pub use crate::{ConnectionState, PeerSignalPath, PeerTransport};
use anyhow::Result;
use async_trait::async_trait;
use cashu_service::CashuPaymentClient;
#[cfg(test)]
use nostr_sdk::nostr::Kind;
use nostr_sdk::nostr::{Event, Keys};
use std::collections::{BTreeSet, HashMap};
use std::sync::Arc;
use std::time::{Duration, Instant};
use tokio::sync::{mpsc, Mutex, RwLock};
use tracing::{debug, error, info, warn};
use crate::bluetooth::{
BluetoothConfig, BluetoothMesh, BluetoothPeerRegistrar, BluetoothRuntimeContext,
};
use crate::cashu::{CashuMintMetadataStore, CashuQuoteState, CashuRoutingConfig, NegotiatedQuote};
use crate::local_bus::SharedLocalNostrBus;
use crate::mesh_session::{
resolve_root_from_peer_sessions as resolve_root_via_peer_sessions, MeshSession,
};
use crate::mesh_store_core::{
run_hedged_waves, sync_selector_peers, HedgedWaveAction, RequestDispatchConfig,
};
use crate::multicast::{MulticastConfig, MulticastNostrBus};
use crate::nostr::NostrRelayTransport;
use crate::peer::{ContentStore, Peer, PendingRequest};
use crate::peer_selector::{PeerMetadataSnapshot, PeerSelector, SelectorSummary};
use crate::protocol::{DataQuoteRequest, DataRequest};
use crate::relay_bridge::SharedMeshRelayClient;
use crate::root_events::PeerRootEvent;
use crate::runtime_control::{can_track_source_peer, PeerStateEvent};
use crate::runtime_peer::{
MeshPeerEntry as SharedPeerEntry, PeerClassifier as SharedPeerClassifier,
};
use crate::runtime_state::MeshRuntimeState;
use crate::session::MeshPeer;
use crate::signaling::MeshRouter;
use crate::transport::{
PeerLink as SharedPeerLink, PeerLinkFactory as SharedPeerLinkFactory,
SignalingTransport as SharedSignalingTransport, TransportError as SharedTransportError,
};
use crate::types::{
validate_mesh_frame, KnownPeerRecord, KnownPeerSnapshot, MeshNostrFrame, MeshNostrPayload,
SignalingMessage, TimedSeenSet,
};
use crate::wifi_aware::{
mobile_wifi_aware_bridge, WifiAwareConfig, WifiAwareNostrBus, WIFI_AWARE_SOURCE,
};
use crate::{
ClassifyRequest as SharedClassifyRequest, IceCandidate as SharedIceCandidate, PeerDirection,
PeerId, PeerPool, MESH_SIGNALING_EVENT_KIND,
};
pub type PeerClassifier = SharedPeerClassifier;
pub type PeerEntry = SharedPeerEntry<MeshPeer>;
#[derive(Clone)]
pub struct WebRTCConfig {
pub relays: Vec<String>,
pub signaling_enabled: bool,
pub hash_get_enabled: bool,
pub signal_urls: Vec<String>,
pub max_outbound: usize,
pub max_inbound: usize,
pub hello_interval_ms: u64,
pub message_timeout_ms: u64,
pub stun_servers: Vec<String>,
pub debug: bool,
pub multicast: MulticastConfig,
pub wifi_aware: WifiAwareConfig,
pub bluetooth: BluetoothConfig,
pub pools: crate::PoolSettings,
pub request_selection_strategy: crate::SelectionStrategy,
pub request_fairness_enabled: bool,
pub request_dispatch: RequestDispatchConfig,
}
impl Default for WebRTCConfig {
fn default() -> Self {
Self {
relays: vec![
"wss://relay.damus.io".to_string(),
"wss://relay.primal.net".to_string(),
"wss://temp.iris.to".to_string(),
"wss://relay.snort.social".to_string(),
],
signaling_enabled: true,
hash_get_enabled: true,
signal_urls: Vec::new(),
max_outbound: 6,
max_inbound: 6,
hello_interval_ms: 3000,
message_timeout_ms: 15000,
stun_servers: vec![
"stun:stun.iris.to:3478".to_string(),
"stun:stun.l.google.com:19302".to_string(),
"stun:stun.cloudflare.com:3478".to_string(),
],
debug: false,
multicast: MulticastConfig::default(),
wifi_aware: WifiAwareConfig::default(),
bluetooth: BluetoothConfig::default(),
pools: crate::PoolSettings::default(),
request_selection_strategy: crate::SelectionStrategy::Weighted,
request_fairness_enabled: true,
request_dispatch: RequestDispatchConfig {
initial_fanout: 2,
hedge_fanout: 1,
max_fanout: 8,
hedge_interval_ms: 120,
},
}
}
}
#[derive(Debug, Clone)]
pub struct PeerStatus {
pub peer_id: String,
pub pubkey: String,
pub state: String,
pub direction: PeerDirection,
pub connected_at: Option<std::time::Instant>,
pub pool: PeerPool,
}
fn bluetooth_nostr_only_mode() -> bool {
matches!(
std::env::var("HTREE_BLUETOOTH_NOSTR_ONLY").ok().as_deref(),
Some("1" | "true" | "TRUE" | "yes" | "YES")
)
}
pub struct WebRTCState {
pub runtime: MeshRuntimeState<MeshPeer>,
peer_selector: Arc<RwLock<PeerSelector>>,
direct_signaling_tx: RwLock<Option<mpsc::Sender<(String, Event)>>>,
request_dispatch: RequestDispatchConfig,
request_timeout: Duration,
