use futures::future; use futures::sync::{mpsc, oneshot}; use futures::{Async, Future, Poll, Sink, Stream}; use protobuf::{self, Message}; use core::config::ConnectConfig; use core::mercury::MercuryError; use core::session::Session; use core::spotify_id::SpotifyId; use core::util::SeqGenerator; use core::version; use protocol; use protocol::spirc::{DeviceState, Frame, MessageType, PlayStatus, State}; use playback::mixer::Mixer; use playback::player::Player; use rand; use rand::Rng; use std; use std::time::{SystemTime, UNIX_EPOCH}; pub struct SpircTask { player: Player, mixer: Box, linear_volume: bool, sequence: SeqGenerator, ident: String, device: DeviceState, state: State, subscription: Box>, sender: Box>, commands: mpsc::UnboundedReceiver, end_of_track: Box>, shutdown: bool, session: Session, } pub enum SpircCommand { Play, PlayPause, Pause, Prev, Next, VolumeUp, VolumeDown, Shutdown, } pub struct Spirc { commands: mpsc::UnboundedSender, } fn now_ms() -> i64 { let dur = match SystemTime::now().duration_since(UNIX_EPOCH) { Ok(dur) => dur, Err(err) => err.duration(), }; (dur.as_secs() * 1000 + (dur.subsec_nanos() / 1000_000) as u64) as i64 } fn initial_state() -> State { let mut frame = protocol::spirc::State::new(); frame.set_repeat(false); frame.set_shuffle(false); frame.set_status(PlayStatus::kPlayStatusStop); frame.set_position_ms(0); frame.set_position_measured_at(0); frame } fn initial_device_state(config: ConnectConfig, volume: u16) -> DeviceState { { let mut msg = DeviceState::new(); msg.set_sw_version(version::version_string()); msg.set_is_active(false); msg.set_can_play(true); msg.set_volume(volume as u32); msg.set_name(config.name); { let repeated = msg.mut_capabilities(); { let msg = repeated.push_default(); msg.set_typ(protocol::spirc::CapabilityType::kCanBePlayer); { let repeated = msg.mut_intValue(); repeated.push(1) }; msg }; { let msg = repeated.push_default(); msg.set_typ(protocol::spirc::CapabilityType::kDeviceType); { let repeated = msg.mut_intValue(); repeated.push(config.device_type as i64) }; msg }; { let msg = repeated.push_default(); msg.set_typ(protocol::spirc::CapabilityType::kGaiaEqConnectId); { let repeated = msg.mut_intValue(); repeated.push(1) }; msg }; { let msg = repeated.push_default(); msg.set_typ(protocol::spirc::CapabilityType::kSupportsLogout); { let repeated = msg.mut_intValue(); repeated.push(0) }; msg }; { let msg = repeated.push_default(); msg.set_typ(protocol::spirc::CapabilityType::kIsObservable); { let repeated = msg.mut_intValue(); repeated.push(1) }; msg }; { let msg = repeated.push_default(); msg.set_typ(protocol::spirc::CapabilityType::kVolumeSteps); { let repeated = msg.mut_intValue(); repeated.push(64) }; msg }; { let msg = repeated.push_default(); msg.set_typ(protocol::spirc::CapabilityType::kSupportedContexts); { let repeated = msg.mut_stringValue(); repeated.push(::std::convert::Into::into("album")); repeated.push(::std::convert::Into::into("playlist")); repeated.push(::std::convert::Into::into("search")); repeated.push(::std::convert::Into::into("inbox")); repeated.push(::std::convert::Into::into("toplist")); repeated.push(::std::convert::Into::into("starred")); repeated.push(::std::convert::Into::into("publishedstarred")); repeated.push(::std::convert::Into::into("track")) }; msg }; { let msg = repeated.push_default(); msg.set_typ(protocol::spirc::CapabilityType::kSupportedTypes); { let repeated = msg.mut_stringValue(); repeated.push(::std::convert::Into::into("audio/local")); repeated.push(::std::convert::Into::into("audio/track")); repeated.push(::std::convert::Into::into("local")); repeated.push(::std::convert::Into::into("track")) }; msg }; }; msg } } fn calc_logarithmic_volume(volume: u16) -> u16 { // Volume conversion taken from https://www.dr-lex.be/info-stuff/volumecontrols.html#ideal2 // Convert the given volume [0..0xffff] to a dB gain // We assume a dB range of 60dB. // Use the equatation: a * exp(b * x) // in which a = IDEAL_FACTOR, b = 1/1000 const IDEAL_FACTOR: f64 = 6.908; let normalized_volume = volume as f64 / std::u16::MAX as f64; // To get a value between 0 and 1 let mut val = std::u16::MAX; // Prevent val > std::u16::MAX due to rounding errors if normalized_volume < 0.999 { let new_volume = (normalized_volume * IDEAL_FACTOR).exp() / 1000.0; val = (new_volume * std::u16::MAX as f64) as u16; } debug!("input volume:{} to mixer: {}", volume, val); // return the scale factor (0..0xffff) (equivalent to a voltage multiplier). val } fn volume_to_mixer(volume: u16, linear_volume: bool) -> u16 { if linear_volume { debug!("linear volume: {}", volume); volume } else { calc_logarithmic_volume(volume) } } impl Spirc { pub fn new( config: ConnectConfig, session: Session, player: Player, mixer: Box, ) -> (Spirc, SpircTask) { debug!("new Spirc[{}]", session.session_id()); let ident = session.device_id().to_owned(); let uri = format!("hm://remote/3/user/{}/", session.username()); let subscription = session.mercury().subscribe(&uri as &str); let subscription = subscription .map(|stream| stream.map_err(|_| MercuryError)) .flatten_stream(); let subscription = Box::new(subscription.map(|response| -> Frame { let data = response.payload.first().unwrap(); protobuf::parse_from_bytes(data).unwrap() })); let sender = Box::new( session .mercury() .sender(uri) .with(|frame: Frame| Ok(frame.write_to_bytes().unwrap())), ); let (cmd_tx, cmd_rx) = mpsc::unbounded(); let volume = config.volume as u16; let linear_volume = config.linear_volume; let device = initial_device_state(config, volume); mixer.set_volume(volume_to_mixer(volume as u16, linear_volume)); let mut task = SpircTask { player: player, mixer: mixer, linear_volume: linear_volume, sequence: SeqGenerator::new(1), ident: ident, device: device, state: initial_state(), subscription: subscription, sender: sender, commands: cmd_rx, end_of_track: Box::new(future::empty()), shutdown: false, session: session.clone(), }; let spirc = Spirc { commands: cmd_tx }; task.hello(); (spirc, task) } pub fn play(&self) { let _ = self.commands.unbounded_send(SpircCommand::Play); } pub fn play_pause(&self) { let _ = self.commands.unbounded_send(SpircCommand::PlayPause); } pub fn pause(&self) { let _ = self.commands.unbounded_send(SpircCommand::Pause); } pub fn prev(&self) { let _ = self.commands.unbounded_send(SpircCommand::Prev); } pub fn next(&self) { let _ = self.commands.unbounded_send(SpircCommand::Next); } pub fn volume_up(&self) { let _ = self.commands.unbounded_send(SpircCommand::VolumeUp); } pub fn volume_down(&self) { let _ = self.commands.unbounded_send(SpircCommand::VolumeDown); } pub fn shutdown(&self) { let _ = self.commands.unbounded_send(SpircCommand::Shutdown); } } impl Future for SpircTask { type Item = (); type Error = (); fn poll(&mut self) -> Poll<(), ()> { loop { let mut progress = false; if self.session.is_invalid() { return Ok(Async::Ready(())); } if !self.shutdown { match self.subscription.poll().unwrap() { Async::Ready(Some(frame)) => { progress = true; self.handle_frame(frame); } Async::Ready(None) => panic!