u16) -> Result { let ip_address: IpAddr = address.parse().map_err(|_| Error::InvalidNodeAddress)?; Ok(SocketAddr::new(ip_address, port)) } #[cfg(test)] pub mod tests { use std::sync::Arc; use std::sync::atomic::{AtomicUsize, Ordering}; use std::time::{Duration, Instant}; use std::collections::{BTreeSet, VecDeque}; use parking_lot::Mutex; use tokio_core::reactor::Core; use ethereum_types::{Address, H256}; use ethkey::{Random, Generator, Public, Signature, sign}; use key_server_cluster::{NodeId, SessionId, Requester, Error, DummyAclStorage, DummyKeyStorage, MapKeyServerSet, PlainNodeKeyPair, KeyStorage}; use key_server_cluster::message::Message; use key_server_cluster::cluster::{Cluster, ClusterCore, ClusterConfiguration, ClusterClient, ClusterState}; use key_server_cluster::cluster_sessions::{ClusterSession, AdminSession, ClusterSessionsListener}; use key_server_cluster::generation_session::{SessionImpl as GenerationSession, SessionState as GenerationSessionState}; use key_server_cluster::decryption_session::{SessionImpl as DecryptionSession}; use key_server_cluster::encryption_session::{SessionImpl as EncryptionSession}; use key_server_cluster::signing_session_ecdsa::{SessionImpl as EcdsaSigningSession}; use key_server_cluster::signing_session_schnorr::{SessionImpl as SchnorrSigningSession}; use key_server_cluster::key_version_negotiation_session::{SessionImpl as KeyVersionNegotiationSession, IsolatedSessionTransport as KeyVersionNegotiationSessionTransport}; const TIMEOUT: Duration = Duration::from_millis(300); #[derive(Default)] pub struct DummyClusterClient { pub generation_requests_count: AtomicUsize, } #[derive(Debug)] pub struct DummyCluster { id: NodeId, data: Mutex, } #[derive(Debug, Default)] struct DummyClusterData { nodes: BTreeSet, messages: VecDeque<(NodeId, Message)>, } impl ClusterClient for DummyClusterClient { fn cluster_state(&self) -> ClusterState { unimplemented!("test-only") } fn new_generation_session(&self, _session_id: SessionId, _origin: Option
, _author: Address, _threshold: usize) -> Result, Error> { self.generation_requests_count.fetch_add(1, Ordering::Relaxed); Err(Error::Internal("test-error".into())) } fn new_encryption_session(&self, _session_id: SessionId, _requester: Requester, _common_point: Public, _encrypted_point: Public) -> Result, Error> { unimplemented!("test-only") } fn new_decryption_session(&self, _session_id: SessionId, _origin: Option
, _requester: Requester, _version: Option, _is_shadow_decryption: bool, _is_broadcast_session: bool) -> Result, Error> { unimplemented!("test-only") } fn new_schnorr_signing_session(&self, _session_id: SessionId, _requester: Requester, _version: Option, _message_hash: H256) -> Result, Error> { unimplemented!("test-only") } fn new_ecdsa_signing_session(&self, _session_id: SessionId, _requester: Requester, _version: Option, _message_hash: H256) -> Result, Error> { unimplemented!("test-only") } fn new_key_version_negotiation_session(&self, _session_id: SessionId) -> Result>, Error> { unimplemented!("test-only") } fn new_servers_set_change_session(&self, _session_id: Option, _migration_id: Option, _new_nodes_set: BTreeSet, _old_set_signature: Signature, _new_set_signature: Signature) -> Result, Error> { unimplemented!("test-only") } fn add_generation_listener(&self, _listener: Arc>) {} fn add_decryption_listener(&self, _listener: Arc>) {} fn make_faulty_generation_sessions(&self) { unimplemented!("test-only") } fn generation_session(&self, _session_id: &SessionId) -> Option> { unimplemented!("test-only") } fn connect(&self) { unimplemented!("test-only") } fn key_storage(&self) -> Arc { unimplemented!("test-only") } } impl DummyCluster { pub fn new(id: NodeId) -> Self { DummyCluster { id: id, data: Mutex::new(DummyClusterData::default()) } } pub fn node(&self) -> NodeId { self.id.clone() } pub fn add_node(&self, node: NodeId) { self.data.lock().nodes.insert(node); } pub fn add_nodes>(&self, nodes: I) { self.data.lock().nodes.extend(nodes) } pub fn remove_node(&self, node: &NodeId) { self.data.lock().nodes.remove(node); } pub fn take_message(&self) -> Option<(NodeId, Message)> { self.data.lock().messages.pop_front() } } impl Cluster for DummyCluster { fn broadcast(&self, message: Message) -> Result<(), Error> { let mut data = self.data.lock(); let all_nodes: Vec<_> = data.nodes.iter().cloned().filter(|n| n != &self.id).collect(); for node in all_nodes { data.messages.push_back((node, message.clone())); } Ok(()) } fn send(&self, to: &NodeId, message: Message) -> Result<(), Error> { debug_assert!