cashu_quotes: Arc<CashuQuoteState>,
}
const SEEN_FRAME_CAP: usize = 4096;
const SEEN_FRAME_TTL: Duration = Duration::from_secs(120);
const SEEN_EVENT_CAP: usize = 8192;
const SEEN_EVENT_TTL: Duration = Duration::from_secs(600);
type PendingRequestsMap = Arc<Mutex<HashMap<String, PendingRequest>>>;
type ConnectedPeer = (
String,
PendingRequestsMap,
Arc<webrtc::data_channel::RTCDataChannel>,
);
type ConnectedSession = (String, MeshPeer, PeerTransport);
type SharedProductionRouter = MeshRouter<RouterSignalingBridge, SharedRouterPeerFactory>;
#[derive(Clone)]
struct RouterSignalingBridge {
peer_id: String,
signaling_tx: mpsc::Sender<SignalingMessage>,
}
impl RouterSignalingBridge {
fn new(peer_id: String, signaling_tx: mpsc::Sender<SignalingMessage>) -> Self {
Self {
peer_id,
signaling_tx,
}
}
}
#[async_trait]
impl SharedSignalingTransport for RouterSignalingBridge {
async fn connect(&self, _relays: &[String]) -> Result<(), SharedTransportError> {
Ok(())
}
async fn disconnect(&self) {}
async fn publish(&self, msg: SignalingMessage) -> Result<(), SharedTransportError> {
self.signaling_tx
.send(msg)
.await
.map_err(|e| SharedTransportError::SendFailed(e.to_string()))
}
async fn recv(&self) -> Option<SignalingMessage> {
None
}
fn try_recv(&self) -> Option<SignalingMessage> {
None
}
fn peer_id(&self) -> &str {
&self.peer_id
}
}
struct SharedRouterPeerFactory {
my_peer_id: PeerId,
signaling_tx: mpsc::Sender<SignalingMessage>,
stun_servers: Vec<String>,
store: Option<Arc<dyn ContentStore>>,
state: Arc<WebRTCState>,
state_event_tx: mpsc::Sender<PeerStateEvent>,
nostr_relay: Option<SharedMeshRelayClient>,
mesh_frame_tx: mpsc::Sender<(PeerId, MeshNostrFrame)>,
signal_urls: Vec<String>,
peer_classifier: PeerClassifier,
peers: RwLock<HashMap<String, Arc<Peer>>>,
}
impl SharedRouterPeerFactory {
#[allow(clippy::too_many_arguments)]
fn new(
my_peer_id: PeerId,
signaling_tx: mpsc::Sender<SignalingMessage>,
stun_servers: Vec<String>,
store: Option<Arc<dyn ContentStore>>,
state: Arc<WebRTCState>,
state_event_tx: mpsc::Sender<PeerStateEvent>,
nostr_relay: Option<SharedMeshRelayClient>,
mesh_frame_tx: mpsc::Sender<(PeerId, MeshNostrFrame)>,
signal_urls: Vec<String>,
peer_classifier: PeerClassifier,
) -> Self {
Self {
my_peer_id,
signaling_tx,
stun_servers,
store,
state,
state_event_tx,
nostr_relay,
mesh_frame_tx,
signal_urls,
peer_classifier,
peers: RwLock::new(HashMap::new()),
}
}
async fn register_peer(&self, peer_id: PeerId, direction: PeerDirection, peer: Arc<Peer>) {
let peer_key = peer_id.to_string();
let pool = (self.peer_classifier)(&peer_id.pubkey);
self.peers
.write()
.await
.insert(peer_key.clone(), peer.clone());
let mut peers = self.state.runtime.peers.write().await;
peers.insert(
peer_key,
PeerEntry {
peer_id,
direction,
state: ConnectionState::Connecting,
last_seen: Instant::now(),
peer: Some(MeshPeer::WebRtc(peer)),
pool,
transport: PeerTransport::WebRtc,
signal_paths: BTreeSet::from([PeerSignalPath::Relay]),
bytes_sent: 0,
bytes_received: 0,
},
);
}
async fn create_peer(
&self,
peer_id: PeerId,
direction: PeerDirection,
) -> Result<Peer, SharedTransportError> {
let mut peer = Peer::new_with_store_and_events(
peer_id,
direction,
self.my_peer_id.clone(),
self.signaling_tx.clone(),
self.stun_servers.clone(),
self.store.clone(),
Some(self.state_event_tx.clone()),
self.nostr_relay.clone(),
Some(self.mesh_frame_tx.clone()),
Some(self.state.cashu_quotes.clone()),
)
.await
.map_err(|e| SharedTransportError::ConnectionFailed(e.to_string()))?;
peer.set_signal_urls(self.signal_urls.clone());
Ok(peer)
}
}
#[async_trait]
impl SharedPeerLinkFactory for SharedRouterPeerFactory {
async fn create_offer(
&self,
target_peer_id: &str,
) -> Result<(Arc<dyn SharedPeerLink>, String), SharedTransportError> {
let target_peer = PeerId::from_string(target_peer_id).ok_or_else(|| {
SharedTransportError::ConnectionFailed(format!("invalid peer id {target_peer_id}"))
})?;
let peer = Arc::new(
self.create_peer(target_peer.clone(), PeerDirection::Outbound)
.await?,
);
peer.setup_handlers()
.await
.map_err(|e| SharedTransportError::ConnectionFailed(e.to_string()))?;
let offer = peer
.connect()
.await
.map_err(|e| SharedTransportError::ConnectionFailed(e.to_string()))?;
let sdp = offer
.get("sdp")
.and_then(|value| value.as_str())
.ok_or_else(|| {
SharedTransportError::ConnectionFailed("missing SDP in CLI peer offer".to_string())
})?
