librespot/audio/src/fetch.rs
2020-01-17 18:47:30 +01:00

1083 lines
39 KiB
Rust

use byteorder::{BigEndian, ByteOrder, WriteBytesExt};
use bytes::Bytes;
use futures::sync::{mpsc, oneshot};
use futures::Stream;
use futures::{Async, Future, Poll};
use range_set::{Range, RangeSet};
use std::cmp::{max, min};
use std::fs;
use std::io::{self, Read, Seek, SeekFrom, Write};
use std::sync::{Arc, Condvar, Mutex};
use std::time::{Duration, Instant};
use tempfile::NamedTempFile;
use futures::sync::mpsc::unbounded;
use librespot_core::channel::{Channel, ChannelData, ChannelError, ChannelHeaders};
use librespot_core::session::Session;
use librespot_core::spotify_id::FileId;
use std::sync::atomic;
use std::sync::atomic::AtomicUsize;
const MINIMUM_DOWNLOAD_SIZE: usize = 1024 * 16;
// The minimum size of a block that is requested from the Spotify servers in one request.
// This is the block size that is typically requested while doing a seek() on a file.
// Note: smaller requests can happen if part of the block is downloaded already.
const INITIAL_DOWNLOAD_SIZE: usize = 1024 * 16;
// The amount of data that is requested when initially opening a file.
// Note: if the file is opened to play from the beginning, the amount of data to
// read ahead is requested in addition to this amount. If the file is opened to seek to
// another position, then only this amount is requested on the first request.
const INITIAL_PING_TIME_ESTIMATE_SECONDS: f64 = 0.5;
// The pig time that is used for calculations before a ping time was actually measured.
const MAXIMUM_ASSUMED_PING_TIME_SECONDS: f64 = 1.5;
// If the measured ping time to the Spotify server is larger than this value, it is capped
// to avoid run-away block sizes and pre-fetching.
pub const READ_AHEAD_BEFORE_PLAYBACK_SECONDS: f64 = 1.0;
// Before playback starts, this many seconds of data must be present.
// Note: the calculations are done using the nominal bitrate of the file. The actual amount
// of audio data may be larger or smaller.
pub const READ_AHEAD_BEFORE_PLAYBACK_ROUNDTRIPS: f64 = 2.0;
// Same as READ_AHEAD_BEFORE_PLAYBACK_SECONDS, but the time is taken as a factor of the ping
// time to the Spotify server.
// Both, READ_AHEAD_BEFORE_PLAYBACK_SECONDS and READ_AHEAD_BEFORE_PLAYBACK_ROUNDTRIPS are
// obeyed.
// Note: the calculations are done using the nominal bitrate of the file. The actual amount
// of audio data may be larger or smaller.
pub const READ_AHEAD_DURING_PLAYBACK_SECONDS: f64 = 5.0;
// While playing back, this many seconds of data ahead of the current read position are
// requested.
// Note: the calculations are done using the nominal bitrate of the file. The actual amount
// of audio data may be larger or smaller.
pub const READ_AHEAD_DURING_PLAYBACK_ROUNDTRIPS: f64 = 10.0;
// Same as READ_AHEAD_DURING_PLAYBACK_SECONDS, but the time is taken as a factor of the ping
// time to the Spotify server.
// Note: the calculations are done using the nominal bitrate of the file. The actual amount
// of audio data may be larger or smaller.
const PREFETCH_THRESHOLD_FACTOR: f64 = 4.0;
// If the amount of data that is pending (requested but not received) is less than a certain amount,
// data is pre-fetched in addition to the read ahead settings above. The threshold for requesting more
// data is calculated as
// <pending bytes> < PREFETCH_THRESHOLD_FACTOR * <ping time> * <nominal data rate>
const FAST_PREFETCH_THRESHOLD_FACTOR: f64 = 1.5;
// Similar to PREFETCH_THRESHOLD_FACTOR, but it also takes the current download rate into account.
