use std::sync::Arc; use std::collections::HashMap; use std::time::Duration; use std::net::{IpAddr, SocketAddr}; use futures::future::join_all; use hyper::client::Client; use tokio::sync::RwLock; use sha2::{Sha256, Digest}; use crate::Config; use crate::error::Error; use crate::data::*; use crate::proto::*; use crate::rpc::*; const PING_INTERVAL: Duration = Duration::from_secs(10); const PING_TIMEOUT: Duration = Duration::from_secs(2); const MAX_FAILED_PINGS: usize = 3; pub struct System { pub config: Config, pub id: UUID, pub rpc_client: Client, pub members: RwLock, } pub struct Members { pub status: HashMap, pub status_hash: Hash, pub config: NetworkConfig, } impl Members { fn handle_ping(&mut self, ip: IpAddr, info: &PingMessage) -> bool { let addr = SocketAddr::new(ip, info.rpc_port); let old_status = self.status.insert(info.id.clone(), NodeStatus{ addr: addr.clone(), remaining_ping_attempts: MAX_FAILED_PINGS, datacenter: info.datacenter.clone(), }); match old_status { None => { eprintln!("Newly pingable node: {}", hex::encode(info.id)); true } Some(x) => x.addr != addr, } } fn recalculate_status_hash(&mut self) { let mut nodes = self.status.iter().collect::>(); nodes.sort_by_key(|(id, _status)| *id); let mut hasher = Sha256::new(); eprintln!("Current set of pingable nodes: --"); for (id, status) in nodes { eprintln!("{} {} ({})", hex::encode(id), status.addr, status.datacenter); hasher.input(format!("{} {}\n", hex::encode(id), status.addr)); } eprintln!("END --"); self.status_hash.copy_from_slice(&hasher.result()[..]); } } pub struct NodeStatus { pub addr: SocketAddr, pub datacenter: String, pub remaining_ping_attempts: usize, } impl System { pub fn new(config: Config, id: UUID) -> Self { let mut members = Members{ status: HashMap::new(), status_hash: [0u8; 32], config: NetworkConfig{ members: HashMap::new(), version: 0, }, }; members.recalculate_status_hash(); System{ config, id, rpc_client: Client::new(), members: RwLock::new(members), } } pub async fn make_ping(&self) -> Message { let members = self.members.read().await; Message::Ping(PingMessage{ id: self.id, datacenter: self.config.datacenter.clone(), rpc_port: self.config.rpc_port, status_hash: members.status_hash.clone(), config_version: members.config.version, }) } pub async fn broadcast(self: Arc, msg: Message, timeout: Duration) { let members = self.members.read().await; let to = members.status.keys().filter(|x| **x != self.id).cloned().collect::>(); drop(members); rpc_call_many(self.clone(), &to[..], &msg, None, timeout).await; } pub async fn bootstrap(self: Arc) { let bootstrap_peers = self.config.bootstrap_peers .iter() .map(|ip| (ip.clone(), None)) .collect::>(); self.clone().ping_nodes(bootstrap_peers).await; tokio::spawn(self.ping_loop()); } pub async fn ping_nodes(self: Arc, peers: Vec<(SocketAddr, Option)>) { let ping_msg = self.make_ping().await; let ping_resps = join_all( peers.iter() .map(|(addr, id_option)| { let sys = self.clone(); let ping_msg_ref = &ping_msg; async move { (id_option, addr.clone(), rpc_call_addr(sys, &addr, ping_msg_ref, PING_TIMEOUT).await) } })).await; let mut members = self.members.write().await; let mut has_changes = false; let mut to_advertise = vec![]; for (id_option, addr, ping_resp) in ping_resps { if let Ok(Message::Ping(info)) = ping_resp { let is_new = members.handle_ping(addr.ip(), &info); if is_new { has_changes = true; to_advertise.push(AdvertisedNode{ id: info.id.clone(), addr: addr.clone(), }); } if is_new || members.status_hash != info.status_hash { tokio::spawn(self.clone().pull_status(info.id.clone())); } if is_new || members.config.version < info.config_version { tokio::spawn(self.clone().pull_config(info.id.clone())); } } else if let Some(id) = id_option { let remaining_attempts = members.status.get(id).map(|x| x.remaining_ping_attempts).unwrap_or(0); if remaining_attempts == 0 { eprintln!