.to_string();
self.register_peer(target_peer, PeerDirection::Outbound, peer.clone())
.await;
Ok((peer as Arc<dyn SharedPeerLink>, sdp))
}
async fn accept_offer(
&self,
from_peer_id: &str,
offer_sdp: &str,
) -> Result<(Arc<dyn SharedPeerLink>, String), SharedTransportError> {
let from_peer = PeerId::from_string(from_peer_id).ok_or_else(|| {
SharedTransportError::ConnectionFailed(format!("invalid peer id {from_peer_id}"))
})?;
let peer = Arc::new(
self.create_peer(from_peer.clone(), PeerDirection::Inbound)
.await?,
);
peer.setup_handlers()
.await
.map_err(|e| SharedTransportError::ConnectionFailed(e.to_string()))?;
let answer = peer
.handle_offer(serde_json::json!({ "type": "offer", "sdp": offer_sdp }))
.await
.map_err(|e| SharedTransportError::ConnectionFailed(e.to_string()))?;
let sdp = answer
.get("sdp")
.and_then(|value| value.as_str())
.ok_or_else(|| {
SharedTransportError::ConnectionFailed("missing SDP in CLI peer answer".to_string())
})?
.to_string();
self.register_peer(from_peer, PeerDirection::Inbound, peer.clone())
.await;
Ok((peer as Arc<dyn SharedPeerLink>, sdp))
}
async fn handle_answer(
&self,
target_peer_id: &str,
answer_sdp: &str,
) -> Result<Arc<dyn SharedPeerLink>, SharedTransportError> {
let peer = self
.peers
.read()
.await
.get(target_peer_id)
.cloned()
.ok_or_else(|| {
SharedTransportError::ConnectionFailed(format!(
"missing outbound peer for {target_peer_id}"
))
})?;
peer.handle_answer(serde_json::json!({ "type": "answer", "sdp": answer_sdp }))
.await
.map_err(|e| SharedTransportError::ConnectionFailed(e.to_string()))?;
Ok(peer as Arc<dyn SharedPeerLink>)
}
async fn handle_candidate(
&self,
peer_id: &str,
candidate: SharedIceCandidate,
) -> Result<(), SharedTransportError> {
let peer = self.peers.read().await.get(peer_id).cloned();
if let Some(peer) = peer {
peer.handle_candidate(serde_json::json!({
"candidate": candidate.candidate,
"sdpMLineIndex": candidate.sdp_m_line_index,
"sdpMid": candidate.sdp_mid,
}))
.await
.map_err(|e| SharedTransportError::ConnectionFailed(e.to_string()))?;
}
Ok(())
}
async fn remove_peer(&self, peer_id: &str) -> Result<(), SharedTransportError> {
self.peers.write().await.remove(peer_id);
Ok(())
}
}
impl WebRTCState {
pub fn new() -> Self {
let cfg = WebRTCConfig::default();
Self::new_with_routing_and_cashu(
cfg.request_selection_strategy,
cfg.request_fairness_enabled,
cfg.request_dispatch,
Duration::from_millis(cfg.message_timeout_ms),
CashuRoutingConfig::default(),
None,
None,
)
}
pub fn new_with_routing(
selection_strategy: crate::SelectionStrategy,
fairness_enabled: bool,
request_dispatch: RequestDispatchConfig,
) -> Self {
let cfg = WebRTCConfig::default();
Self::new_with_routing_and_cashu(
selection_strategy,
fairness_enabled,
request_dispatch,
Duration::from_millis(cfg.message_timeout_ms),
CashuRoutingConfig::default(),
None,
None,
)
}
pub fn new_with_routing_and_cashu(
selection_strategy: crate::SelectionStrategy,
fairness_enabled: bool,
request_dispatch: RequestDispatchConfig,
request_timeout: Duration,
cashu_routing: CashuRoutingConfig,
payment_client: Option<Arc<dyn CashuPaymentClient>>,
mint_metadata: Option<Arc<CashuMintMetadataStore>>,
) -> Self {
let mut selector = PeerSelector::with_strategy(selection_strategy);
selector.set_fairness(fairness_enabled);
let peer_selector = Arc::new(RwLock::new(selector));
let cashu_quotes = Arc::new(if let Some(mint_metadata) = mint_metadata {
CashuQuoteState::new_with_mint_metadata(
cashu_routing,
peer_selector.clone(),
payment_client,
mint_metadata,
)
} else {
CashuQuoteState::new(cashu_routing, peer_selector.clone(), payment_client)
});
Self {
runtime: MeshRuntimeState::new(),
peer_selector,
direct_signaling_tx: RwLock::new(None),
request_dispatch,
request_timeout,
cashu_quotes,
}
}
pub async fn set_local_buses(&self, buses: Vec<SharedLocalNostrBus>) {
self.runtime.set_local_buses(buses).await;
}
pub async fn add_local_bus(&self, bus: SharedLocalNostrBus) {
self.runtime.add_local_bus(bus).await;
}
pub async fn set_multicast_bus(&self, bus: Option<Arc<MulticastNostrBus>>) {
let buses = bus
.into_iter()
.map(|bus| bus as SharedLocalNostrBus)
.collect();
self.set_local_buses(buses).await;