(&self.id != to); self.data.lock().messages.push_back((to.clone(), message)); Ok(()) } fn is_connected(&self, node: &NodeId) -> bool { let data = self.data.lock(); &self.id == node || data.nodes.contains(node) } fn nodes(&self) -> BTreeSet { self.data.lock().nodes.iter().cloned().collect() } fn configured_nodes_count(&self) -> usize { self.data.lock().nodes.len() } fn connected_nodes_count(&self) -> usize { self.data.lock().nodes.len() } } pub fn loop_until(core: &mut Core, timeout: Duration, predicate: F) where F: Fn() -> bool { let start = Instant::now(); loop { core.turn(Some(Duration::from_millis(1))); if predicate() { break; } if Instant::now() - start > timeout { panic!("no result in {:?}", timeout); } } } pub fn all_connections_established(cluster: &Arc) -> bool { cluster.config().key_server_set.snapshot().new_set.keys() .filter(|p| *p != cluster.config().self_key_pair.public()) .all(|p| cluster.connection(p).is_some()) } pub fn make_clusters(core: &Core, ports_begin: u16, num_nodes: usize) -> Vec> { let key_pairs: Vec<_> = (0..num_nodes).map(|_| Random.generate().unwrap()).collect(); let cluster_params: Vec<_> = (0..num_nodes).map(|i| ClusterConfiguration { threads: 1, self_key_pair: Arc::new(PlainNodeKeyPair::new(key_pairs[i].clone())), listen_address: ("127.0.0.1".to_owned(), ports_begin + i as u16), key_server_set: Arc::new(MapKeyServerSet::new(key_pairs.iter().enumerate() .map(|(j, kp)| (kp.public().clone(), format!("127.0.0.1:{}", ports_begin + j as u16).parse().unwrap())) .collect())), allow_connecting_to_higher_nodes: false, key_storage: Arc::new(DummyKeyStorage::default()), acl_storage: Arc::new(DummyAclStorage::default()), admin_public: None, auto_migrate_enabled: false, }).collect(); let clusters: Vec<_> = cluster_params.into_iter().enumerate() .map(|(_, params)| ClusterCore::new(core.handle(), params).unwrap()) .collect(); clusters } pub fn run_clusters(clusters: &[Arc]) { for cluster in clusters { cluster.run_listener().unwrap(); } for cluster in clusters { cluster.run_connections().unwrap(); } } #[test] fn cluster_connects_to_other_nodes() { let mut core = Core::new().unwrap(); let clusters = make_clusters(&core, 6010, 3); run_clusters(&clusters); loop_until(&mut core, TIMEOUT, || clusters.iter().all(all_connections_established)); } #[test] fn cluster_wont_start_generation_session_if_not_fully_connected() { let core = Core::new().unwrap(); let clusters = make_clusters(&core, 6013, 3); clusters[0].run().unwrap(); match clusters[0].client().new_generation_session(SessionId::default(), Default::default(), Default::default(), 1) { Err(Error::NodeDisconnected) => (), Err(e) => panic!("unexpected error {:?}", e), _ => panic!("unexpected success"), } } #[test] fn error_in_generation_session_broadcasted_to_all_other_nodes() { //::logger::init_log(); let mut core = Core::new().unwrap(); let clusters = make_clusters(&core, 6016, 3); run_clusters(&clusters); loop_until(&mut core, TIMEOUT, || clusters.iter().all(all_connections_established)); // ask one of nodes to produce faulty generation sessions clusters[1].client().make_faulty_generation_sessions(); // start && wait for generation session to fail let session = clusters[0].client().new_generation_session(SessionId::default(), Default::default(), Default::default(), 1).unwrap(); loop_until(&mut core, TIMEOUT, || session.joint_public_and_secret().is_some() && clusters[0].client().generation_session(&SessionId::default()).is_none()); assert!(session.joint_public_and_secret().unwrap().is_err()); // check that faulty session is either removed from all nodes, or nonexistent (already removed) for i in 1..3 { if let Some(session) = clusters[i].client().generation_session(&SessionId::default()) { // wait for both session completion && session removal (session completion event is fired // before session is removed from its own container by cluster) loop_until(&mut core, TIMEOUT, || session.joint_public_and_secret().is_some() && clusters[i].client().generation_session(&SessionId::default()).is_none()); assert!