// The formula used is
// <pending bytes> < FAST_PREFETCH_THRESHOLD_FACTOR * <ping time> * <measured download rate>
// This mechanism allows for fast downloading of the remainder of the file. The number should be larger
// than 1 so the download rate ramps up until the bandwidth is saturated. The larger the value, the faster
// the download rate ramps up. However, this comes at the cost that it might hurt ping-time if a seek is
// performed while downloading. Values smaller than 1 cause the download rate to collapse and effectively
// only PREFETCH_THRESHOLD_FACTOR is in effect. Thus, set to zero if bandwidth saturation is not wanted.
const MAX_PREFETCH_REQUESTS: usize = 4;
// Limit the number of requests that are pending simultaneously before pre-fetching data. Pending
// requests share bandwidth. Thus, havint too many requests can lead to the one that is needed next
// for playback to be delayed leading to a buffer underrun. This limit has the effect that a new
// pre-fetch request is only sent if less than MAX_PREFETCH_REQUESTS are pending.
pub enum AudioFile {
Cached(fs::File),
Streaming(AudioFileStreaming),
}
pub enum AudioFileOpen {
Cached(Option<fs::File>),
Streaming(AudioFileOpenStreaming),
}
pub struct AudioFileOpenStreaming {
session: Session,
initial_data_rx: Option<ChannelData>,
initial_data_length: Option<usize>,
initial_request_sent_time: Instant,
headers: ChannelHeaders,
file_id: FileId,
complete_tx: Option<oneshot::Sender<NamedTempFile>>,
streaming_data_rate: usize,
}
enum StreamLoaderCommand {
Fetch(Range), // signal the stream loader to fetch a range of the file
RandomAccessMode(), // optimise download strategy for random access
StreamMode(), // optimise download strategy for streaming
Close(), // terminate and don't load any more data
}
#[derive(Clone)]
pub struct StreamLoaderController {
channel_tx: Option<mpsc::UnboundedSender<StreamLoaderCommand>>,
stream_shared: Option<Arc<AudioFileShared>>,
file_size: usize,
}
impl StreamLoaderController {
pub fn len(&self) -> usize {
return self.file_size;
}
pub fn range_available(&self, range: Range) -> bool {
if let Some(ref shared) = self.stream_shared {
let download_status = shared.download_status.lock().unwrap();
if range.length
<= download_status
.downloaded
.contained_length_from_value(range.start)
{
return true;
} else {
return false;
}
} else {
if range.length <= self.len() - range.start {
return true;
} else {
return false;
}
}
}
pub fn ping_time_ms(&self) -> usize {
if let Some(ref shared) = self.stream_shared {
return shared.ping_time_ms.load(atomic::Ordering::Relaxed);
} else {
return 0;
}
}
fn send_stream_loader_command(&mut self, command: StreamLoaderCommand) {
if let Some(ref mut channel) = self.channel_tx {
// ignore the error in case the channel has been closed already.
let _ = channel.unbounded_send(command);
}
}
pub fn fetch(&mut self, range: Range) {
// signal the stream loader to fetch a range of the file
self.send_stream_loader_command(StreamLoaderCommand::Fetch(range));
}
pub fn fetch_blocking(&mut self, mut range: Range) {
// signal the stream loader to tech a range of the file and block until it is loaded.
// ensure the range is within the file's bounds.
if range.start >= self.len() {
range.length = 0;
} else if range.end() > self.len() {
range.length = self.len() - range.start;
}
self.fetch(range);
if let Some(ref shared) = self.stream_shared {
let mut download_status = shared.download_status.lock().unwrap();
while range.length
> download_status
.downloaded
.contained_length_from_value(range.start)
{
download_status = shared
.cond
.wait_timeout(download_status, Duration::from_millis(1000))
.unwrap()
.0;
if range.length
> (download_status
.downloaded
.union(&download_status.requested)
.contained_length_from_value(range.start))
{
// For some reason, the requested range is neither downloaded nor requested.
// This could be due to a network error. Request it again.