}
pub async fn reset_runtime_state(&self) {
self.runtime.reset().await;
}
pub async fn peer_metadata_snapshot(&self) -> PeerMetadataSnapshot {
self.peer_selector
.read()
.await
.export_peer_metadata_snapshot()
}
pub async fn import_peer_metadata_snapshot(&self, snapshot: &PeerMetadataSnapshot) {
self.peer_selector
.write()
.await
.import_peer_metadata_snapshot(snapshot);
}
pub async fn selector_summary(&self) -> SelectorSummary {
self.peer_selector.read().await.summary()
}
pub async fn known_peer_snapshot(&self) -> KnownPeerSnapshot {
self.runtime.known_peer_snapshot().await
}
pub async fn import_known_peer_snapshot(&self, snapshot: &KnownPeerSnapshot) {
self.runtime.import_known_peer_snapshot(snapshot).await;
}
pub async fn ordered_known_peers(&self) -> Vec<KnownPeerRecord> {
let snapshot = self.runtime.known_peer_snapshot().await;
let mut by_peer = snapshot
.peers
.into_iter()
.map(|peer| (peer.peer_id.clone(), peer))
.collect::<HashMap<_, _>>();
let ordered_ids = {
let mut selector = self.peer_selector.write().await;
for peer_id in by_peer.keys() {
selector.add_peer(peer_id);
}
selector.select_peers()
};
let mut ordered = Vec::new();
for peer_id in ordered_ids {
if let Some(peer) = by_peer.remove(&peer_id) {
ordered.push(peer);
}
}
let mut remaining = by_peer.into_values().collect::<Vec<_>>();
remaining.sort_by(|a, b| a.peer_id.cmp(&b.peer_id));
ordered.extend(remaining);
ordered
}
pub async fn set_direct_signaling_sender(&self, tx: Option<mpsc::Sender<(String, Event)>>) {
*self.direct_signaling_tx.write().await = tx;
}
pub async fn submit_direct_signaling_event(&self, source: String, event: Event) -> bool {
let tx = self.direct_signaling_tx.read().await.clone();
let Some(tx) = tx else {
return false;
};
tx.send((source, event)).await.is_ok()
}
pub fn get_bandwidth(&self) -> (u64, u64) {
self.runtime.get_bandwidth()
}
pub fn get_mesh_stats(&self) -> (u64, u64, u64) {
self.runtime.get_mesh_stats()
}
pub fn record_mesh_received(&self) {
self.runtime.record_mesh_received();
}
pub fn record_mesh_forwarded(&self, count: u64) {
self.runtime.record_mesh_forwarded(count);
}
pub fn record_mesh_duplicate_drop(&self) {
self.runtime.record_mesh_duplicate_drop();
}
pub async fn record_sent(&self, peer_id: &str, bytes: u64) {
self.runtime.record_sent(peer_id, bytes).await;
}
pub async fn record_received(&self, peer_id: &str, bytes: u64) {
self.runtime.record_received(peer_id, bytes).await;
}
pub async fn request_from_peers(&self, hash_hex: &str) -> Option<Vec<u8>> {
self.request_from_peers_with_source(hash_hex)
.await
.map(|(data, _peer_id)| data)
}
pub async fn request_from_peers_with_source(
&self,
hash_hex: &str,
) -> Option<(Vec<u8>, String)> {
use crate::BLOB_REQUEST_POLICY;
let peer_hash_get = self.runtime.peer_hash_get_snapshot().await;
let peers = self.runtime.peers.read().await;
let peer_refs: Vec<_> = peers
.values()
.filter(|p| p.state == ConnectionState::Connected && p.peer.is_some())
.filter_map(|p| {
if !peer_hash_get
.get(&p.peer_id.to_string())
.copied()
.unwrap_or(true)
{
return None;
}
p.peer
.clone()
.map(|peer| (p.peer_id.to_string(), peer, p.transport))
})
.collect();
drop(peers);
let mut connected_peers: Vec<ConnectedPeer> = Vec::new();
let mut connected_sessions: Vec<ConnectedSession> = Vec::new();
for (peer_id, peer, transport) in peer_refs {
if !peer.is_ready() {
continue;
}
if bluetooth_nostr_only_mode() && transport == PeerTransport::Bluetooth {
continue;
}
if let Some(webrtc_peer) = peer.as_webrtc() {
let dc_guard = webrtc_peer.data_channel.lock().await;
if let Some(dc) = dc_guard.as_ref() {
connected_peers.push((
peer_id.clone(),
webrtc_peer.pending_requests.clone(),
dc.clone(),
));
}
}
connected_sessions.push((peer_id, peer, transport));
}
if connected_sessions.is_empty() {
debug!(
"No connected peers to query for {}",
&hash_hex[..8.min(hash_hex.len())]
);
return None;
}
let hash_bytes = match hex::decode(hash_hex) {
Ok(b) => b,
Err(_) => return None,
};
let expected_hash: [u8; 32] = match hash_bytes.as_slice().try_into() {
Ok(h) => h,
Err(_) => {
debug!(
"Invalid hash length {}, expected 32 bytes",
hash_bytes.len()
);
return None;
}
};