("subscription terminated"), Async::NotReady => (), } match self.commands.poll().unwrap() { Async::Ready(Some(command)) => { progress = true; self.handle_command(command); } Async::Ready(None) => (), Async::NotReady => (), } match self.end_of_track.poll() { Ok(Async::Ready(())) => { progress = true; self.handle_end_of_track(); } Ok(Async::NotReady) => (), Err(oneshot::Canceled) => self.end_of_track = Box::new(future::empty()), } } let poll_sender = self.sender.poll_complete().unwrap(); // Only shutdown once we've flushed out all our messages if self.shutdown && poll_sender.is_ready() { return Ok(Async::Ready(())); } if !progress { return Ok(Async::NotReady); } } } } impl SpircTask { fn handle_command(&mut self, cmd: SpircCommand) { let active = self.device.get_is_active(); match cmd { SpircCommand::Play => { if active { self.handle_play(); self.notify(None); } else { CommandSender::new(self, MessageType::kMessageTypePlay).send(); } } SpircCommand::PlayPause => { if active { self.handle_play_pause(); self.notify(None); } else { CommandSender::new(self, MessageType::kMessageTypePlayPause).send(); } } SpircCommand::Pause => { if active { self.handle_pause(); self.notify(None); } else { CommandSender::new(self, MessageType::kMessageTypePause).send(); } } SpircCommand::Prev => { if active { self.handle_prev(); self.notify(None); } else { CommandSender::new(self, MessageType::kMessageTypePrev).send(); } } SpircCommand::Next => { if active { self.handle_next(); self.notify(None); } else { CommandSender::new(self, MessageType::kMessageTypeNext).send(); } } SpircCommand::VolumeUp => { if active { self.handle_volume_up(); self.notify(None); } else { CommandSender::new(self, MessageType::kMessageTypeVolumeUp).send(); } } SpircCommand::VolumeDown => { if active { self.handle_volume_down(); self.notify(None); } else { CommandSender::new(self, MessageType::kMessageTypeVolumeDown).send(); } } SpircCommand::Shutdown => { CommandSender::new(self, MessageType::kMessageTypeGoodbye).send(); self.shutdown = true; self.commands.close(); } } } fn handle_frame(&mut self, frame: Frame) { debug!( "{:?} {:?} {} {} {}", frame.get_typ(), frame.get_device_state().get_name(), frame.get_ident(), frame.get_seq_nr(), frame.get_state_update_id() ); if frame.get_ident() == self.ident || (frame.get_recipient().len() > 0 && !frame.get_recipient().contains(&self.ident)) { return; } match frame.get_typ() { MessageType::kMessageTypeHello => { self.notify(Some(frame.get_ident())); } MessageType::kMessageTypeLoad => { if !self.device.get_is_active() { self.device.set_is_active(true); self.device.set_became_active_at(now_ms()); } self.update_tracks(&frame); if self.state.get_track().len() > 0 { self.state.set_position_ms(frame.get_state().get_position_ms()); self.state.set_position_measured_at(now_ms() as u64); let play = frame.get_state().get_status() == PlayStatus::kPlayStatusPlay; self.load_track(play); } else { self.state.set_status(PlayStatus::kPlayStatusStop); } self.notify(None); } MessageType::kMessageTypePlay => { self.handle_play(); self.notify(None); } MessageType::kMessageTypePlayPause => { self.handle_play_pause(); self.notify(None); } MessageType::kMessageTypePause => { self.handle_pause(); self.notify(None); } MessageType::kMessageTypeNext => { self.handle_next(); self.notify(None); } MessageType::kMessageTypePrev => { self.handle_prev(); self.notify(None); } MessageType::kMessageTypeVolumeUp => { self.handle_volume_up(); self.notify(None); } MessageType::kMessageTypeVolumeDown => { self.handle_volume_down(); self.notify(None); } MessageType::kMessageTypeRepeat => { self.state.set_repeat(frame.get_state().get_repeat()); self.notify(None); } MessageType::kMessageTypeShuffle => { self.state.set_shuffle(frame.get_state().get_shuffle()); if self.state.get_shuffle() { let current_index = self.state.get_playing_track_index(); { let tracks = self.state.mut_track(); tracks.swap(0, current_index as usize); if let Some((_, rest)) = tracks.split_first_mut() { rand::thread_rng().shuffle(rest); } } self.state.set_playing_track_index(0); } else { let context = self.state.get_context_uri(); debug!