(session.joint_public_and_secret().unwrap().is_err()); } } } #[test] fn generation_session_completion_signalled_if_failed_on_master() { //::logger::init_log(); let mut core = Core::new().unwrap(); let clusters = make_clusters(&core, 6025, 3); run_clusters(&clusters); loop_until(&mut core, TIMEOUT, || clusters.iter().all(all_connections_established)); // ask one of nodes to produce faulty generation sessions clusters[0].client().make_faulty_generation_sessions(); // start && wait for generation session to fail let session = clusters[0].client().new_generation_session(SessionId::default(), Default::default(), Default::default(), 1).unwrap(); loop_until(&mut core, TIMEOUT, || session.joint_public_and_secret().is_some() && clusters[0].client().generation_session(&SessionId::default()).is_none()); assert!(session.joint_public_and_secret().unwrap().is_err()); // check that faulty session is either removed from all nodes, or nonexistent (already removed) for i in 1..3 { if let Some(session) = clusters[i].client().generation_session(&SessionId::default()) { // wait for both session completion && session removal (session completion event is fired // before session is removed from its own container by cluster) loop_until(&mut core, TIMEOUT, || session.joint_public_and_secret().is_some() && clusters[i].client().generation_session(&SessionId::default()).is_none()); assert!(session.joint_public_and_secret().unwrap().is_err()); } } } #[test] fn generation_session_is_removed_when_succeeded() { //::logger::init_log(); let mut core = Core::new().unwrap(); let clusters = make_clusters(&core, 6019, 3); run_clusters(&clusters); loop_until(&mut core, TIMEOUT, || clusters.iter().all(all_connections_established)); // start && wait for generation session to complete let session = clusters[0].client().new_generation_session(SessionId::default(), Default::default(), Default::default(), 1).unwrap(); loop_until(&mut core, TIMEOUT, || (session.state() == GenerationSessionState::Finished || session.state() == GenerationSessionState::Failed) && clusters[0].client().generation_session(&SessionId::default()).is_none()); assert!(session.joint_public_and_secret().unwrap().is_ok()); // check that session is either removed from all nodes, or nonexistent (already removed) for i in 1..3 { if let Some(session) = clusters[i].client().generation_session(&SessionId::default()) { loop_until(&mut core, TIMEOUT, || (session.state() == GenerationSessionState::Finished || session.state() == GenerationSessionState::Failed) && clusters[i].client().generation_session(&SessionId::default()).is_none()); assert!(session.joint_public_and_secret().unwrap().is_err()); } } } #[test] fn sessions_are_removed_when_initialization_fails() { let mut core = Core::new().unwrap(); let clusters = make_clusters(&core, 6022, 3); run_clusters(&clusters); loop_until(&mut core, TIMEOUT, || clusters.iter().all(all_connections_established)); // generation session { // try to start generation session => fail in initialization assert_eq!(clusters[0].client().new_generation_session(SessionId::default(), Default::default(), Default::default(), 100).map(|_| ()), Err(Error::NotEnoughNodesForThreshold)); // try to start generation session => fails in initialization assert_eq!(clusters[0].client().new_generation_session(SessionId::default(), Default::default(), Default::default(), 100).map(|_| ()), Err(Error::NotEnoughNodesForThreshold)); assert!(clusters[0].data.sessions.generation_sessions.is_empty()); } // decryption session { // try to start decryption session => fails in initialization assert_eq!(clusters[0].client().new_decryption_session(Default::default(), Default::default(), Default::default(), Some(Default::default()), false, false).map(|_| ()), Err(Error::InvalidMessage)); // try to start generation session => fails in initialization assert_eq!(clusters[0].client().new_decryption_session(Default::default(), Default::default(), Default::default(), Some(Default::default()), false, false).map(|_| ()), Err(Error::InvalidMessage)); assert!(clusters[0].data.sessions.decryption_sessions.is_empty()); assert!(clusters[0].data.sessions.negotiation_sessions.is_empty()); } } #[test] fn schnorr_signing_session_completes_if_node_does_not_have_a_share() { //::logger::init_log(); let mut core = Core::new().unwrap(); let clusters = make_clusters(&core, 6028, 3); run_clusters(&clusters); loop_until(&mut core, TIMEOUT, || clusters.iter().all(all_connections_established)); // start && wait for generation session to complete let session = clusters[0].client().new_generation_session(SessionId::default(), Default::default(), Default::default(), 1).unwrap(); loop_until(&mut core, TIMEOUT, || (session.state() == GenerationSessionState::Finished || session.state() == GenerationSessionState::Failed) && clusters[0].client().generation_session(&SessionId::default()).is_none()); assert!