let connected_peer_ids: Vec<String> = connected_sessions
.iter()
.map(|(peer_id, _, _)| peer_id.clone())
.collect();
sync_selector_peers(self.peer_selector.as_ref(), &connected_peer_ids).await;
let ordered_peer_ids = self.peer_selector.write().await.select_peers();
let mut quote_by_peer: HashMap<
String,
(
PendingRequestsMap,
Arc<webrtc::data_channel::RTCDataChannel>,
),
> = connected_peers
.iter()
.cloned()
.map(|(peer_id, pending, dc)| (peer_id, (pending, dc)))
.collect();
let mut ordered_quote_peers: Vec<ConnectedPeer> = Vec::new();
for peer_id in &ordered_peer_ids {
if let Some((pending, dc)) = quote_by_peer.remove(peer_id) {
ordered_quote_peers.push((peer_id.clone(), pending, dc));
}
}
for (peer_id, (pending, dc)) in quote_by_peer {
ordered_quote_peers.push((peer_id, pending, dc));
}
let mut by_peer: HashMap<String, (MeshPeer, PeerTransport)> = connected_sessions
.into_iter()
.map(|(peer_id, peer, transport)| (peer_id, (peer, transport)))
.collect();
let mut ordered_peers: Vec<ConnectedSession> = Vec::new();
for peer_id in ordered_peer_ids {
if let Some((peer, transport)) = by_peer.remove(&peer_id) {
ordered_peers.push((peer_id, peer, transport));
}
}
for (peer_id, (peer, transport)) in by_peer {
ordered_peers.push((peer_id, peer, transport));
}
debug!(
"Querying {} peers for {} with shared hedged scheduler",
ordered_peers.len(),
&hash_hex[..8.min(hash_hex.len())],
);
if let Some((requested_mint, payment_sat, quote_ttl_ms)) =
self.cashu_quotes.requester_quote_terms().await
{
if let Some(quote) = self
.request_quote_from_peers(
&hash_bytes,
requested_mint,
payment_sat,
quote_ttl_ms,
&ordered_quote_peers,
)
.await
{
if let Some(data) = self
.request_from_single_peer(
hash_hex,
&hash_bytes,
expected_hash,
"e.peer_id,
Some("e),
&ordered_quote_peers,
)
.await
{
debug!(
"Got quoted response from peer {} for {}",
quote.peer_id,
&hash_hex[..8.min(hash_hex.len())]
);
return Some((data, quote.peer_id));
}
}
}
let request = DataRequest {
h: hash_bytes.clone(),
htl: BLOB_REQUEST_POLICY.max_htl,
q: None,
};
let wire = crate::encode_request(&request);
let wire_len = wire.len() as u64;
let current_result_rx = Arc::new(Mutex::new(None));
if let Some((data, peer_id)) = run_hedged_waves(
ordered_peers.len(),
self.request_dispatch,
self.request_timeout,
|range| {
let wave_peers = ordered_peers[range].to_vec();
let (result_tx, result_rx) =
mpsc::channel::<(String, Instant, Result<Option<Vec<u8>>>)>(wave_peers.len());
let current_result_rx = current_result_rx.clone();
let hash_hex = hash_hex.to_string();
async move {
*current_result_rx.lock().await = Some(result_rx);
let sent = wave_peers.len();
for (peer_id, peer, transport) in wave_peers {
if transport != PeerTransport::Bluetooth {
self.record_sent(&peer_id, wire_len).await;
}
self.peer_selector
.write()
.await
.record_request(&peer_id, wire_len);
let result_tx = result_tx.clone();
let peer_id_for_task = peer_id.clone();
let peer = peer.clone();
let hash_hex = hash_hex.clone();
let per_request_timeout = self.request_timeout;
tokio::spawn(async move {
let started = Instant::now();
let result = peer.request(&hash_hex, per_request_timeout).await;
let _ = result_tx.send((peer_id_for_task, started, result)).await;
});
}
drop(result_tx);
sent
}
},
|wait| {
let current_result_rx = current_result_rx.clone();
async move {
let mut current_result_rx = current_result_rx.lock().await;
let Some(result_rx) = current_result_rx.as_mut() else {
return HedgedWaveAction::Abort;
};
let deadline = Instant::now() + wait;
loop {
let now = Instant::now();
if now >= deadline {
return HedgedWaveAction::Continue;
}
let remaining = deadline.saturating_duration_since(now);
match tokio::time::timeout(remaining, result_rx.recv()).await {
Ok(Some((peer_id, started, Ok(Some(data))))) => {
let rtt_ms = started.elapsed().as_millis() as u64;
if hashtree_core::sha256(&data) == expected_hash {
let should_record = {
let peers = self.runtime.peers.read().await;
peers
.get(&peer_id)
.map(|entry| {
entry.transport != PeerTransport::Bluetooth
})
.unwrap_or(true)
};
if should_record {
self.record_received(&peer_id, data.len() as u64).await;
}
self.peer_selector.write().await.record_success(
