use crate::peer_store::{PeerStoreProvider, ProtocolHandle as ProtocolHandleT};
use futures::{channel::oneshot, future::Either, FutureExt, StreamExt};
use libp2p::PeerId;
use log::{debug, error, trace, warn};
use sc_utils::mpsc::{tracing_unbounded, TracingUnboundedReceiver, TracingUnboundedSender};
use sp_arithmetic::traits::SaturatedConversion;
use std::{
collections::{HashMap, HashSet},
sync::Arc,
time::{Duration, Instant},
};
use wasm_timer::Delay;
pub const LOG_TARGET: &str = "peerset";
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct SetId(usize);
impl SetId {
pub const fn from(id: usize) -> Self {
Self(id)
}
}
impl From<usize> for SetId {
fn from(id: usize) -> Self {
Self(id)
}
}
impl From<SetId> for usize {
fn from(id: SetId) -> Self {
id.0
}
}
#[derive(Debug)]
pub struct ProtoSetConfig {
pub in_peers: u32,
pub out_peers: u32,
pub reserved_nodes: HashSet<PeerId>,
pub reserved_only: bool,
}
#[derive(Debug, PartialEq)]
pub enum Message {
Connect {
set_id: SetId,
peer_id: PeerId,
},
Drop {
set_id: SetId,
peer_id: PeerId,
},
Accept(IncomingIndex),
Reject(IncomingIndex),
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct IncomingIndex(pub u64);
impl From<u64> for IncomingIndex {
fn from(val: u64) -> Self {
Self(val)
}
}
#[derive(Debug)]
enum Action {
AddReservedPeer(PeerId),
RemoveReservedPeer(PeerId),
SetReservedPeers(HashSet<PeerId>),
SetReservedOnly(bool),
DisconnectPeer(PeerId),
GetReservedPeers(oneshot::Sender<Vec<PeerId>>),
}
#[derive(Debug)]
enum Event {
IncomingConnection(PeerId, IncomingIndex),
Dropped(PeerId),
}
#[derive(Debug, Clone)]
pub struct ProtocolHandle {
actions_tx: TracingUnboundedSender<Action>,
events_tx: TracingUnboundedSender<Event>,
}
impl ProtocolHandle {
pub fn add_reserved_peer(&self, peer_id: PeerId) {
let _ = self.actions_tx.unbounded_send(Action::AddReservedPeer(peer_id));
}
pub fn remove_reserved_peer(&self, peer_id: PeerId) {
let _ = self.actions_tx.unbounded_send(Action::RemoveReservedPeer(peer_id));
}
pub fn set_reserved_peers(&self, peer_ids: HashSet<PeerId>) {
let _ = self.actions_tx.unbounded_send(Action::SetReservedPeers(peer_ids));
}
pub fn set_reserved_only(&self, reserved: bool) {
let _ = self.actions_tx.unbounded_send(Action::SetReservedOnly(reserved));
}
pub fn disconnect_peer(&self, peer_id: PeerId) {
let _ = self.actions_tx.unbounded_send(Action::DisconnectPeer(peer_id));
}
pub fn reserved_peers(&self, pending_response: oneshot::Sender<Vec<PeerId>>) {
let _ = self.actions_tx.unbounded_send(Action::GetReservedPeers(pending_response));
}
pub fn incoming_connection(&self, peer_id: PeerId, incoming_index: IncomingIndex) {
let _ = self
.events_tx
.unbounded_send(Event::IncomingConnection(peer_id, incoming_index));
}
pub fn dropped(&self, peer_id: PeerId) {
let _ = self.events_tx.unbounded_send(Event::Dropped(peer_id));
}
}
impl ProtocolHandleT for ProtocolHandle {
fn disconnect_peer(&self, peer_id: sc_network_types::PeerId) {
let _ = self.actions_tx.unbounded_send(Action::DisconnectPeer(peer_id.into()));
}
}
#[derive(Clone, Copy, Debug)]
enum Direction {
Inbound,
Outbound,
}
#[derive(Clone, Debug)]
enum PeerState {
Connected(Direction),
NotConnected,
}
impl PeerState {
fn is_connected(&self) -> bool {
matches!(self, PeerState::Connected(_))
}
}
impl Default for PeerState {
fn default() -> PeerState {
PeerState::NotConnected
}
}
#[derive(Debug)]
pub struct ProtocolController {
set_id: SetId,
actions_rx: TracingUnboundedReceiver<Action>,
events_rx: TracingUnboundedReceiver<Event>,
num_in: u32,
num_out: u32,
max_in: u32,
max_out: u32,
nodes: HashMap<PeerId, Direction>,
reserved_nodes: HashMap<PeerId, PeerState>,
reserved_only: bool,
next_periodic_alloc_slots: Instant,
to_notifications: TracingUnboundedSender<Message>,
peer_store: Arc<dyn PeerStoreProvider>,
}
impl ProtocolController {
pub fn new(
set_id: SetId,
config: ProtoSetConfig,
to_notifications: TracingUnboundedSender<Message>,
peer_store: Arc<dyn PeerStoreProvider>,
) -> (ProtocolHandle, ProtocolController) {
let (actions_tx, actions_rx) = tracing_unbounded("mpsc_api_protocol", 10_000);
let (events_tx, events_rx) = tracing_unbounded("mpsc_notifications_protocol", 10_000);
let handle = ProtocolHandle { actions_tx, events_tx };
peer_store.register_protocol(Arc::new(handle.clone()));
let reserved_nodes =
config.reserved_nodes.iter().map(|p| (*p, PeerState::NotConnected)).collect();
let controller = ProtocolController {
set_id,
actions_rx,
events_rx,
num_in: 0,
num_out: 0,
max_in: config.in_peers,
max_out: config.out_peers,
nodes: HashMap::new(),
reserved_nodes,
reserved_only: config.reserved_only,
next_periodic_alloc_slots: Instant::now(),
to_notifications,
peer_store,
};
(handle, controller)
}
pub async fn run(mut self) {
while self.next_action().await {}
}
pub async fn next_action(&mut self) -> bool {
let either = loop {
let mut next_alloc_slots = Delay::new_at(self.next_periodic_alloc_slots).fuse();
futures::select_biased! {
event = self.events_rx.next() => match event {