// We can't use self.fetch here because self can't be borrowed mutably, so we access the channel directly.
if let Some(ref mut channel) = self.channel_tx {
// ignore the error in case the channel has been closed already.
let _ = channel.unbounded_send(StreamLoaderCommand::Fetch(range));
}
}
}
}
}
pub fn fetch_next(&mut self, length: usize) {
let range: Range = if let Some(ref shared) = self.stream_shared {
Range {
start: shared.read_position.load(atomic::Ordering::Relaxed),
length: length,
}
} else {
return;
};
self.fetch(range);
}
pub fn fetch_next_blocking(&mut self, length: usize) {
let range: Range = if let Some(ref shared) = self.stream_shared {
Range {
start: shared.read_position.load(atomic::Ordering::Relaxed),
length: length,
}
} else {
return;
};
self.fetch_blocking(range);
}
pub fn set_random_access_mode(&mut self) {
// optimise download strategy for random access
self.send_stream_loader_command(StreamLoaderCommand::RandomAccessMode());
}
pub fn set_stream_mode(&mut self) {
// optimise download strategy for streaming
self.send_stream_loader_command(StreamLoaderCommand::StreamMode());
}
pub fn close(&mut self) {
// terminate stream loading and don't load any more data for this file.
self.send_stream_loader_command(StreamLoaderCommand::Close());
}
}
pub struct AudioFileStreaming {
read_file: fs::File,
position: u64,
stream_loader_command_tx: mpsc::UnboundedSender<StreamLoaderCommand>,
shared: Arc<AudioFileShared>,
}
struct AudioFileDownloadStatus {
requested: RangeSet,
downloaded: RangeSet,
}
#[derive(Copy, Clone)]
enum DownloadStrategy {
RandomAccess(),
Streaming(),
}
struct AudioFileShared {
file_id: FileId,
file_size: usize,
stream_data_rate: usize,
cond: Condvar,
download_status: Mutex<AudioFileDownloadStatus>,
download_strategy: Mutex<DownloadStrategy>,
number_of_open_requests: AtomicUsize,
ping_time_ms: AtomicUsize,
read_position: AtomicUsize,
}
impl AudioFileOpenStreaming {
fn finish(&mut self, size: usize) -> AudioFileStreaming {
let shared = Arc::new(AudioFileShared {
file_id: self.file_id,
file_size: size,
stream_data_rate: self.streaming_data_rate,
cond: Condvar::new(),
download_status: Mutex::new(AudioFileDownloadStatus {
requested: RangeSet::new(),
downloaded: RangeSet::new(),
}),
download_strategy: Mutex::new(DownloadStrategy::RandomAccess()), // start with random access mode until someone tells us otherwise
number_of_open_requests: AtomicUsize::new(0),
ping_time_ms: AtomicUsize::new(0),
read_position: AtomicUsize::new(0),
});
let mut write_file = NamedTempFile::new().unwrap();
write_file.as_file().set_len(size as u64).unwrap();
write_file.seek(SeekFrom::Start(0)).unwrap();
let read_file = write_file.reopen().unwrap();
let initial_data_rx = self.initial_data_rx.take().unwrap();
let initial_data_length = self.initial_data_length.take().unwrap();
let complete_tx = self.complete_tx.take().unwrap();
//let (seek_tx, seek_rx) = mpsc::unbounded();
let (stream_loader_command_tx, stream_loader_command_rx) =
mpsc::unbounded::<StreamLoaderCommand>();
let fetcher = AudioFileFetch::new(
self.session.clone(),
shared.clone(),
initial_data_rx,
self.initial_request_sent_time,
initial_data_length,
write_file,
stream_loader_command_rx,
complete_tx,
);