&peer_id,
rtt_ms,
data.len() as u64,
);
return HedgedWaveAction::Success((data, peer_id));
}
self.peer_selector.write().await.record_failure(&peer_id);
}
Ok(Some((peer_id, _, Ok(None)))) | Ok(Some((peer_id, _, Err(_)))) => {
self.peer_selector.write().await.record_timeout(&peer_id);
}
Ok(None) | Err(_) => return HedgedWaveAction::Continue,
}
}
}
},
)
.await
{
debug!(
"Got response from peer {} for {}",
peer_id,
&hash_hex[..8.min(hash_hex.len())]
);
return Some((data, peer_id));
}
debug!(
"No peer had data for {}",
&hash_hex[..8.min(hash_hex.len())]
);
None
}
async fn request_quote_from_peers(
&self,
hash_bytes: &[u8],
requested_mint: String,
payment_sat: u64,
quote_ttl_ms: u32,
ordered_peers: &[ConnectedPeer],
) -> Option<NegotiatedQuote> {
if ordered_peers.is_empty() || quote_ttl_ms == 0 {
return None;
}
let hash_hex = hex::encode(hash_bytes);
let rx = self
.cashu_quotes
.register_pending_quote(hash_hex.clone(), Some(requested_mint.clone()), payment_sat)
.await;
let quote_request = DataQuoteRequest {
h: hash_bytes.to_vec(),
p: payment_sat,
t: quote_ttl_ms,
m: Some(requested_mint),
};
let wire = crate::encode_quote_request("e_request);
let rx = Arc::new(Mutex::new(rx));
let result = run_hedged_waves(
ordered_peers.len(),
self.request_dispatch,
self.request_timeout,
|range| {
let wave_peers = ordered_peers[range].to_vec();
let wire = wire.clone();
async move {
let mut sent = 0usize;
for (_, _, dc) in wave_peers {
if dc.send(&bytes::Bytes::copy_from_slice(&wire)).await.is_ok() {
sent += 1;
}
}
sent
}
},
|wait| {
let rx = rx.clone();
async move {
let mut rx = rx.lock().await;
match tokio::time::timeout(wait, &mut *rx).await {
Ok(Ok(Some(quote))) => HedgedWaveAction::Success(quote),
Ok(Ok(None)) | Ok(Err(_)) => HedgedWaveAction::Abort,
Err(_) => HedgedWaveAction::Continue,
}
}
},
)
.await;
self.cashu_quotes.clear_pending_quote(&hash_hex).await;
result
}
async fn request_from_single_peer(
&self,
hash_hex: &str,
hash_bytes: &[u8],
expected_hash: [u8; 32],
target_peer_id: &str,
quote: Option<&NegotiatedQuote>,
ordered_peers: &[ConnectedPeer],
) -> Option<Vec<u8>> {
use crate::BLOB_REQUEST_POLICY;
let (pending_requests, dc) = ordered_peers
.iter()
.find(|(peer_id, _, _)| peer_id == target_peer_id)
.map(|(_, pending_requests, dc)| (pending_requests.clone(), dc.clone()))?;
let request = DataRequest {
h: hash_bytes.to_vec(),
htl: BLOB_REQUEST_POLICY.max_htl,
q: quote.map(|quote| quote.quote_id),
};
let wire = crate::encode_request(&request);
let wire_len = wire.len() as u64;
let sent_at = Instant::now();
let (tx, mut rx) = tokio::sync::oneshot::channel();
{
let mut pending = pending_requests.lock().await;
pending.insert(
hash_hex.to_string(),
if let Some(quote) = quote {
PendingRequest::quoted(
hash_bytes.to_vec(),
tx,
quote.quote_id,
quote.mint_url.clone().unwrap_or_default(),
quote.payment_sat,
)
} else {
PendingRequest::standard(hash_bytes.to_vec(), tx)
},
);
}
if dc
.send(&bytes::Bytes::copy_from_slice(&wire))
.await
.is_err()
{
let mut pending = pending_requests.lock().await;
pending.remove(hash_hex);
self.peer_selector
.write()
.await
.record_failure(target_peer_id);
return None;
}
self.record_sent(target_peer_id, wire_len).await;
self.peer_selector
.write()
.await
.record_request(target_peer_id, wire_len);
let wait_timeout = if let Some(quote) = quote {
let multiplier = quote.payment_sat.clamp(1, 32) as u128;
let extra_ms = self
.cashu_quotes
.settlement_timeout()
.as_millis()
.saturating_mul(multiplier);
self.request_timeout + Duration::from_millis(extra_ms.min(u64::MAX as u128) as u64)
} else {
self.request_timeout
};
match tokio::time::timeout(wait_timeout, &mut rx).await {
Ok(Ok(Some(data))) if hashtree_core::sha256(&data) == expected_hash => {
let rtt_ms = sent_at.elapsed().as_millis() as u64;
self.record_received(target_peer_id, data.len() as u64)
.await;
self.peer_selector.write().await.record_success(
target_peer_id,
rtt_ms,
data.len() as u64,
);
Some(data)
}
Ok(Ok(Some(_))) => {
self.peer_selector
.write()
.await
.record_failure(target_peer_id);
let pending = pending_requests.lock().await.remove(hash_hex);
if let Some(pending) = pending {