Some(event) => break Either::Left(event),
None => return false,
},
action = self.actions_rx.next() => match action {
Some(action) => break Either::Right(action),
None => return false,
},
_ = next_alloc_slots => {
self.alloc_slots();
self.next_periodic_alloc_slots = Instant::now() + Duration::new(1, 0);
},
}
};
match either {
Either::Left(event) => self.process_event(event),
Either::Right(action) => self.process_action(action),
}
true
}
fn process_event(&mut self, event: Event) {
match event {
Event::IncomingConnection(peer_id, index) =>
self.on_incoming_connection(peer_id, index),
Event::Dropped(peer_id) => self.on_peer_dropped(peer_id),
}
}
fn process_action(&mut self, action: Action) {
match action {
Action::AddReservedPeer(peer_id) => self.on_add_reserved_peer(peer_id),
Action::RemoveReservedPeer(peer_id) => self.on_remove_reserved_peer(peer_id),
Action::SetReservedPeers(peer_ids) => self.on_set_reserved_peers(peer_ids),
Action::SetReservedOnly(reserved_only) => self.on_set_reserved_only(reserved_only),
Action::DisconnectPeer(peer_id) => self.on_disconnect_peer(peer_id),
Action::GetReservedPeers(pending_response) =>
self.on_get_reserved_peers(pending_response),
}
}
fn accept_connection(&mut self, peer_id: PeerId, incoming_index: IncomingIndex) {
trace!(
target: LOG_TARGET,
"Accepting {peer_id} ({incoming_index:?}) on {:?} ({}/{} num_in/max_in).",
self.set_id,
self.num_in,
self.max_in,
);
let _ = self.to_notifications.unbounded_send(Message::Accept(incoming_index));
}
fn reject_connection(&mut self, peer_id: PeerId, incoming_index: IncomingIndex) {
trace!(
target: LOG_TARGET,
"Rejecting {peer_id} ({incoming_index:?}) on {:?} ({}/{} num_in/max_in).",
self.set_id,
self.num_in,
self.max_in,
);
let _ = self.to_notifications.unbounded_send(Message::Reject(incoming_index));
}
fn start_connection(&mut self, peer_id: PeerId) {
trace!(
target: LOG_TARGET,
"Connecting to {peer_id} on {:?} ({}/{} num_out/max_out).",
self.set_id,
self.num_out,
self.max_out,
);
let _ = self
.to_notifications
.unbounded_send(Message::Connect { set_id: self.set_id, peer_id });
}
fn drop_connection(&mut self, peer_id: PeerId) {
trace!(
target: LOG_TARGET,
"Dropping {peer_id} on {:?} ({}/{} num_in/max_in, {}/{} num_out/max_out).",
self.set_id,
self.num_in,
self.max_in,
self.num_out,
self.max_out,
);
let _ = self
.to_notifications
.unbounded_send(Message::Drop { set_id: self.set_id, peer_id });
}
fn report_disconnect(&mut self, peer_id: PeerId) {
self.peer_store.report_disconnect(peer_id.into());
}
fn is_banned(&self, peer_id: &PeerId) -> bool {
self.peer_store.is_banned(&peer_id.into())
}
fn on_add_reserved_peer(&mut self, peer_id: PeerId) {
if self.reserved_nodes.contains_key(&peer_id) {
warn!(
target: LOG_TARGET,
"Trying to add an already reserved node {peer_id} as reserved on {:?}.",
self.set_id,
);
return
}
let state = match self.nodes.remove(&peer_id) {
Some(direction) => {
trace!(
target: LOG_TARGET,
"Marking previously connected node {} ({:?}) as reserved on {:?}.",
peer_id,
direction,
self.set_id
);
PeerState::Connected(direction)
},
None => {
trace!(target: LOG_TARGET, "Adding reserved node {peer_id} on {:?}.", self.set_id,);
PeerState::NotConnected
},
};
self.reserved_nodes.insert(peer_id, state.clone());
match state {
PeerState::Connected(Direction::Inbound) => self.num_in -= 1,
PeerState::Connected(Direction::Outbound) => self.num_out -= 1,
PeerState::NotConnected => self.alloc_slots(),
}
}
fn on_remove_reserved_peer(&mut self, peer_id: PeerId) {
let state = match self.reserved_nodes.remove(&peer_id) {
Some(state) => state,
None => {
warn!(
target: LOG_TARGET,
"Trying to remove unknown reserved node {peer_id} from {:?}.", self.set_id,
);
return
},
};
if let PeerState::Connected(direction) = state {
let disconnect = self.reserved_only ||
match direction {
Direction::Inbound => self.num_in >= self.max_in,
Direction::Outbound => self.num_out >= self.max_out,
};
if disconnect {
trace!(
target: LOG_TARGET,
"Disconnecting previously reserved node {peer_id} ({direction:?}) on {:?}.",
self.set_id,
);
self.drop_connection(peer_id);
} else {
trace!(
target: LOG_TARGET,
"Making a connected reserved node {peer_id} ({:?}) on {:?} a regular one.",
direction,
self.set_id,
);
match direction {
Direction::Inbound => self.num_in += 1,
Direction::Outbound => self.num_out += 1,
}
let prev = self.nodes.insert(peer_id, direction);
assert!(prev.is_none(), "Corrupted state: reserved node was also non-reserved.");
}
} else {
trace!(
target: LOG_TARGET,
"Removed disconnected reserved node {peer_id} from {:?}.",
self.set_id,
);
}
}
fn on_set_reserved_peers(&mut self, peer_ids: HashSet<PeerId>) {
let current = self.reserved_nodes.keys().cloned().collect();
let to_insert = peer_ids.difference(¤t).cloned().collect::<Vec<_>>();
let to_remove = current.difference(&peer_ids).cloned().collect::<Vec<_>>();
for node in to_insert {
self.on_add_reserved_peer(node);
}
for node in to_remove {
self.on_remove_reserved_peer(node);
}
}
fn on_set_reserved_only(&mut self, reserved_only: bool) {