self.session.spawn(move |_| fetcher);
AudioFileStreaming {
read_file: read_file,
position: 0,
//seek: seek_tx,
stream_loader_command_tx: stream_loader_command_tx,
shared: shared,
}
}
}
impl Future for AudioFileOpen {
type Item = AudioFile;
type Error = ChannelError;
fn poll(&mut self) -> Poll<AudioFile, ChannelError> {
match *self {
AudioFileOpen::Streaming(ref mut open) => {
let file = try_ready!(open.poll());
Ok(Async::Ready(AudioFile::Streaming(file)))
}
AudioFileOpen::Cached(ref mut file) => {
let file = file.take().unwrap();
Ok(Async::Ready(AudioFile::Cached(file)))
}
}
}
}
impl Future for AudioFileOpenStreaming {
type Item = AudioFileStreaming;
type Error = ChannelError;
fn poll(&mut self) -> Poll<AudioFileStreaming, ChannelError> {
loop {
let (id, data) = try_ready!(self.headers.poll()).unwrap();
if id == 0x3 {
let size = BigEndian::read_u32(&data) as usize * 4;
let file = self.finish(size);
return Ok(Async::Ready(file));
}
}
}
}
impl AudioFile {
pub fn open(
session: &Session,
file_id: FileId,
bytes_per_second: usize,
play_from_beginning: bool,
) -> AudioFileOpen {
let cache = session.cache().cloned();
if let Some(file) = cache.as_ref().and_then(|cache| cache.file(file_id)) {
debug!("File {} already in cache", file_id);
return AudioFileOpen::Cached(Some(file));
}
debug!("Downloading file {}", file_id);
let (complete_tx, complete_rx) = oneshot::channel();
let mut initial_data_length = if play_from_beginning {
INITIAL_DOWNLOAD_SIZE
+ max(
(READ_AHEAD_DURING_PLAYBACK_SECONDS * bytes_per_second as f64) as usize,
(INITIAL_PING_TIME_ESTIMATE_SECONDS
* READ_AHEAD_DURING_PLAYBACK_ROUNDTRIPS
* bytes_per_second as f64) as usize,
)
} else {
INITIAL_DOWNLOAD_SIZE
};
if initial_data_length % 4 != 0 {
initial_data_length += 4 - (initial_data_length % 4);
}
let (headers, data) = request_range(session, file_id, 0, initial_data_length).split();
let open = AudioFileOpenStreaming {
session: session.clone(),
file_id: file_id,
headers: headers,
initial_data_rx: Some(data),
initial_data_length: Some(initial_data_length),
initial_request_sent_time: Instant::now(),
complete_tx: Some(complete_tx),
streaming_data_rate: bytes_per_second,
};
let session_ = session.clone();
session.spawn(move |_| {
complete_rx
.map(move |mut file| {
if let Some(cache) = session_.cache() {
cache.save_file(file_id, &mut file);
debug!("File {} complete, saving to cache", file_id);
} else {
debug!("File {} complete", file_id);
}
})
.or_else(|oneshot::Canceled| Ok(()))
});
return AudioFileOpen::Streaming(open);
}
pub fn get_stream_loader_controller(&self) -> StreamLoaderController {
match self {
AudioFile::Streaming(ref stream) => {
return StreamLoaderController {
channel_tx: Some(stream.stream_loader_command_tx.clone()),
stream_shared: Some(stream.shared.clone()),
file_size: stream.shared.file_size,
};
}
AudioFile::Cached(ref file) => {
return StreamLoaderController {
channel_tx: None,
stream_shared: None,
file_size: file.metadata().unwrap().len() as usize,
};
}
}
}
}
fn request_range(session: &Session, file: FileId, offset: usize, length: usize) -> Channel {
assert!(
offset % 4 == 0,
"Range request start positions must be aligned by 4 bytes."
);
assert!(
length % 4 == 0,
"Range request range lengths must be aligned by 4 bytes."