if let Some(quoted) = pending.quoted {
if let Some(in_flight) = quoted.in_flight_payment {
let _ = self
.cashu_quotes
.revoke_payment_token(&in_flight.mint_url, &in_flight.operation_id)
.await;
}
}
}
None
}
Ok(Ok(None)) | Ok(Err(_)) | Err(_) => {
let pending = pending_requests.lock().await.remove(hash_hex);
if let Some(pending) = pending {
if let Some(quoted) = pending.quoted {
if let Some(in_flight) = quoted.in_flight_payment {
let _ = self
.cashu_quotes
.revoke_payment_token(&in_flight.mint_url, &in_flight.operation_id)
.await;
}
}
}
self.peer_selector
.write()
.await
.record_timeout(target_peer_id);
None
}
}
}
pub async fn resolve_root_from_peers(
&self,
owner_pubkey: &str,
tree_name: &str,
per_peer_timeout: Duration,
) -> Option<PeerRootEvent> {
let peer_refs: Vec<(String, Arc<dyn MeshSession>)> = {
let peers = self.runtime.peers.read().await;
peers
.values()
.filter(|entry| entry.state == ConnectionState::Connected)
.filter(|entry| {
!bluetooth_nostr_only_mode() || entry.transport != PeerTransport::Bluetooth
})
.filter_map(|entry| {
let peer = entry.peer.as_ref()?;
Some((
entry.peer_id.short(),
Arc::new(peer.clone()) as Arc<dyn MeshSession>,
))
})
.collect()
};
let resolved =
resolve_root_via_peer_sessions(peer_refs, owner_pubkey, tree_name, per_peer_timeout)
.await;
if let Some(root) = &resolved {
debug!(
"Resolved {}/{} via peer {} event {}",
owner_pubkey, tree_name, root.peer_id, root.event_id
);
}
resolved
}
pub async fn resolve_root_from_local_buses_with_source(
&self,
owner_pubkey: &str,
tree_name: &str,
timeout: Duration,
) -> Option<(&'static str, PeerRootEvent)> {
self.runtime
.resolve_root_from_local_buses_with_source(owner_pubkey, tree_name, timeout)
.await
}
pub async fn resolve_root_from_local_buses(
&self,
owner_pubkey: &str,
tree_name: &str,
timeout: Duration,
) -> Option<PeerRootEvent> {
self.resolve_root_from_local_buses_with_source(owner_pubkey, tree_name, timeout)
.await
.map(|(_, root)| root)
}
pub async fn resolve_root_from_multicast(
&self,
owner_pubkey: &str,
tree_name: &str,
timeout: Duration,
) -> Option<PeerRootEvent> {
self.resolve_root_from_local_buses(owner_pubkey, tree_name, timeout)
.await
}
}
impl Default for WebRTCState {
fn default() -> Self {
Self::new()
}
}
pub struct WebRTCManager {
config: WebRTCConfig,
my_peer_id: PeerId,
keys: Keys,
state: Arc<WebRTCState>,
shutdown: Arc<tokio::sync::watch::Sender<bool>>,
shutdown_rx: tokio::sync::watch::Receiver<bool>,
signaling_tx: mpsc::Sender<SignalingMessage>,
signaling_rx: Option<mpsc::Receiver<SignalingMessage>>,
store: Option<Arc<dyn ContentStore>>,
peer_classifier: PeerClassifier,
nostr_relay: Option<SharedMeshRelayClient>,
local_buses: Vec<SharedLocalNostrBus>,
state_event_tx: mpsc::Sender<PeerStateEvent>,
state_event_rx: Option<mpsc::Receiver<PeerStateEvent>>,
mesh_frame_tx: mpsc::Sender<(PeerId, MeshNostrFrame)>,
mesh_frame_rx: Option<mpsc::Receiver<(PeerId, MeshNostrFrame)>>,
shared_router: Option<Arc<SharedProductionRouter>>,
seen_frame_ids: Arc<Mutex<TimedSeenSet>>,
seen_event_ids: Arc<Mutex<TimedSeenSet>>,
}
impl WebRTCManager {
pub fn new(keys: Keys, config: WebRTCConfig) -> Self {
let pubkey = keys.public_key().to_hex();
let my_peer_id = PeerId::new(pubkey);
let (shutdown, shutdown_rx) = tokio::sync::watch::channel(false);
let (signaling_tx, signaling_rx) = mpsc::channel(100);
let (state_event_tx, state_event_rx) = mpsc::channel(100);
let (mesh_frame_tx, mesh_frame_rx) = mpsc::channel(256);
let state = Arc::new(WebRTCState::new_with_routing_and_cashu(
config.request_selection_strategy,
config.request_fairness_enabled,
config.request_dispatch,
Duration::from_millis(config.message_timeout_ms),
CashuRoutingConfig::default(),
None,
None,
));
let peer_classifier: PeerClassifier = Arc::new(|_| PeerPool::Other);
Self {
config,
my_peer_id,
keys,
state,
shutdown: Arc::new(shutdown),
shutdown_rx,
signaling_tx,
signaling_rx: Some(signaling_rx),
store: None,
peer_classifier,
nostr_relay: None,
local_buses: Vec::new(),
state_event_tx,
state_event_rx: Some(state_event_rx),
mesh_frame_tx,
mesh_frame_rx: Some(mesh_frame_rx),
shared_router: None,
seen_frame_ids: Arc::new(Mutex::new(TimedSeenSet::new(
SEEN_FRAME_CAP,