trace!(target: LOG_TARGET, "Set reserved only to `{reserved_only}` on {:?}", self.set_id);
self.reserved_only = reserved_only;
if !reserved_only {
return self.alloc_slots()
}
self.nodes
.iter()
.map(|(k, v)| (*k, *v))
.collect::<Vec<(_, _)>>()
.iter()
.for_each(|(peer_id, direction)| {
match direction {
Direction::Inbound => self.num_in -= 1,
Direction::Outbound => self.num_out -= 1,
}
self.drop_connection(*peer_id)
});
self.nodes.clear();
}
fn on_get_reserved_peers(&self, pending_response: oneshot::Sender<Vec<PeerId>>) {
let _ = pending_response.send(self.reserved_nodes.keys().cloned().collect());
}
fn on_disconnect_peer(&mut self, peer_id: PeerId) {
if self.reserved_nodes.contains_key(&peer_id) {
debug!(
target: LOG_TARGET,
"Ignoring request to disconnect reserved peer {peer_id} from {:?}.", self.set_id,
);
return
}
match self.nodes.remove(&peer_id) {
Some(direction) => {
trace!(
target: LOG_TARGET,
"Disconnecting peer {peer_id} ({direction:?}) from {:?}.",
self.set_id
);
match direction {
Direction::Inbound => self.num_in -= 1,
Direction::Outbound => self.num_out -= 1,
}
self.drop_connection(peer_id);
},
None => {
debug!(
target: LOG_TARGET,
"Trying to disconnect unknown peer {peer_id} from {:?}.", self.set_id,
);
},
}
}
fn on_incoming_connection(&mut self, peer_id: PeerId, incoming_index: IncomingIndex) {
trace!(
target: LOG_TARGET,
"Incoming connection from peer {peer_id} ({incoming_index:?}) on {:?}.",
self.set_id,
);
if self.reserved_only && !self.reserved_nodes.contains_key(&peer_id) {
self.reject_connection(peer_id, incoming_index);
return
}
if let Some(state) = self.reserved_nodes.get_mut(&peer_id) {
match state {
PeerState::Connected(ref mut direction) => {
*direction = Direction::Inbound;
self.accept_connection(peer_id, incoming_index);
},
PeerState::NotConnected =>
if self.peer_store.is_banned(&peer_id.into()) {
self.reject_connection(peer_id, incoming_index);
} else {
*state = PeerState::Connected(Direction::Inbound);
self.accept_connection(peer_id, incoming_index);
},
}
return
}
if let Some(direction) = self.nodes.remove(&peer_id) {
trace!(
target: LOG_TARGET,
"Handling incoming connection from peer {} we think we already connected as {:?} on {:?}.",
peer_id,
direction,
self.set_id
);
match direction {
Direction::Inbound => self.num_in -= 1,
Direction::Outbound => self.num_out -= 1,
}
}
if self.num_in >= self.max_in {
self.reject_connection(peer_id, incoming_index);
return
}
if self.is_banned(&peer_id) {
self.reject_connection(peer_id, incoming_index);
return
}
self.num_in += 1;
self.nodes.insert(peer_id, Direction::Inbound);
self.accept_connection(peer_id, incoming_index);
}
fn on_peer_dropped(&mut self, peer_id: PeerId) {
self.on_peer_dropped_inner(peer_id).unwrap_or_else(|peer_id| {
trace!(
target: LOG_TARGET,
"Received `Action::Dropped` for not connected peer {peer_id} on {:?}.",
self.set_id,
)
});
}
fn on_peer_dropped_inner(&mut self, peer_id: PeerId) -> Result<(), PeerId> {
if self.drop_reserved_peer(&peer_id)? || self.drop_regular_peer(&peer_id) {
self.report_disconnect(peer_id);
Ok(())
} else {
Err(peer_id)
}
}
fn drop_reserved_peer(&mut self, peer_id: &PeerId) -> Result<bool, PeerId> {
let Some(state) = self.reserved_nodes.get_mut(peer_id) else { return Ok(false) };
if let PeerState::Connected(direction) = state {
trace!(
target: LOG_TARGET,
"Reserved peer {peer_id} ({direction:?}) dropped from {:?}.",
self.set_id,
);
*state = PeerState::NotConnected;
Ok(true)
} else {
Err(*peer_id)
}
}
fn drop_regular_peer(&mut self, peer_id: &PeerId) -> bool {
let Some(direction) = self.nodes.remove(peer_id) else { return false };
trace!(
target: LOG_TARGET,
"Peer {peer_id} ({direction:?}) dropped from {:?}.",
self.set_id,
);
match direction {
Direction::Inbound => self.num_in -= 1,
Direction::Outbound => self.num_out -= 1,
}
true
}
fn alloc_slots(&mut self) {
self.reserved_nodes
.iter_mut()
.filter_map(|(peer_id, state)| {
(!state.is_connected() && !self.peer_store.is_banned(&peer_id.into())).then(|| {
*state = PeerState::Connected(Direction::Outbound);
peer_id
})
})
.cloned()
.collect::<Vec<_>>()
.into_iter()
.for_each(|peer_id| {
self.start_connection(peer_id);
});
if self.reserved_only || self.num_out >= self.max_out {
return
}
let available_slots = (self.max_out - self.num_out).saturated_into();
let ignored = self
.reserved_nodes
.keys()
.map(From::from)
.collect::<HashSet<sc_network_types::PeerId>>()
.union(
&self.nodes.keys().map(From::from).collect::<HashSet<sc_network_types::PeerId>>(),
)
.cloned()
.collect();
let candidates = self
.peer_store
.outgoing_candidates(available_slots, ignored)
.into_iter()
.filter_map(|peer_id| {
(!self.reserved_nodes.contains_key(&peer_id.into()) &&
!self.nodes.contains_key(&peer_id.into()))
.then_some(peer_id)
.or_else(|| {
error!(
target: LOG_TARGET,
"`PeerStore` returned a node we asked to ignore: {peer_id}.",
);
debug_assert!(false, "`PeerStore` returned a node we asked to ignore.");
None
})
})
.collect::<Vec<_>>();
