use crate::commands::{Command, FileInfo, LocalCommand, RemoteInfo}; use futures_util::StreamExt; use std::{collections::HashMap, path::PathBuf, sync::Arc}; use tokio::{ fs, join, runtime::Runtime, sync::{mpsc, Mutex, RwLock}, }; use tokio_stream::wrappers::UnboundedReceiverStream; use tracing::*; use veloren_network::{ListenAddr, Network, Participant, Pid, Promises, Stream}; #[derive(Debug)] struct ControlChannels { command_receiver: mpsc::UnboundedReceiver, } struct Shared { served: RwLock>, remotes: RwLock>>>, receiving_files: Mutex>>, } pub struct Server { run_channels: ControlChannels, server: Network, client: Network, shared: Shared, } impl Server { pub fn new(runtime: Arc) -> (Self, mpsc::UnboundedSender) { let (command_sender, command_receiver) = mpsc::unbounded_channel(); let server = Network::new(Pid::new(), &runtime); let client = Network::new(Pid::new(), &runtime); let run_channels = ControlChannels { command_receiver }; ( Server { run_channels, server, client, shared: Shared { served: RwLock::new(vec![]), remotes: RwLock::new(HashMap::new()), receiving_files: Mutex::new(HashMap::new()), }, }, command_sender, ) } pub async fn run(self, address: ListenAddr) { let run_channels = self.run_channels; self.server.listen(address).await.unwrap(); join!( self.shared .command_manager(self.client, run_channels.command_receiver), self.shared.connect_manager(self.server), ); } } impl Shared { async fn command_manager( &self, client: Network, command_receiver: mpsc::UnboundedReceiver, ) { trace!("Start command_manager"); let command_receiver = UnboundedReceiverStream::new(command_receiver); command_receiver .for_each_concurrent(None, |cmd| async { match cmd { LocalCommand::Shutdown => println!("Shutting down service"), LocalCommand::Disconnect => { self.remotes.write().await.clear(); println!("Disconnecting all connections"); }, LocalCommand::Connect(addr) => { println!("Trying to connect to: {:?}", &addr); match client.connect(addr.clone()).await { Ok(p) => self.loop_participant(p).await, Err(e) => println!("Failed to connect to {:?}, err: {:?}", &addr, e), } }, LocalCommand::Serve(fileinfo) => { self.served.write().await.push(fileinfo.clone()); println!("Serving file: {:?}", fileinfo.path); }, LocalCommand::List => { let mut total_file_infos = vec![]; for ri in self.remotes.read().await.values() { let mut ri = ri.lock().await; ri.cmd_out.send(Command::List).unwrap(); let mut file_infos = ri.cmd_out.recv::>().await.unwrap(); ri.insert_infos(file_infos.clone()); total_file_infos.append(&mut file_infos); } print_fileinfos(&total_file_infos); }, LocalCommand::Get(id, path) => { // i dont know the owner, just broadcast, i am laaaazyyy for ri in self.remotes.read().await.values() { let ri = ri.lock().await; if ri.get_info(id).is_some() { //found provider, send request. self.receiving_files.lock().await.insert(id, path.clone()); ri.cmd_out.send(Command::Get(id)).unwrap(); // the answer is handled via the other stream! break; } } }, } }) .await; trace!("Stop command_manager"); } async fn connect_manager(&self, network: Network) { trace!("Start connect_manager"); let iter = futures_util::stream::unfold(network, async move |mut network| { network.connected().await.ok().map(|v| (v, network)) }); iter.for_each_concurrent(/* limit */ None, |participant| async { self.loop_participant(participant).await; }) .await; trace!("Stop connect_manager"); } async fn loop_participant(&self, mut p: Participant) { if let (Ok(cmd_out), Ok(file_out), Ok(cmd_in), Ok(file_in)) = ( p.open(3, Promises::ORDERED | Promises::CONSISTENCY, 0) .await, p.open(6, Promises::CONSISTENCY, 0).await, p.opened().await, p.opened().await, ) { debug!(?p, "Connection successfully initiated"); let id = p.remote_pid(); let ri = Arc::new(Mutex::new(RemoteInfo::new(cmd_out, file_out, p))); self.remotes.write().await.insert(id, ri.clone()); join!( self.handle_remote_cmd(cmd_in, ri.clone()), self.handle_files(file_in, ri.clone()), ); } } async fn handle_remote_cmd(&self, mut stream: Stream, remote_info: Arc>) { while let Ok(msg) = stream.recv::().await { println!("Got message: {:?}", &msg); match msg { Command::List => { info!("Request to send my list"); let served = self.served.read().await.clone(); stream.send(served).unwrap(); }, Command::Get(id) => { for file_info in self.served.read().await.iter() { if file_info.id() == id { info!("Request to send file i got, sending it"); if let Ok(data) = file_info.load().await { match remote_info.lock().await.file_out.send((file_info, data)) { Ok(_) => debug!("send file"), Err(e) => error!(?e, "sending file failed"), } } else { warn!("Cannot send file as loading failed, oes it still exist?"); } } } }, } } } async fn handle_files(&self, mut stream: Stream, _remote_info: Arc>) { while let Ok((fi, data)) = stream.recv::<(FileInfo, Vec)>().await { debug!(?fi, "Got file"); let path = self.receiving_files.lock().await.remove(&fi.id()).flatten(); let path: PathBuf = match &path { Some(path) => shellexpand::tilde(&path).parse().unwrap(), None => { let mut path = std::env::current_dir().unwrap(); path.push(fi.path().file_name().unwrap()); trace!("No path provided, saving down to {:?}", path); path }, }; debug!("Received file, going to save it under {:?}", path); fs::write(path, data).await.unwrap(); } } } fn print_fileinfos(infos: &[FileInfo]) { let mut i = 0; for info in infos { let bytes = info.size; match bytes { 0..100_000 => println!("{}: {}bytes '{}'", info.id(), bytes, info.path), 100_000..100_000_000 => { println!("{}: {}bytes '{}'", info.id(), bytes / 1024, info.path) }, _ => println!( "{}: {}bytes '{}'", info.id(), bytes / 1024 / 1024, info.path ), } i += 1; } println!("-- {} files available", i); }