SEEN_FRAME_TTL,
))),
seen_event_ids: Arc::new(Mutex::new(TimedSeenSet::new(
SEEN_EVENT_CAP,
SEEN_EVENT_TTL,
))),
}
}
pub fn new_with_state(keys: Keys, config: WebRTCConfig, state: Arc<WebRTCState>) -> Self {
let mut manager = Self::new(keys, config);
manager.state = state;
manager
}
pub fn new_with_classifier(
keys: Keys,
config: WebRTCConfig,
classifier: PeerClassifier,
) -> Self {
let mut manager = Self::new(keys, config);
manager.peer_classifier = classifier;
manager
}
pub fn new_with_store(keys: Keys, config: WebRTCConfig, store: Arc<dyn ContentStore>) -> Self {
let mut manager = Self::new(keys, config);
manager.store = Some(store);
manager
}
pub fn new_with_store_and_classifier(
keys: Keys,
config: WebRTCConfig,
store: Arc<dyn ContentStore>,
classifier: PeerClassifier,
) -> Self {
Self::new_with_store_and_classifier_and_cashu(
keys,
config,
store,
classifier,
CashuRoutingConfig::default(),
None,
None,
)
}
pub fn new_with_state_and_store_and_classifier(
keys: Keys,
config: WebRTCConfig,
state: Arc<WebRTCState>,
store: Arc<dyn ContentStore>,
classifier: PeerClassifier,
) -> Self {
let mut manager = Self::new_with_state(keys, config, state);
manager.store = Some(store);
manager.peer_classifier = classifier;
manager
}
pub fn new_with_store_and_classifier_and_cashu(
keys: Keys,
config: WebRTCConfig,
store: Arc<dyn ContentStore>,
classifier: PeerClassifier,
cashu_routing: CashuRoutingConfig,
payment_client: Option<Arc<dyn CashuPaymentClient>>,
mint_metadata: Option<Arc<CashuMintMetadataStore>>,
) -> Self {
let mut manager = Self::new(keys, config);
manager.state = Arc::new(WebRTCState::new_with_routing_and_cashu(
manager.config.request_selection_strategy,
manager.config.request_fairness_enabled,
manager.config.request_dispatch,
Duration::from_millis(manager.config.message_timeout_ms),
cashu_routing,
payment_client,
mint_metadata,
));
manager.store = Some(store);
manager.peer_classifier = classifier;
manager
}
pub fn set_store(&mut self, store: Arc<dyn ContentStore>) {
self.store = Some(store);
}
pub fn set_peer_classifier(&mut self, classifier: PeerClassifier) {
self.peer_classifier = classifier;
}
pub fn set_nostr_relay(&mut self, relay: SharedMeshRelayClient) {
self.nostr_relay = Some(relay);
}
pub fn my_peer_id(&self) -> &PeerId {
&self.my_peer_id
}
pub fn state(&self) -> Arc<WebRTCState> {
self.state.clone()
}
pub fn shutdown_signal(&self) -> Arc<tokio::sync::watch::Sender<bool>> {
self.shutdown.clone()
}
pub fn shutdown(&self) {
let _ = self.shutdown.send(true);
}
pub async fn connected_count(&self) -> usize {
self.state
.runtime
.connected_count
.load(std::sync::atomic::Ordering::Relaxed)
}
pub async fn peer_statuses(&self) -> Vec<PeerStatus> {
self.state
.runtime
.peers
.read()
.await
.values()
.map(|p| PeerStatus {
peer_id: p.peer_id.to_string(),
pubkey: p.peer_id.pubkey.clone(),
state: p.state.to_string(),
direction: p.direction,
connected_at: Some(p.last_seen),
pool: p.pool,
})
.collect()
}
pub async fn get_pool_counts(&self) -> (usize, usize, usize, usize) {
let peers = self.state.runtime.peers.read().await;
let mut follows_connected = 0;
let mut follows_active = 0;
let mut other_connected = 0;
let mut other_active = 0;
for entry in peers.values() {
let is_active = entry.state == ConnectionState::Connected
|| entry.state == ConnectionState::Connecting;
match entry.pool {
PeerPool::Follows => {
if is_active {
follows_active += 1;
}
if entry.state == ConnectionState::Connected {
follows_connected += 1;
}
}
PeerPool::Other => {
if is_active {
other_active += 1;
}
if entry.state == ConnectionState::Connected {
other_connected += 1;
}
}
}
}
(
follows_connected,
follows_active,
other_connected,
other_active,
)
}
fn local_bus_max_peers(&self, source: &str) -> Option<usize> {
match source {
"multicast" => Some(self.config.multicast.max_peers),
WIFI_AWARE_SOURCE => Some(self.config.wifi_aware.max_peers),
_ => None,
}
}
#[cfg_attr(not(test), allow(dead_code))]
fn can_track_local_bus_peer(
&self,
source: &str,
peer_key: &str,
peers: &HashMap<String, PeerEntry>,
) -> bool {
can_track_source_peer(source, peer_key, peers, self.local_bus_max_peers(source))
}
}
mod runtime;