if candidates.len() > available_slots {
error!(
target: LOG_TARGET,
"`PeerStore` returned more nodes than there are slots available.",
);
debug_assert!(false, "`PeerStore` returned more nodes than there are slots available.");
}
candidates.into_iter().take(available_slots).for_each(|peer_id| {
self.num_out += 1;
self.nodes.insert(peer_id.into(), Direction::Outbound);
self.start_connection(peer_id.into());
})
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::{
peer_store::{PeerStoreProvider, ProtocolHandle as ProtocolHandleT},
ReputationChange,
};
use libp2p::PeerId;
use sc_network_common::role::ObservedRole;
use sc_utils::mpsc::{tracing_unbounded, TryRecvError};
use std::collections::HashSet;
mockall::mock! {
#[derive(Debug)]
pub PeerStoreHandle {}
impl PeerStoreProvider for PeerStoreHandle {
fn is_banned(&self, peer_id: &sc_network_types::PeerId) -> bool;
fn register_protocol(&self, protocol_handle: Arc<dyn ProtocolHandleT>);
fn report_disconnect(&self, peer_id: sc_network_types::PeerId);
fn set_peer_role(&self, peer_id: &sc_network_types::PeerId, role: ObservedRole);
fn report_peer(&self, peer_id: sc_network_types::PeerId, change: ReputationChange);
fn peer_reputation(&self, peer_id: &sc_network_types::PeerId) -> i32;
fn peer_role(&self, peer_id: &sc_network_types::PeerId) -> Option<ObservedRole>;
fn outgoing_candidates(&self, count: usize, ignored: HashSet<sc_network_types::PeerId>) -> Vec<sc_network_types::PeerId>;
fn add_known_peer(&self, peer_id: sc_network_types::PeerId);
}
}
#[test]
fn reserved_nodes_are_connected_dropped_and_accepted() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 0,
out_peers: 0,
reserved_nodes: std::iter::once(reserved1).collect(),
reserved_only: true,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(4).return_const(false);
peer_store.expect_report_disconnect().times(2).return_const(());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.on_add_reserved_peer(reserved2);
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved2 }));
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
controller.on_peer_dropped(reserved1);
controller.on_peer_dropped(reserved2);
let incoming1 = IncomingIndex(1);
controller.on_incoming_connection(reserved1, incoming1);
assert_eq!(rx.try_recv().unwrap(), Message::Accept(incoming1));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
let incoming2 = IncomingIndex(2);
controller.on_incoming_connection(reserved2, incoming2);
assert_eq!(rx.try_recv().unwrap(), Message::Accept(incoming2));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
}
#[test]
fn banned_reserved_nodes_are_not_connected_and_not_accepted() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 0,
out_peers: 0,
reserved_nodes: std::iter::once(reserved1).collect(),
reserved_only: true,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(6).return_const(true);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.on_add_reserved_peer(reserved2);
controller.alloc_slots();
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
let incoming1 = IncomingIndex(1);
controller.on_incoming_connection(reserved1, incoming1);
assert_eq!(rx.try_recv().unwrap(), Message::Reject(incoming1));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
let incoming2 = IncomingIndex(2);
controller.on_incoming_connection(reserved2, incoming2);
assert_eq!(rx.try_recv().unwrap(), Message::Reject(incoming2));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
}
#[test]
fn we_try_to_reconnect_to_dropped_reserved_nodes() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 0,
out_peers: 0,
reserved_nodes: std::iter::once(reserved1).collect(),
reserved_only: true,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(4).return_const(false);
peer_store.expect_report_disconnect().times(2).return_const(());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.on_add_reserved_peer(reserved2);
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved2 }));
controller.on_peer_dropped(reserved1);
controller.on_peer_dropped(reserved2);
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved2 }));
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
}
#[test]
fn nodes_supplied_by_peer_store_are_connected() {
let peer1 = PeerId::random();
let peer2 = PeerId::random();
let candidates = vec![peer1.into(), peer2.into()];
let config = ProtoSetConfig {
in_peers: 0,
out_peers: 2,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_outgoing_candidates().once().return_const(candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer2 }));
assert_eq!(controller.num_out, 2);
assert_eq!(controller.num_in, 0);
controller.alloc_slots();
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.num_out, 2);
assert_eq!(controller.num_in, 0);
}
#[test]
fn both_reserved_nodes_and_nodes_supplied_by_peer_store_are_connected() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let regular1 = PeerId::random();
let regular2 = PeerId::random();
let outgoing_candidates = vec![regular1.into(), regular2.into()];
