//! The `retransmit_stage` retransmits shreds between validators use crate::{ cluster_info::{compute_retransmit_peers, ClusterInfo, DATA_PLANE_FANOUT}, cluster_info_vote_listener::VerifiedVoteReceiver, cluster_slots::ClusterSlots, cluster_slots_service::ClusterSlotsService, completed_data_sets_service::CompletedDataSetsSender, contact_info::ContactInfo, repair_service::DuplicateSlotsResetSender, repair_service::RepairInfo, result::{Error, Result}, window_service::{should_retransmit_and_persist, WindowService}, }; use crossbeam_channel::Receiver; use solana_ledger::{ blockstore::{Blockstore, CompletedSlotsReceiver}, leader_schedule_cache::LeaderScheduleCache, staking_utils, }; use solana_measure::measure::Measure; use solana_metrics::inc_new_counter_error; use solana_perf::packet::Packets; use solana_runtime::bank_forks::BankForks; use solana_sdk::clock::{Epoch, Slot}; use solana_sdk::epoch_schedule::EpochSchedule; use solana_sdk::pubkey::Pubkey; use solana_sdk::timing::timestamp; use solana_streamer::streamer::PacketReceiver; use std::{ cmp, collections::hash_set::HashSet, collections::{BTreeMap, HashMap}, net::UdpSocket, sync::atomic::{AtomicBool, AtomicU64, Ordering}, sync::mpsc::channel, sync::mpsc::RecvTimeoutError, sync::Mutex, sync::{Arc, RwLock}, thread::{self, Builder, JoinHandle}, time::Duration, }; // Limit a given thread to consume about this many packets so that // it doesn't pull up too much work. const MAX_PACKET_BATCH_SIZE: usize = 100; #[derive(Default)] struct RetransmitStats { total_packets: AtomicU64, total_batches: AtomicU64, total_time: AtomicU64, epoch_fetch: AtomicU64, epoch_cache_update: AtomicU64, repair_total: AtomicU64, discard_total: AtomicU64, retransmit_total: AtomicU64, last_ts: AtomicU64, compute_turbine_peers_total: AtomicU64, packets_by_slot: Mutex>, packets_by_source: Mutex>, } #[allow(clippy::too_many_arguments)] fn update_retransmit_stats( stats: &Arc, total_time: u64, total_packets: usize, retransmit_total: u64, discard_total: u64, repair_total: u64, compute_turbine_peers_total: u64, peers_len: usize, packets_by_slot: HashMap, packets_by_source: HashMap, epoch_fetch: u64, epoch_cach_update: u64, ) { stats.total_time.fetch_add(total_time, Ordering::Relaxed); stats .total_packets .fetch_add(total_packets as u64, Ordering::Relaxed); stats .retransmit_total .fetch_add(retransmit_total, Ordering::Relaxed); stats .repair_total .fetch_add(repair_total, Ordering::Relaxed); stats .discard_total .fetch_add(discard_total, Ordering::Relaxed); stats .compute_turbine_peers_total .fetch_add(compute_turbine_peers_total, Ordering::Relaxed); stats.total_batches.fetch_add(1, Ordering::Relaxed); stats.epoch_fetch.fetch_add(epoch_fetch, Ordering::Relaxed); stats .epoch_cache_update .fetch_add(epoch_cach_update, Ordering::Relaxed); { let mut stats_packets_by_slot = stats.packets_by_slot.lock().unwrap(); for (slot, count) in packets_by_slot { *stats_packets_by_slot.entry(slot).or_insert(0) += count; } } { let mut stats_packets_by_source = stats.packets_by_source.lock().unwrap(); for (source, count) in packets_by_source { *stats_packets_by_source.entry(source).or_insert(0) += count; } } let now = timestamp(); let last = stats.last_ts.load(Ordering::Relaxed); if now - last > 2000 && stats.last_ts.compare_and_swap(last, now, Ordering::Relaxed) == last { datapoint_info!("retransmit-num_nodes", ("count", peers_len, i64)); datapoint_info!( "retransmit-stage", ( "total_time", stats.total_time.swap(0, Ordering::Relaxed) as i64, i64 ), ( "epoch_fetch", stats.epoch_fetch.swap(0, Ordering::Relaxed) as i64, i64 ), ( "epoch_cache_update", stats.epoch_cache_update.swap(0, Ordering::Relaxed) as i64, i64 ), ( "total_batches", stats.total_batches.swap(0, Ordering::Relaxed) as i64, i64 ), ( "total_packets", stats.total_packets.swap(0, Ordering::Relaxed) as i64, i64 ), ( "retransmit_total", stats.retransmit_total.swap(0, Ordering::Relaxed) as i64, i64 ), ( "compute_turbine", stats.compute_turbine_peers_total.swap(0, Ordering::Relaxed) as i64, i64 ), ( "repair_total", stats.repair_total.swap(0, Ordering::Relaxed) as i64, i64 ), ( "discard_total", stats.discard_total.swap(0, Ordering::Relaxed) as i64, i64 ), ); let mut packets_by_slot = stats.packets_by_slot.lock().unwrap(); info!