);
let start = offset / 4;
let end = (offset + length) / 4;
let (id, channel) = session.channel().allocate();
let mut data: Vec<u8> = Vec::new();
data.write_u16::<BigEndian>(id).unwrap();
data.write_u8(0).unwrap();
data.write_u8(1).unwrap();
data.write_u16::<BigEndian>(0x0000).unwrap();
data.write_u32::<BigEndian>(0x00000000).unwrap();
data.write_u32::<BigEndian>(0x00009C40).unwrap();
data.write_u32::<BigEndian>(0x00020000).unwrap();
data.write(&file.0).unwrap();
data.write_u32::<BigEndian>(start as u32).unwrap();
data.write_u32::<BigEndian>(end as u32).unwrap();
session.send_packet(0x8, data);
channel
}
struct PartialFileData {
offset: usize,
data: Bytes,
}
enum ReceivedData {
ResponseTimeMs(usize),
Data(PartialFileData),
}
struct AudioFileFetchDataReceiver {
shared: Arc<AudioFileShared>,
file_data_tx: mpsc::UnboundedSender<ReceivedData>,
data_rx: ChannelData,
initial_data_offset: usize,
initial_request_length: usize,
data_offset: usize,
request_length: usize,
request_sent_time: Option<Instant>,
measure_ping_time: bool,
}
impl AudioFileFetchDataReceiver {
fn new(
shared: Arc<AudioFileShared>,
file_data_tx: mpsc::UnboundedSender<ReceivedData>,
data_rx: ChannelData,
data_offset: usize,
request_length: usize,
request_sent_time: Instant,
) -> AudioFileFetchDataReceiver {
let measure_ping_time = shared
.number_of_open_requests
.load(atomic::Ordering::SeqCst)
== 0;
shared
.number_of_open_requests
.fetch_add(1, atomic::Ordering::SeqCst);
AudioFileFetchDataReceiver {
shared: shared,
data_rx: data_rx,
file_data_tx: file_data_tx,
initial_data_offset: data_offset,
initial_request_length: request_length,
data_offset: data_offset,
request_length: request_length,
request_sent_time: Some(request_sent_time),
measure_ping_time: measure_ping_time,
}
}
}
impl AudioFileFetchDataReceiver {
fn finish(&mut self) {
if self.request_length > 0 {
let missing_range = Range::new(self.data_offset, self.request_length);
let mut download_status = self.shared.download_status.lock().unwrap();
download_status.requested.subtract_range(&missing_range);
self.shared.cond.notify_all();
}
self.shared
.number_of_open_requests
.fetch_sub(1, atomic::Ordering::SeqCst);
}
}
impl Future for AudioFileFetchDataReceiver {
type Item = ();
type Error = ();
fn poll(&mut self) -> Poll<(), ()> {
loop {
match self.data_rx.poll() {
Ok(Async::Ready(Some(data))) => {
if self.measure_ping_time {
if let Some(request_sent_time) = self.request_sent_time {
let duration = Instant::now() - request_sent_time;
let duration_ms: u64;
if 0.001 * (duration.as_millis() as f64)
> MAXIMUM_ASSUMED_PING_TIME_SECONDS
{
duration_ms = (MAXIMUM_ASSUMED_PING_TIME_SECONDS * 1000.0) as u64;
} else {
duration_ms = duration.as_millis() as u64;
}
let _ = self
.file_data_tx
.unbounded_send(ReceivedData::ResponseTimeMs(duration_ms as usize));
self.measure_ping_time = false;
}
}
let data_size = data.len();
let _ = self
.file_data_tx
.unbounded_send(ReceivedData::Data(PartialFileData {
offset: self.data_offset,
data: data,
}));
self.data_offset += data_size;
if self.request_length < data_size {
warn!("Data receiver for range {} (+{}) received more data from server than requested.", self.initial_data_offset, self.initial_request_length);
self.request_length = 0;
} else {
self.request_length -= data_size;
}
if self.request_length == 0 {
self.finish();
return Ok(Async::Ready(()));
}
}
Ok(Async::Ready(None)) => {
if self.request_length > 0 {
warn!("Data receiver for range {} (+{}) received less data from server than requested.", self.initial_data_offset, self.initial_request_length);
}
self.finish();
return Ok(Async::Ready(()));
}
Ok(Async::NotReady) => {
return Ok(Async::NotReady);
}
Err(ChannelError) => {
warn!(
"Error from channel for data receiver for range {} (+{}).",
self.initial_data_offset, self.initial_request_length
);
self.finish();
return Ok(Async::Ready(()));
}
}
}
}
}
struct AudioFileFetch {
session: Session,
shared: Arc<AudioFileShared>,
output: Option<NamedTempFile>,
file_data_tx: mpsc::UnboundedSender<ReceivedData>,
file_data_rx: mpsc::UnboundedReceiver<ReceivedData>,
stream_loader_command_rx: mpsc::UnboundedReceiver<StreamLoaderCommand>,
complete_tx: Option<oneshot::Sender<NamedTempFile>>,