("Removing node {} after too many failed pings", hex::encode(id)); members.status.remove(id); has_changes = true; } else { if let Some(st) = members.status.get_mut(id) { st.remaining_ping_attempts = remaining_attempts - 1; } } } } if has_changes { members.recalculate_status_hash(); } drop(members); if to_advertise.len() > 0 { self.broadcast(Message::AdvertiseNodesUp(to_advertise), PING_TIMEOUT).await; } } pub async fn handle_ping(self: Arc, from: &SocketAddr, ping: &PingMessage) -> Result { let mut members = self.members.write().await; let is_new = members.handle_ping(from.ip(), ping); if is_new { members.recalculate_status_hash(); } let status_hash = members.status_hash.clone(); let config_version = members.config.version; drop(members); if is_new || status_hash != ping.status_hash { tokio::spawn(self.clone().pull_status(ping.id.clone())); } if is_new || config_version < ping.config_version { tokio::spawn(self.clone().pull_config(ping.id.clone())); } Ok(self.make_ping().await) } pub async fn handle_pull_status(&self) -> Result { let members = self.members.read().await; let mut mem = vec![]; for (node, status) in members.status.iter() { mem.push(AdvertisedNode{ id: node.clone(), addr: status.addr.clone(), }); } Ok(Message::AdvertiseNodesUp(mem)) } pub async fn handle_pull_config(&self) -> Result { let members = self.members.read().await; Ok(Message::AdvertiseConfig(members.config.clone())) } pub async fn handle_advertise_nodes_up(self: Arc, adv: &[AdvertisedNode]) -> Result { let mut to_ping = vec![]; let mut members = self.members.write().await; let mut has_changed = false; for node in adv.iter() { if node.id == self.id { // learn our own ip address let self_addr = SocketAddr::new(node.addr.ip(), self.config.rpc_port); let old_self = members.status.insert(node.id.clone(), NodeStatus{ addr: self_addr, datacenter: self.config.datacenter.clone(), remaining_ping_attempts: MAX_FAILED_PINGS, }); has_changed = match old_self { None => true, Some(x) => x.addr != self_addr, }; } else if !members.status.contains_key(&node.id) { to_ping.push((node.addr.clone(), Some(node.id.clone()))); } } if has_changed { members.recalculate_status_hash(); } drop(members); if to_ping.len() > 0 { tokio::spawn(self.clone().ping_nodes(to_ping)); } Ok(Message::Ok) } pub async fn handle_advertise_config(self: Arc, adv: &NetworkConfig) -> Result { let mut members = self.members.write().await; if adv.version > members.config.version { members.config = adv.clone(); tokio::spawn(self.clone().broadcast(Message::AdvertiseConfig(adv.clone()), PING_TIMEOUT)); } Ok(Message::Ok) } pub async fn ping_loop(self: Arc) { loop { let restart_at = tokio::time::delay_for(PING_INTERVAL); let members = self.members.read().await; let ping_addrs = members.status.iter() .filter(|(id, _)| **id != self.id) .map(|(id, status)| (status.addr.clone(), Some(id.clone()))) .collect::>(); drop(members); self.clone().ping_nodes(ping_addrs).await; restart_at.await } } pub fn pull_status(self: Arc, peer: UUID) -> impl futures::future::Future + Send + 'static { async move { let resp = rpc_call(self.clone(), &peer, &Message::PullStatus, PING_TIMEOUT).await; if let Ok(Message::AdvertiseNodesUp(nodes)) = resp { let _: Result<_, _> = self.handle_advertise_nodes_up(&nodes).await; } } } pub async fn pull_config(self: Arc, peer: UUID) { let resp = rpc_call(self.clone(), &peer, &Message::PullConfig, PING_TIMEOUT).await; if let Ok(Message::AdvertiseConfig(config)) = resp { let _: Result<_, _> = self.handle_advertise_config(&config).await; } } }