("retransmit: packets_by_slot: {:?}", packets_by_slot); packets_by_slot.clear(); drop(packets_by_slot); let mut packets_by_source = stats.packets_by_source.lock().unwrap(); info!("retransmit: packets_by_source: {:?}", packets_by_source); packets_by_source.clear(); } } #[derive(Default)] struct EpochStakesCache { epoch: Epoch, stakes: Option>>, peers: Vec, stakes_and_index: Vec<(u64, usize)>, } fn retransmit( bank_forks: &Arc>, leader_schedule_cache: &Arc, cluster_info: &ClusterInfo, r: &Arc>, sock: &UdpSocket, id: u32, stats: &Arc, epoch_stakes_cache: &Arc>, last_peer_update: &Arc, ) -> Result<()> { let timer = Duration::new(1, 0); let r_lock = r.lock().unwrap(); let packets = r_lock.recv_timeout(timer)?; let mut timer_start = Measure::start("retransmit"); let mut total_packets = packets.packets.len(); let mut packet_v = vec![packets]; while let Ok(nq) = r_lock.try_recv() { total_packets += nq.packets.len(); packet_v.push(nq); if total_packets >= MAX_PACKET_BATCH_SIZE { break; } } drop(r_lock); let mut epoch_fetch = Measure::start("retransmit_epoch_fetch"); let r_bank = bank_forks.read().unwrap().working_bank(); let bank_epoch = r_bank.get_leader_schedule_epoch(r_bank.slot()); epoch_fetch.stop(); let mut epoch_cache_update = Measure::start("retransmit_epoch_cach_update"); let mut r_epoch_stakes_cache = epoch_stakes_cache.read().unwrap(); if r_epoch_stakes_cache.epoch != bank_epoch { drop(r_epoch_stakes_cache); let mut w_epoch_stakes_cache = epoch_stakes_cache.write().unwrap(); if w_epoch_stakes_cache.epoch != bank_epoch { let stakes = staking_utils::staked_nodes_at_epoch(&r_bank, bank_epoch); let stakes = stakes.map(Arc::new); w_epoch_stakes_cache.stakes = stakes; w_epoch_stakes_cache.epoch = bank_epoch; } drop(w_epoch_stakes_cache); r_epoch_stakes_cache = epoch_stakes_cache.read().unwrap(); } let now = timestamp(); let last = last_peer_update.load(Ordering::Relaxed); if now - last > 1000 && last_peer_update.compare_and_swap(last, now, Ordering::Relaxed) == last { drop(r_epoch_stakes_cache); let mut w_epoch_stakes_cache = epoch_stakes_cache.write().unwrap(); let (peers, stakes_and_index) = cluster_info.sorted_retransmit_peers_and_stakes(w_epoch_stakes_cache.stakes.clone()); w_epoch_stakes_cache.peers = peers; w_epoch_stakes_cache.stakes_and_index = stakes_and_index; drop(w_epoch_stakes_cache); r_epoch_stakes_cache = epoch_stakes_cache.read().unwrap(); } let mut peers_len = 0; epoch_cache_update.stop(); let my_id = cluster_info.id(); let mut discard_total = 0; let mut repair_total = 0; let mut retransmit_total = 0; let mut compute_turbine_peers_total = 0; let mut packets_by_slot: HashMap = HashMap::new(); let mut packets_by_source: HashMap = HashMap::new(); for mut packets in packet_v { for packet in packets.packets.iter_mut() { // skip discarded packets and repair packets if packet.meta.discard { total_packets -= 1; discard_total += 1; continue; } if packet.meta.repair { total_packets -= 1; repair_total += 1; continue; } let mut compute_turbine_peers = Measure::start("turbine_start"); let (my_index, mut shuffled_stakes_and_index) = ClusterInfo::shuffle_peers_and_index( &my_id, &r_epoch_stakes_cache.peers, &r_epoch_stakes_cache.stakes_and_index, packet.meta.seed, ); peers_len = cmp::max(peers_len, shuffled_stakes_and_index.len()); shuffled_stakes_and_index.remove(my_index); // split off the indexes, we don't need the stakes anymore let indexes = shuffled_stakes_and_index .into_iter() .map(|(_, index)| index) .collect(); let (neighbors, children) = compute_retransmit_peers(DATA_PLANE_FANOUT, my_index, indexes); let neighbors: Vec<_> = neighbors .into_iter() .map(|index| &r_epoch_stakes_cache.peers[index]) .collect(); let children: Vec<_> = children .into_iter() .map(|index| &r_epoch_stakes_cache.peers[index]) .collect(); compute_turbine_peers.stop(); compute_turbine_peers_total += compute_turbine_peers.as_us(); *packets_by_slot.entry(packet.meta.slot).or_insert(0) += 1; *packets_by_source .entry(packet.meta.addr().to_string()) .or_insert(0) += 1; let leader = leader_schedule_cache.slot_leader_at(packet.meta.slot, Some(r_bank.as_ref())); let mut retransmit_time = Measure::start("retransmit_to"); if !packet.meta.forward { ClusterInfo::retransmit_to(&neighbors, packet, leader, sock, true)?; ClusterInfo::retransmit_to(&children, packet, leader, sock, false)?; } else { ClusterInfo::retransmit_to(&children, packet, leader, sock, true)?; } retransmit_time.stop(); retransmit_total += retransmit_time.as_us(); } } timer_start.stop(); debug!( "retransmitted {} packets in {}ms retransmit_time: {}ms id: {}", total_packets, timer_start.as_ms(), retransmit_total, id, ); update_retransmit_stats( stats, timer_start.as_us(), total_packets, retransmit_total, discard_total, repair_total, compute_turbine_peers_total, peers_len, packets_by_slot, packets_by_source, epoch_fetch.as_us(), epoch_cache_update.as_us(), ); Ok(()) } /// Service to retransmit messages from the leader or layer 1 to relevant peer nodes. /// See `cluster_info` for network layer definitions. /// # Arguments /// * `sockets` - Sockets to read from. /// * `bank_forks` - The BankForks structure /// * `leader_schedule_cache` - The leader schedule to verify shreds /// * `cluster_info` - This structure needs to be updated and populated by the bank and via gossip. /// * `r` - Receive channel for shreds to be retransmitted to all the layer 1 nodes. pub fn retransmitter( sockets: Arc>, bank_forks: Arc>, leader_schedule_cache: &Arc, cluster_info: Arc, r: Arc>, ) -> Vec> { let stats = Arc::new(RetransmitStats::default()); (0..sockets.len()) .map(|s| { let sockets = sockets.clone(); let bank_forks = bank_forks.clone(); let leader_schedule_cache = leader_schedule_cache.clone(); let r = r.clone(); let cluster_info = cluster_info.clone(); let stats = stats.clone(); let epoch_stakes_cache = Arc::new(RwLock::new(EpochStakesCache::default())); let last_peer_update = Arc::new(AtomicU64::new(0)); Builder::new() .name("solana-retransmitter".to_string()) .spawn(move || { trace!("retransmitter started"); loop { if let Err(e) = retransmit( &bank_forks, &leader_schedule_cache, &cluster_info, &r, &sockets[s], s as u32, &stats, &epoch_stakes_cache, &last_peer_update, ) { match e { Error::RecvTimeoutError(RecvTimeoutError::Disconnected) => break, Error::RecvTimeoutError(RecvTimeoutError::Timeout) => (), _ => { inc_new_counter_error!("streamer-retransmit-error", 1, 1); } } } } trace!("exiting retransmitter"); }) .unwrap() }) .collect() } pub struct RetransmitStage { thread_hdls: Vec>, window_service: WindowService, cluster_slots_service: ClusterSlotsService, } impl RetransmitStage { #[allow(clippy::new_ret_no_self)] #[allow(clippy::too_many_arguments)] pub fn new( bank_forks: Arc>, leader_schedule_cache: &Arc, blockstore: Arc, cluster_info: &Arc, retransmit_sockets: Arc>, repair_socket: Arc, verified_receiver: Receiver>, exit: &Arc, completed_slots_receiver: CompletedSlotsReceiver, epoch_schedule: EpochSchedule, cfg: Option>, shred_version: u16, cluster_slots: Arc, duplicate_slots_reset_sender: DuplicateSlotsResetSender, verified_vote_receiver: VerifiedVoteReceiver, repair_validators: Option>, completed_data_sets_sender: CompletedDataSetsSender, ) -> Self { let (retransmit_sender, retransmit_receiver) = channel(); let retransmit_receiver = Arc::new(Mutex::new(retransmit_receiver)); let t_retransmit = retransmitter( retransmit_sockets, bank_forks.clone(), leader_schedule_cache, cluster_info.clone(), retransmit_receiver, ); let leader_schedule_cache_clone = leader_schedule_cache.clone(); let cluster_slots_service = ClusterSlotsService::new( blockstore.clone(), cluster_slots.clone(), bank_forks.clone(), cluster_info.clone(), completed_slots_receiver, exit.clone(), ); let repair_info = RepairInfo { bank_forks, epoch_schedule, duplicate_slots_reset_sender, repair_validators, }; let window_service = WindowService::new( blockstore, cluster_info.clone(), verified_receiver, retransmit_sender, repair_socket, exit, repair_info, leader_schedule_cache, move |id, shred, working_bank, last_root| { let is_connected = cfg .as_ref() .map(|x| x.load(Ordering::Relaxed)) .unwrap_or(true); let rv = should_retransmit_and_persist( shred, working_bank, &leader_schedule_cache_clone, id, last_root, shred_version, ); rv && is_connected }, cluster_slots, verified_vote_receiver, completed_data_sets_sender, ); let thread_hdls = t_retransmit; Self { thread_hdls, window_service, cluster_slots_service, } } pub fn join(self) -> thread::Result<()> { for thread_hdl in self.thread_hdls { thread_hdl.join()?; } self.window_service.join()?; self.cluster_slots_service.join()?; Ok(()) } } #[cfg(test)] mod tests { use super::*; use crate::contact_info::ContactInfo; use solana_ledger::blockstore_processor::{process_blockstore, ProcessOptions}; use solana_ledger::create_new_tmp_ledger; use solana_ledger::genesis_utils::{create_genesis_config, GenesisConfigInfo}; use solana_net_utils::find_available_port_in_range; use solana_perf::packet::{Meta, Packet, Packets}; use solana_sdk::pubkey::Pubkey; use std::net::{IpAddr, Ipv4Addr}; #[test] fn test_skip_repair() { let GenesisConfigInfo { genesis_config, .. } = create_genesis_config(123); let (ledger_path, _blockhash) = create_new_tmp_ledger!(&genesis_config); let blockstore = Blockstore::open(&ledger_path).unwrap(); let opts = ProcessOptions { full_leader_cache: true, ..ProcessOptions::default() }; let (bank_forks, cached_leader_schedule) = process_blockstore(&genesis_config, &blockstore, Vec::new(), opts).unwrap(); let leader_schedule_cache = Arc::new(cached_leader_schedule); let bank_forks = Arc::new(RwLock::new(bank_forks)); let mut me = ContactInfo::new_localhost(&Pubkey::new_rand(), 0); let ip_addr = IpAddr::V4(Ipv4Addr::new(0, 0, 0, 0)); let port = find_available_port_in_range(ip_addr, (8000, 10000)).unwrap(); let me_retransmit = UdpSocket::bind(format!("127.0.0.1:{}", port)).unwrap(); // need to make sure tvu and tpu are valid addresses me.tvu_forwards = me_retransmit.local_addr().unwrap(); let port = find_available_port_in_range(ip_addr, (8000, 10000)).unwrap(); me.tvu = UdpSocket::bind(format!("127.0.0.1:{}", port)) .unwrap() .local_addr() .unwrap(); let other = ContactInfo::new_localhost(&Pubkey::new_rand(), 0); let cluster_info = ClusterInfo::new_with_invalid_keypair(other); cluster_info.insert_info(me); let retransmit_socket = Arc::new(vec![UdpSocket::bind("0.0.0.0:0").unwrap()]); let cluster_info = Arc::new(cluster_info); let (retransmit_sender, retransmit_receiver) = channel(); let t_retransmit = retransmitter( retransmit_socket, bank_forks, &leader_schedule_cache, cluster_info, Arc::new(Mutex::new(retransmit_receiver)), ); let _thread_hdls = vec![t_retransmit]; let packets = Packets::new(vec![Packet::default()]); // it should send this over the sockets. retransmit_sender.send(packets).unwrap(); let mut packets = Packets::new(vec![]); solana_streamer::packet::recv_from(&mut packets, &me_retransmit, 1).unwrap(); assert_eq!(packets.packets.len(), 1); assert_eq!(packets.packets[0].meta.repair, false); let repair = Packet { meta: Meta { repair: true, ..Meta::default() }, ..Packet::default() }; // send 1 repair and 1 "regular" packet so that we don't block forever on the recv_from let packets = Packets::new(vec![repair, Packet::default()]); retransmit_sender.send(packets).unwrap(); let mut packets = Packets::new(vec![]); solana_streamer::packet::recv_from(&mut packets, &me_retransmit, 1).unwrap(); assert_eq!(packets.packets.len(), 1); assert_eq!(packets.packets[0].meta.repair, false); } }