("{:?}", context); } self.notify(None); } MessageType::kMessageTypeSeek => { let position = frame.get_position(); self.state.set_position_ms(position); self.state.set_position_measured_at(now_ms() as u64); self.player.seek(position); self.notify(None); } MessageType::kMessageTypeReplace => { self.update_tracks(&frame); self.notify(None); } MessageType::kMessageTypeVolume => { self.device.set_volume(frame.get_volume()); self.mixer .set_volume(volume_to_mixer(frame.get_volume() as u16, self.linear_volume)); self.notify(None); } MessageType::kMessageTypeNotify => { if self.device.get_is_active() && frame.get_device_state().get_is_active() { self.device.set_is_active(false); self.state.set_status(PlayStatus::kPlayStatusStop); self.player.stop(); self.mixer.stop(); } } _ => (), } } fn handle_play(&mut self) { if self.state.get_status() == PlayStatus::kPlayStatusPause { self.mixer.start(); self.player.play(); self.state.set_status(PlayStatus::kPlayStatusPlay); self.state.set_position_measured_at(now_ms() as u64); } } fn handle_play_pause(&mut self) { match self.state.get_status() { PlayStatus::kPlayStatusPlay => self.handle_pause(), PlayStatus::kPlayStatusPause => self.handle_play(), _ => (), } } fn handle_pause(&mut self) { if self.state.get_status() == PlayStatus::kPlayStatusPlay { self.player.pause(); self.mixer.stop(); self.state.set_status(PlayStatus::kPlayStatusPause); let now = now_ms() as u64; let position = self.state.get_position_ms(); let diff = now - self.state.get_position_measured_at(); self.state.set_position_ms(position + diff as u32); self.state.set_position_measured_at(now); } } fn consume_queued_track(&mut self) -> usize { // Removes current track if it is queued // Returns the index of the next track let current_index = self.state.get_playing_track_index() as usize; if self.state.get_track()[current_index].get_queued() { self.state.mut_track().remove(current_index); return current_index; } current_index + 1 } fn handle_next(&mut self) { let mut new_index = self.consume_queued_track() as u32; let mut continue_playing = true; if new_index >= self.state.get_track().len() as u32 { new_index = 0; // Loop around back to start continue_playing = self.state.get_repeat(); } self.state.set_playing_track_index(new_index); self.state.set_position_ms(0); self.state.set_position_measured_at(now_ms() as u64); self.load_track(continue_playing); } fn handle_prev(&mut self) { // Previous behaves differently based on the position // Under 3s it goes to the previous song (starts playing) // Over 3s it seeks to zero (retains previous play status) if self.position() < 3000 { // Queued tracks always follow the currently playing track. // They should not be considered when calculating the previous // track so extract them beforehand and reinsert them after it. let mut queue_tracks = Vec::new(); { let queue_index = self.consume_queued_track(); let tracks = self.state.mut_track(); while queue_index < tracks.len() && tracks[queue_index].get_queued() { queue_tracks.push(tracks.remove(queue_index)); } } let current_index = self.state.get_playing_track_index(); let new_index = if current_index > 0 { current_index - 1 } else if self.state.get_repeat() { self.state.get_track().len() as