let reserved_nodes = [reserved1, reserved2].iter().cloned().collect();
let config =
ProtoSetConfig { in_peers: 10, out_peers: 10, reserved_nodes, reserved_only: false };
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(2).return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(outgoing_candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 4);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved2 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: regular1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: regular2 }));
assert_eq!(controller.num_out, 2);
assert_eq!(controller.num_in, 0);
}
#[test]
fn if_slots_are_freed_we_try_to_allocate_them_again() {
let peer1 = PeerId::random();
let peer2 = PeerId::random();
let peer3 = PeerId::random();
let candidates1 = vec![peer1.into(), peer2.into()];
let candidates2 = vec![peer3.into()];
let config = ProtoSetConfig {
in_peers: 0,
out_peers: 2,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_outgoing_candidates().once().return_const(candidates1);
peer_store.expect_outgoing_candidates().once().return_const(candidates2);
peer_store.expect_report_disconnect().times(2).return_const(());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer2 }));
assert_eq!(controller.num_out, 2);
assert_eq!(controller.num_in, 0);
controller.alloc_slots();
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.num_out, 2);
assert_eq!(controller.num_in, 0);
controller.on_peer_dropped(peer1);
controller.on_peer_dropped(peer2);
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 1);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer3 }));
assert_eq!(controller.num_out, 1);
assert_eq!(controller.num_in, 0);
}
#[test]
fn in_reserved_only_mode_no_peers_are_requested_from_peer_store_and_connected() {
let config = ProtoSetConfig {
in_peers: 0,
out_peers: 2,
reserved_nodes: HashSet::new(),
reserved_only: true,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
}
#[test]
fn in_reserved_only_mode_no_regular_peers_are_accepted() {
let config = ProtoSetConfig {
in_peers: 2,
out_peers: 0,
reserved_nodes: HashSet::new(),
reserved_only: true,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
let peer = PeerId::random();
let incoming_index = IncomingIndex(1);
controller.on_incoming_connection(peer, incoming_index);
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 1);
assert!(messages.contains(&Message::Reject(incoming_index)));
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
}
#[test]
fn disabling_reserved_only_mode_allows_to_connect_to_peers() {
let peer1 = PeerId::random();
let peer2 = PeerId::random();
let candidates = vec![peer1.into(), peer2.into()];
let config = ProtoSetConfig {
in_peers: 0,
out_peers: 10,
reserved_nodes: HashSet::new(),
reserved_only: true,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_outgoing_candidates().once().return_const(candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
controller.on_set_reserved_only(false);
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer2 }));
assert_eq!(controller.num_out, 2);
assert_eq!(controller.num_in, 0);
}
#[test]
fn enabling_reserved_only_mode_disconnects_regular_peers() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let regular1 = PeerId::random();
let regular2 = PeerId::random();
let outgoing_candidates = vec![regular1.into()];
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: [reserved1, reserved2].iter().cloned().collect(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(3).return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(outgoing_candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 3);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved2 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: regular1 }));
assert_eq!(controller.num_out, 1);
assert_eq!(controller.num_in, 0);
let incoming_index = IncomingIndex(1);
controller.on_incoming_connection(regular2, incoming_index);
assert_eq!(rx.try_recv().unwrap(), Message::Accept(incoming_index));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.num_out, 1);
assert_eq!(controller.num_in, 1);
controller.on_set_reserved_only(true);
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Drop { set_id: SetId::from(0), peer_id: regular1 }));
assert!(messages.contains(&Message::Drop { set_id: SetId::from(0), peer_id: regular2 }));
assert_eq!(controller.nodes.len(), 0);
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
}
#[test]
fn removed_disconnected_reserved_node_is_forgotten() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: [reserved1, reserved2].iter().cloned().collect(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
assert_eq!(controller.reserved_nodes.len(), 2);
assert_eq!(controller.nodes.len(), 0);
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
controller.on_remove_reserved_peer(reserved1);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.reserved_nodes.len(), 1);
assert!(!controller.reserved_nodes.contains_key(&reserved1));
assert_eq!(controller.nodes.len(), 0);