network_response_times_ms: Vec<usize>,
}
impl AudioFileFetch {
fn new(
session: Session,
shared: Arc<AudioFileShared>,
initial_data_rx: ChannelData,
initial_request_sent_time: Instant,
initial_data_length: usize,
output: NamedTempFile,
stream_loader_command_rx: mpsc::UnboundedReceiver<StreamLoaderCommand>,
complete_tx: oneshot::Sender<NamedTempFile>,
) -> AudioFileFetch {
let (file_data_tx, file_data_rx) = unbounded::<ReceivedData>();
{
let requested_range = Range::new(0, initial_data_length);
let mut download_status = shared.download_status.lock().unwrap();
download_status.requested.add_range(&requested_range);
}
let initial_data_receiver = AudioFileFetchDataReceiver::new(
shared.clone(),
file_data_tx.clone(),
initial_data_rx,
0,
initial_data_length,
initial_request_sent_time,
);
session.spawn(move |_| initial_data_receiver);
AudioFileFetch {
session: session,
shared: shared,
output: Some(output),
file_data_tx: file_data_tx,
file_data_rx: file_data_rx,
stream_loader_command_rx: stream_loader_command_rx,
complete_tx: Some(complete_tx),
network_response_times_ms: Vec::new(),
}
}
fn get_download_strategy(&mut self) -> DownloadStrategy {
*(self.shared.download_strategy.lock().unwrap())
}
fn download_range(&mut self, mut offset: usize, mut length: usize) {
if length < MINIMUM_DOWNLOAD_SIZE {
length = MINIMUM_DOWNLOAD_SIZE;
}
// ensure the values are within the bounds and align them by 4 for the spotify protocol.
if offset >= self.shared.file_size {
return;
}
if length <= 0 {
return;
}
if offset + length > self.shared.file_size {
length = self.shared.file_size - offset;
}
if offset % 4 != 0 {
length += offset % 4;
offset -= offset % 4;
}
if length % 4 != 0 {
length += 4 - (length % 4);
}
let mut ranges_to_request = RangeSet::new();
ranges_to_request.add_range(&Range::new(offset, length));
let mut download_status = self.shared.download_status.lock().unwrap();
ranges_to_request.subtract_range_set(&download_status.downloaded);
ranges_to_request.subtract_range_set(&download_status.requested);
for range in ranges_to_request.iter() {
let (_headers, data) = request_range(
&self.session,
self.shared.file_id,
range.start,
range.length,
)
.split();
download_status.requested.add_range(range);
let receiver = AudioFileFetchDataReceiver::new(
self.shared.clone(),
self.file_data_tx.clone(),
data,
range.start,
range.length,
Instant::now(),
);
self.session.spawn(move |_| receiver);
}
}
fn pre_fetch_more_data(&mut self, bytes: usize, max_requests_to_send: usize) {
let mut bytes_to_go = bytes;
let mut requests_to_go = max_requests_to_send;
while bytes_to_go > 0 && requests_to_go > 0 {
// determine what is still missing
let mut missing_data = RangeSet::new();
missing_data.add_range(&Range::new(0, self.shared.file_size));
{
let download_status = self.shared.download_status.lock().unwrap();
missing_data.subtract_range_set(&download_status.downloaded);
missing_data.subtract_range_set(&download_status.requested);
}
// download data from after the current read position first
let mut tail_end = RangeSet::new();
let read_position = self.shared.read_position.load(atomic::Ordering::Relaxed);
tail_end.add_range(&Range::new(
read_position,
self.shared.file_size - read_position,
));
let tail_end = tail_end.intersection(&missing_data);
if !tail_end.is_empty() {
let range = tail_end.get_range(0);
let offset = range.start;
let length = min(range.length, bytes_to_go);
self.download_range(offset, length);
requests_to_go -= 1;
bytes_to_go -= length;
} else if !missing_data.is_empty() {
// ok, the tail is downloaded, download something fom the beginning.
let range = missing_data.get_range(0);
let offset = range.start;
let length = min(range.length, bytes_to_go);
self.download_range(offset, length);
requests_to_go -= 1;
bytes_to_go -= length;
} else {
return;
}
}
}
fn poll_file_data_rx(&mut self) -> Poll<(), ()> {
loop {
match self.file_data_rx.poll() {
Ok(Async::Ready(None)) => {
return Ok(Async::Ready(()));
}
Ok(Async::Ready(Some(ReceivedData::ResponseTimeMs(response_time_ms)))) => {
trace!("Ping time estimated as: {} ms.", response_time_ms);
// record the response time
self.network_response_times_ms.push(response_time_ms);
// prune old response times. Keep at most three.