u32 - 1 } else { 0 }; // Reinsert queued tracks after the new playing track. let mut pos = (new_index + 1) as usize; for track in queue_tracks.into_iter() { self.state.mut_track().insert(pos, track); pos += 1; } self.state.set_playing_track_index(new_index); self.state.set_position_ms(0); self.state.set_position_measured_at(now_ms() as u64); self.load_track(true); } else { self.state.set_position_ms(0); self.state.set_position_measured_at(now_ms() as u64); self.player.seek(0); } } fn handle_volume_up(&mut self) { let mut volume: u32 = self.device.get_volume() as u32 + 4096; if volume > 0xFFFF { volume = 0xFFFF; } self.device.set_volume(volume); self.mixer .set_volume(volume_to_mixer(volume as u16, self.linear_volume)); } fn handle_volume_down(&mut self) { let mut volume: i32 = self.device.get_volume() as i32 - 4096; if volume < 0 { volume = 0; } self.device.set_volume(volume as u32); self.mixer .set_volume(volume_to_mixer(volume as u16, self.linear_volume)); } fn handle_end_of_track(&mut self) { self.handle_next(); self.notify(None); } fn position(&mut self) -> u32 { let diff = now_ms() as u64 - self.state.get_position_measured_at(); self.state.get_position_ms() + diff as u32 } fn update_tracks(&mut self, frame: &protocol::spirc::Frame) { let index = frame.get_state().get_playing_track_index(); let tracks = frame.get_state().get_track(); let context_uri = frame.get_state().get_context_uri().to_owned(); self.state.set_playing_track_index(index); self.state.set_track(tracks.into_iter().cloned().collect()); self.state.set_context_uri(context_uri); self.state.set_repeat(frame.get_state().get_repeat()); self.state.set_shuffle(frame.get_state().get_shuffle()); } fn load_track(&mut self, play: bool) { let index = self.state.get_playing_track_index(); let track = { let gid = self.state.get_track()[index as usize].get_gid(); SpotifyId::from_raw(gid).unwrap() }; let position = self.state.get_position_ms(); let end_of_track = self.player.load(track, play, position); if play { self.state.set_status(PlayStatus::kPlayStatusPlay); } else { self.state.set_status(PlayStatus::kPlayStatusPause); } self.end_of_track = Box::new(end_of_track); } fn hello(&mut self) { CommandSender::new(self, MessageType::kMessageTypeHello).send(); } fn notify(&mut self, recipient: Option<&str>) { let mut cs = CommandSender::new(self, MessageType::kMessageTypeNotify); if let Some(s) = recipient { cs = cs.recipient(&s); } cs.send(); } } impl Drop for SpircTask { fn drop(&mut self) { debug!("drop Spirc[{}]", self.session.session_id()); } } struct CommandSender<'a> { spirc: &'a mut SpircTask, frame: protocol::spirc::Frame, } impl<'a> CommandSender<'a> { fn new(spirc: &'a mut SpircTask, cmd: MessageType) -> CommandSender { let mut frame = protocol::spirc::Frame::new(); frame.set_version(1); frame.set_protocol_version(::std::convert::Into::into("2.0.0")); frame.set_ident(spirc.ident.clone()); frame.set_seq_nr(spirc.sequence.get()); frame.set_typ(cmd); frame.set_device_state(spirc.device.clone()); frame.set_state_update_id(now_ms()); CommandSender { spirc: spirc, frame: frame, } } fn recipient(mut self, recipient: &'a str) -> CommandSender { self.frame.mut_recipient().push(recipient.to_owned()); self } #[allow(dead_code)] fn state(mut self, state: protocol::spirc::State) -> CommandSender<'a> { self.frame.set_state(state); self } fn send(mut self) { if !self.frame.has_state() && self.spirc.device.get_is_active() { self.frame.set_state(self.spirc.state.clone()); } let send = self.spirc.sender.start_send(self.frame).unwrap(); assert!(send.is_ready()); } }