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
}
#[test]
fn removed_connected_reserved_node_is_disconnected_in_reserved_only_mode() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: [reserved1, reserved2].iter().cloned().collect(),
reserved_only: true,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(2).return_const(false);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved1 }));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved2 }));
assert_eq!(controller.reserved_nodes.len(), 2);
assert!(controller.reserved_nodes.contains_key(&reserved1));
assert!(controller.reserved_nodes.contains_key(&reserved2));
assert!(controller.nodes.is_empty());
controller.on_remove_reserved_peer(reserved1);
assert_eq!(
rx.try_recv().unwrap(),
Message::Drop { set_id: SetId::from(0), peer_id: reserved1 }
);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.reserved_nodes.len(), 1);
assert!(controller.reserved_nodes.contains_key(&reserved2));
assert!(controller.nodes.is_empty());
}
#[test]
fn removed_connected_reserved_nodes_become_regular_in_non_reserved_mode() {
let peer1 = PeerId::random();
let peer2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: [peer1, peer2].iter().cloned().collect(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(2).return_const(false);
peer_store
.expect_outgoing_candidates()
.once()
.return_const(Vec::<sc_network_types::PeerId>::new());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.on_incoming_connection(peer1, IncomingIndex(1));
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Accept(IncomingIndex(1))));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer2 }));
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
controller.on_remove_reserved_peer(peer1);
controller.on_remove_reserved_peer(peer2);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.nodes.len(), 2);
assert!(matches!(controller.nodes.get(&peer1), Some(Direction::Inbound)));
assert!(matches!(controller.nodes.get(&peer2), Some(Direction::Outbound)));
assert_eq!(controller.num_out, 1);
assert_eq!(controller.num_in, 1);
}
#[test]
fn regular_nodes_stop_occupying_slots_when_become_reserved() {
let peer1 = PeerId::random();
let peer2 = PeerId::random();
let outgoing_candidates = vec![peer1.into()];
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(outgoing_candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
controller.on_incoming_connection(peer2, IncomingIndex(1));
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer1 }));
assert!(messages.contains(&Message::Accept(IncomingIndex(1))));
assert_eq!(controller.num_in, 1);
assert_eq!(controller.num_out, 1);
controller.on_add_reserved_peer(peer1);
controller.on_add_reserved_peer(peer2);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.num_in, 0);
assert_eq!(controller.num_out, 0);
}
#[test]
fn disconnecting_regular_peers_work() {
let peer1 = PeerId::random();
let peer2 = PeerId::random();
let outgoing_candidates = vec![peer1.into()];
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(outgoing_candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
controller.on_incoming_connection(peer2, IncomingIndex(1));
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer1 }));
assert!(messages.contains(&Message::Accept(IncomingIndex(1))));
assert_eq!(controller.nodes.len(), 2);
assert!(matches!(controller.nodes.get(&peer1), Some(Direction::Outbound)));
assert!(matches!(controller.nodes.get(&peer2), Some(Direction::Inbound)));
assert_eq!(controller.num_in, 1);
assert_eq!(controller.num_out, 1);
controller.on_disconnect_peer(peer1);
assert_eq!(
rx.try_recv().unwrap(),
Message::Drop { set_id: SetId::from(0), peer_id: peer1 }
);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.nodes.len(), 1);
assert!(!controller.nodes.contains_key(&peer1));
assert_eq!(controller.num_in, 1);
assert_eq!(controller.num_out, 0);
controller.on_disconnect_peer(peer2);
assert_eq!(
rx.try_recv().unwrap(),
Message::Drop { set_id: SetId::from(0), peer_id: peer2 }
);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.nodes.len(), 0);
assert_eq!(controller.num_in, 0);
assert_eq!(controller.num_out, 0);
}
#[test]
fn disconnecting_reserved_peers_is_a_noop() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: [reserved1, reserved2].iter().cloned().collect(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(2).return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(Vec::new());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.on_incoming_connection(reserved1, IncomingIndex(1));
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Accept(IncomingIndex(1))));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved2 }));
assert!(matches!(
controller.reserved_nodes.get(&reserved1),
Some(PeerState::Connected(Direction::Inbound))
));
assert!(matches!(
controller.reserved_nodes.get(&reserved2),
Some(PeerState::Connected(Direction::Outbound))
));
controller.on_disconnect_peer(reserved1);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(