while self.network_response_times_ms.len() > 3 {
self.network_response_times_ms.remove(0);
}
// stats::median is experimental. So we calculate the median of up to three ourselves.
let ping_time_ms: usize = match self.network_response_times_ms.len() {
1 => self.network_response_times_ms[0] as usize,
2 => {
((self.network_response_times_ms[0]
+ self.network_response_times_ms[1])
/ 2) as usize
}
3 => {
let mut times = self.network_response_times_ms.clone();
times.sort();
times[1]
}
_ => unreachable!(),
};
// store our new estimate for everyone to see
self.shared
.ping_time_ms
.store(ping_time_ms, atomic::Ordering::Relaxed);
}
Ok(Async::Ready(Some(ReceivedData::Data(data)))) => {
self.output
.as_mut()
.unwrap()
.seek(SeekFrom::Start(data.offset as u64))
.unwrap();
self.output
.as_mut()
.unwrap()
.write_all(data.data.as_ref())
.unwrap();
let mut full = false;
{
let mut download_status = self.shared.download_status.lock().unwrap();
let received_range = Range::new(data.offset, data.data.len());
download_status.downloaded.add_range(&received_range);
self.shared.cond.notify_all();
if download_status.downloaded.contained_length_from_value(0)
>= self.shared.file_size
{
full = true;
}
drop(download_status);
}
if full {
self.finish();
return Ok(Async::Ready(()));
}
}
Ok(Async::NotReady) => {
return Ok(Async::NotReady);
}
Err(()) => unreachable!(),
}
}
}
fn poll_stream_loader_command_rx(&mut self) -> Poll<(), ()> {
loop {
match self.stream_loader_command_rx.poll() {
Ok(Async::Ready(None)) => {
return Ok(Async::Ready(()));
}
Ok(Async::Ready(Some(StreamLoaderCommand::Fetch(request)))) => {
self.download_range(request.start, request.length);
}
Ok(Async::Ready(Some(StreamLoaderCommand::RandomAccessMode()))) => {
*(self.shared.download_strategy.lock().unwrap()) =
DownloadStrategy::RandomAccess();
}
Ok(Async::Ready(Some(StreamLoaderCommand::StreamMode()))) => {
*(self.shared.download_strategy.lock().unwrap()) =
DownloadStrategy::Streaming();
}
Ok(Async::Ready(Some(StreamLoaderCommand::Close()))) => {
return Ok(Async::Ready(()));
}
Ok(Async::NotReady) => return Ok(Async::NotReady),
Err(()) => unreachable!(),
}
}
}
fn finish(&mut self) {
let mut output = self.output.take().unwrap();
let complete_tx = self.complete_tx.take().unwrap();
output.seek(SeekFrom::Start(0)).unwrap();
let _ = complete_tx.send(output);
}
}
impl Future for AudioFileFetch {
type Item = ();
type Error = ();
fn poll(&mut self) -> Poll<(), ()> {
match self.poll_stream_loader_command_rx() {
Ok(Async::NotReady) => (),
Ok(Async::Ready(_)) => {
return Ok(Async::Ready(()));
}
Err(()) => unreachable!(),
}
match self.poll_file_data_rx() {
Ok(Async::NotReady) => (),
Ok(Async::Ready(_)) => {
return Ok(Async::Ready(()));
}
Err(()) => unreachable!(),
}
if let DownloadStrategy::Streaming() = self.get_download_strategy() {
let number_of_open_requests = self
.shared
.number_of_open_requests
.load(atomic::Ordering::SeqCst);
let max_requests_to_send =
MAX_PREFETCH_REQUESTS - min(MAX_PREFETCH_REQUESTS, number_of_open_requests);
if max_requests_to_send > 0 {
let bytes_pending: usize = {
let download_status = self.shared.download_status.lock().unwrap();
download_status
.requested
.minus(&download_status.downloaded)
.len()
};
let ping_time_seconds =
0.001 * self.shared.ping_time_ms.load(atomic::Ordering::Relaxed) as f64;
let download_rate = self.session.channel().get_download_rate_estimate();
let desired_pending_bytes = max(
(PREFETCH_THRESHOLD_FACTOR
* ping_time_seconds
* self.shared.stream_data_rate as f64) as usize,
(FAST_PREFETCH_THRESHOLD_FACTOR * ping_time_seconds * download_rate as f64)
as usize,
);
if bytes_pending < desired_pending_bytes {
self.pre_fetch_more_data(
desired_pending_bytes - bytes_pending,
max_requests_to_send,
);
}
}
}
return Ok(Async::NotReady);
}
}
impl Read for AudioFileStreaming {
fn read(&mut self, output: &mut [u8]) -> io::Result<usize> {
let offset = self.position as usize;
if offset >= self.shared.file_size {
return Ok(0);
}
let length = min(output.len(), self.shared.file_size - offset);
let length_to_request = match *(self.shared.download_strategy.lock().unwrap()) {
DownloadStrategy::RandomAccess() => length,
DownloadStrategy::Streaming() => {
// Due to the read-ahead stuff, we potentially request more than the actual reqeust demanded.