(session.joint_public_and_secret().unwrap().is_ok()); // now remove share from node2 assert!((0..3).all(|i| clusters[i].data.sessions.generation_sessions.is_empty())); clusters[2].data.config.key_storage.remove(&Default::default()).unwrap(); // and try to sign message with generated key let signature = sign(Random.generate().unwrap().secret(), &Default::default()).unwrap(); let session0 = clusters[0].client().new_schnorr_signing_session(Default::default(), signature.into(), None, Default::default()).unwrap(); let session = clusters[0].data.sessions.schnorr_signing_sessions.first().unwrap(); loop_until(&mut core, TIMEOUT, || session.is_finished() && (0..3).all(|i| clusters[i].data.sessions.schnorr_signing_sessions.is_empty())); session0.wait().unwrap(); // and try to sign message with generated key using node that has no key share let signature = sign(Random.generate().unwrap().secret(), &Default::default()).unwrap(); let session2 = clusters[2].client().new_schnorr_signing_session(Default::default(), signature.into(), None, Default::default()).unwrap(); let session = clusters[2].data.sessions.schnorr_signing_sessions.first().unwrap(); loop_until(&mut core, TIMEOUT, || session.is_finished() && (0..3).all(|i| clusters[i].data.sessions.schnorr_signing_sessions.is_empty())); session2.wait().unwrap(); // now remove share from node1 clusters[1].data.config.key_storage.remove(&Default::default()).unwrap(); // and try to sign message with generated key let signature = sign(Random.generate().unwrap().secret(), &Default::default()).unwrap(); let session1 = clusters[0].client().new_schnorr_signing_session(Default::default(), signature.into(), None, Default::default()).unwrap(); let session = clusters[0].data.sessions.schnorr_signing_sessions.first().unwrap(); loop_until(&mut core, TIMEOUT, || session.is_finished()); session1.wait().unwrap_err(); } #[test] fn ecdsa_signing_session_completes_if_node_does_not_have_a_share() { //::logger::init_log(); let mut core = Core::new().unwrap(); let clusters = make_clusters(&core, 6041, 4); run_clusters(&clusters); loop_until(&mut core, TIMEOUT, || clusters.iter().all(all_connections_established)); // start && wait for generation session to complete let session = clusters[0].client().new_generation_session(SessionId::default(), Default::default(), Default::default(), 1).unwrap(); loop_until(&mut core, TIMEOUT, || (session.state() == GenerationSessionState::Finished || session.state() == GenerationSessionState::Failed) && clusters[0].client().generation_session(&SessionId::default()).is_none()); assert!(session.joint_public_and_secret().unwrap().is_ok()); // now remove share from node2 assert!((0..3).all(|i| clusters[i].data.sessions.generation_sessions.is_empty())); clusters[2].data.config.key_storage.remove(&Default::default()).unwrap(); // and try to sign message with generated key let signature = sign(Random.generate().unwrap().secret(), &Default::default()).unwrap(); let session0 = clusters[0].client().new_ecdsa_signing_session(Default::default(), signature.into(), None, H256::random()).unwrap(); let session = clusters[0].data.sessions.ecdsa_signing_sessions.first().unwrap(); loop_until(&mut core, Duration::from_millis(1000), || session.is_finished() && (0..3).all(|i| clusters[i].data.sessions.ecdsa_signing_sessions.is_empty())); session0.wait().unwrap(); // and try to sign message with generated key using node that has no key share let signature = sign(Random.generate().unwrap().secret(), &Default::default()).unwrap(); let session2 = clusters[2].client().new_ecdsa_signing_session(Default::default(), signature.into(), None, H256::random()).unwrap(); let session = clusters[2].data.sessions.ecdsa_signing_sessions.first().unwrap(); loop_until(&mut core, Duration::from_millis(1000), || session.is_finished() && (0..3).all(|i| clusters[i].data.sessions.ecdsa_signing_sessions.is_empty())); session2.wait().unwrap(); // now remove share from node1 clusters[1].data.config.key_storage.remove(&Default::default()).unwrap(); // and try to sign message with generated key let signature = sign(Random.generate().unwrap().secret(), &Default::default()).unwrap(); let session1 = clusters[0].client().new_ecdsa_signing_session(Default::default(), signature.into(), None, H256::random()).unwrap(); let session = clusters[0].data.sessions.ecdsa_signing_sessions.first().unwrap(); loop_until(&mut core, Duration::from_millis(1000), || session.is_finished()); session1.wait().unwrap_err(); } }