controller.reserved_nodes.get(&reserved1),
Some(PeerState::Connected(Direction::Inbound))
));
controller.on_disconnect_peer(reserved2);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(
controller.reserved_nodes.get(&reserved2),
Some(PeerState::Connected(Direction::Outbound))
));
}
#[test]
fn dropping_regular_peers_work() {
let peer1 = PeerId::random();
let peer2 = PeerId::random();
let outgoing_candidates = vec![peer1.into()];
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(outgoing_candidates);
peer_store.expect_report_disconnect().times(2).return_const(());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.alloc_slots();
controller.on_incoming_connection(peer2, IncomingIndex(1));
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: peer1 }));
assert!(messages.contains(&Message::Accept(IncomingIndex(1))));
assert_eq!(controller.nodes.len(), 2);
assert!(matches!(controller.nodes.get(&peer1), Some(Direction::Outbound)));
assert!(matches!(controller.nodes.get(&peer2), Some(Direction::Inbound)));
assert_eq!(controller.num_in, 1);
assert_eq!(controller.num_out, 1);
controller.on_peer_dropped(peer1);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.nodes.len(), 1);
assert!(!controller.nodes.contains_key(&peer1));
assert_eq!(controller.num_in, 1);
assert_eq!(controller.num_out, 0);
controller.on_peer_dropped(peer2);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert_eq!(controller.nodes.len(), 0);
assert_eq!(controller.num_in, 0);
assert_eq!(controller.num_out, 0);
}
#[test]
fn incoming_request_for_connected_reserved_node_switches_it_to_inbound() {
let reserved1 = PeerId::random();
let reserved2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: [reserved1, reserved2].iter().cloned().collect(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(2).return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(Vec::new());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.on_incoming_connection(reserved1, IncomingIndex(1));
controller.alloc_slots();
let mut messages = Vec::new();
while let Some(message) = rx.try_recv().ok() {
messages.push(message);
}
assert_eq!(messages.len(), 2);
assert!(messages.contains(&Message::Accept(IncomingIndex(1))));
assert!(messages.contains(&Message::Connect { set_id: SetId::from(0), peer_id: reserved2 }));
assert!(matches!(
controller.reserved_nodes.get(&reserved1),
Some(PeerState::Connected(Direction::Inbound))
));
assert!(matches!(
controller.reserved_nodes.get(&reserved2),
Some(PeerState::Connected(Direction::Outbound))
));
controller.on_incoming_connection(reserved1, IncomingIndex(2));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Accept(IncomingIndex(2)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(
controller.reserved_nodes.get(&reserved1),
Some(PeerState::Connected(Direction::Inbound))
));
controller.on_incoming_connection(reserved2, IncomingIndex(3));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Accept(IncomingIndex(3)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(
controller.reserved_nodes.get(&reserved2),
Some(PeerState::Connected(Direction::Inbound))
));
}
#[test]
fn incoming_request_for_connected_regular_node_switches_it_to_inbound() {
let regular1 = PeerId::random();
let regular2 = PeerId::random();
let outgoing_candidates = vec![regular1.into()];
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().times(3).return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(outgoing_candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
controller.alloc_slots();
assert_eq!(
rx.try_recv().ok().unwrap(),
Message::Connect { set_id: SetId::from(0), peer_id: regular1 }
);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(controller.nodes.get(®ular1).unwrap(), Direction::Outbound,));
controller.on_incoming_connection(regular2, IncomingIndex(0));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Accept(IncomingIndex(0)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(controller.nodes.get(®ular2).unwrap(), Direction::Inbound,));
controller.on_incoming_connection(regular1, IncomingIndex(1));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Accept(IncomingIndex(1)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(controller.nodes.get(®ular1).unwrap(), Direction::Inbound,));
controller.on_incoming_connection(regular2, IncomingIndex(2));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Accept(IncomingIndex(2)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(controller.nodes.get(®ular2).unwrap(), Direction::Inbound,));
}
#[test]
fn incoming_request_for_connected_node_is_rejected_if_its_banned() {
let regular1 = PeerId::random();
let regular2 = PeerId::random();
let outgoing_candidates = vec![regular1.into()];
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(false);
peer_store.expect_is_banned().times(2).return_const(true);
peer_store.expect_outgoing_candidates().once().return_const(outgoing_candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
controller.alloc_slots();
assert_eq!(