let ping_time_seconds =
0.0001 * self.shared.ping_time_ms.load(atomic::Ordering::Relaxed) as f64;
let length_to_request = length
+ max(
(READ_AHEAD_DURING_PLAYBACK_SECONDS * self.shared.stream_data_rate as f64)
as usize,
(READ_AHEAD_DURING_PLAYBACK_ROUNDTRIPS
* ping_time_seconds
* self.shared.stream_data_rate as f64) as usize,
);
min(length_to_request, self.shared.file_size - offset)
}
};
let mut ranges_to_request = RangeSet::new();
ranges_to_request.add_range(&Range::new(offset, length_to_request));
let mut download_status = self.shared.download_status.lock().unwrap();
ranges_to_request.subtract_range_set(&download_status.downloaded);
ranges_to_request.subtract_range_set(&download_status.requested);
for range in ranges_to_request.iter() {
self.stream_loader_command_tx
.unbounded_send(StreamLoaderCommand::Fetch(range.clone()))
.unwrap();
}
if length == 0 {
return Ok(0);
}
let mut download_message_printed = false;
while !download_status.downloaded.contains(offset) {
if let DownloadStrategy::Streaming() = *self.shared.download_strategy.lock().unwrap() {
if !download_message_printed {
debug!("Stream waiting for download of file position {}. Downloaded ranges: {}. Pending ranges: {}", offset, download_status.downloaded, download_status.requested.minus(&download_status.downloaded));
download_message_printed = true;
}
}
download_status = self
.shared
.cond
.wait_timeout(download_status, Duration::from_millis(1000))
.unwrap()
.0;
}
let available_length = download_status
.downloaded
.contained_length_from_value(offset);
assert!(available_length > 0);
drop(download_status);
self.position = self.read_file.seek(SeekFrom::Start(offset as u64)).unwrap();
let read_len = min(length, available_length);
let read_len = self.read_file.read(&mut output[..read_len])?;
if download_message_printed {
debug!(
"Read at postion {} completed. {} bytes returned, {} bytes were requested.",
offset,
read_len,
output.len()
);
}
self.position += read_len as u64;
self.shared
.read_position
.store(self.position as usize, atomic::Ordering::Relaxed);
return Ok(read_len);
}
}
impl Seek for AudioFileStreaming {
fn seek(&mut self, pos: SeekFrom) -> io::Result<u64> {
self.position = self.read_file.seek(pos)?;
// Do not seek past EOF
self.shared
.read_position
.store(self.position as usize, atomic::Ordering::Relaxed);
Ok(self.position)
}
}
impl Read for AudioFile {
fn read(&mut self, output: &mut [u8]) -> io::Result<usize> {
match *self {
AudioFile::Cached(ref mut file) => file.read(output),
AudioFile::Streaming(ref mut file) => file.read(output),
}
}
}
impl Seek for AudioFile {
fn seek(&mut self, pos: SeekFrom) -> io::Result<u64> {
match *self {
AudioFile::Cached(ref mut file) => file.seek(pos),
AudioFile::Streaming(ref mut file) => file.seek(pos),
}
}
}