rx.try_recv().ok().unwrap(),
Message::Connect { set_id: SetId::from(0), peer_id: regular1 }
);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(controller.nodes.get(®ular1).unwrap(), Direction::Outbound,));
controller.on_incoming_connection(regular2, IncomingIndex(0));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Accept(IncomingIndex(0)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(controller.nodes.get(®ular2).unwrap(), Direction::Inbound,));
controller.on_incoming_connection(regular1, IncomingIndex(1));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Reject(IncomingIndex(1)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(!controller.nodes.contains_key(®ular1));
controller.on_incoming_connection(regular2, IncomingIndex(2));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Reject(IncomingIndex(2)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(!controller.nodes.contains_key(®ular2));
}
#[test]
fn incoming_request_for_connected_node_is_rejected_if_no_slots_available() {
let regular1 = PeerId::random();
let regular2 = PeerId::random();
let outgoing_candidates = vec![regular1.into()];
let config = ProtoSetConfig {
in_peers: 1,
out_peers: 1,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(false);
peer_store.expect_outgoing_candidates().once().return_const(outgoing_candidates);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
assert_eq!(controller.num_out, 0);
assert_eq!(controller.num_in, 0);
controller.alloc_slots();
assert_eq!(
rx.try_recv().ok().unwrap(),
Message::Connect { set_id: SetId::from(0), peer_id: regular1 }
);
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(controller.nodes.get(®ular1).unwrap(), Direction::Outbound,));
controller.on_incoming_connection(regular2, IncomingIndex(0));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Accept(IncomingIndex(0)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(matches!(controller.nodes.get(®ular2).unwrap(), Direction::Inbound,));
controller.max_in = 0;
controller.on_incoming_connection(regular1, IncomingIndex(1));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Reject(IncomingIndex(1)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(!controller.nodes.contains_key(®ular1));
controller.on_incoming_connection(regular2, IncomingIndex(2));
assert_eq!(rx.try_recv().ok().unwrap(), Message::Reject(IncomingIndex(2)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
assert!(!controller.nodes.contains_key(®ular2));
}
#[test]
fn incoming_peers_that_exceed_slots_are_rejected() {
let peer1 = PeerId::random();
let peer2 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 1,
out_peers: 10,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(false);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.on_incoming_connection(peer1, IncomingIndex(1));
assert_eq!(rx.try_recv().unwrap(), Message::Accept(IncomingIndex(1)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
controller.on_incoming_connection(peer2, IncomingIndex(2));
assert_eq!(rx.try_recv().unwrap(), Message::Reject(IncomingIndex(2)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
}
#[test]
fn banned_regular_incoming_node_is_rejected() {
let peer1 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: HashSet::new(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(true);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
controller.on_incoming_connection(peer1, IncomingIndex(1));
assert_eq!(rx.try_recv().unwrap(), Message::Reject(IncomingIndex(1)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
}
#[test]
fn banned_reserved_incoming_node_is_rejected() {
let reserved1 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: std::iter::once(reserved1).collect(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(true);
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
assert!(controller.reserved_nodes.contains_key(&reserved1));
controller.on_incoming_connection(reserved1, IncomingIndex(1));
assert_eq!(rx.try_recv().unwrap(), Message::Reject(IncomingIndex(1)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
}
#[test]
fn we_dont_connect_to_banned_reserved_node() {
let reserved1 = PeerId::random();
let config = ProtoSetConfig {
in_peers: 10,
out_peers: 10,
reserved_nodes: std::iter::once(reserved1).collect(),
reserved_only: false,
};
let (tx, mut rx) = tracing_unbounded("mpsc_test_to_notifications", 100);
let mut peer_store = MockPeerStoreHandle::new();
peer_store.expect_register_protocol().once().return_const(());
peer_store.expect_is_banned().once().return_const(true);
peer_store.expect_outgoing_candidates().once().return_const(Vec::new());
let (_handle, mut controller) =
ProtocolController::new(SetId::from(0), config, tx, Arc::new(peer_store));
assert!(matches!(controller.reserved_nodes.get(&reserved1), Some(PeerState::NotConnected)));
controller.alloc_slots();
assert!(matches!(controller.reserved_nodes.get(&reserved1), Some(PeerState::NotConnected)));
assert_eq!(rx.try_recv().unwrap_err(), TryRecvError::Empty);
}
}