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//! DiscStream — read any disc (physical drive or ISO file) → PES frames.
//!
//! One stream type for all disc sources. The source is a SectorReader —
//! Drive (hardware) or IsoSectorReader (file). DiscStream doesn't care.
//!
//! Read-only. For disc→ISO (raw sector copy), use `Disc::copy()`.
use crate::disc::{Disc, DiscTitle, Extent};
use crate::event::{Event, EventKind};
use crate::sector::SectorReader;
use std::io;
/// Disc stream. Reads sectors from any source → PES frames.
///
/// Sources: physical drive, ISO file, or any SectorReader.
/// Decrypt, demux, and codec parsing happen internally.
pub struct DiscStream {
reader: Box<dyn SectorReader>,
title: DiscTitle,
disc: Option<Disc>,
decrypt_keys: crate::decrypt::DecryptKeys,
// Extents to read
extents: Vec<Extent>,
// Position
current_extent: usize,
current_offset: u32,
// Buffer
read_buf: Vec<u8>,
buf_valid: usize,
// Batch size for reads
batch_sectors: u16,
pub errors: u64,
pub skip_errors: bool,
event_fn: Option<Box<dyn Fn(Event) + Send>>,
eof: bool,
// PES output
ts_demuxer: Option<super::ts::TsDemuxer>,
ps_demuxer: Option<super::ps::PsDemuxer>,
parsers: Vec<(u16, Box<dyn super::codec::CodecParser>)>,
pending_frames: std::collections::VecDeque<crate::pes::PesFrame>,
pid_to_track: Vec<(u16, usize)>,
}
impl DiscStream {
/// Create a disc stream from any sector reader.
///
/// Works with physical drives and ISO files — both implement SectorReader.
/// The caller opens the source, scans for titles/keys, and passes them in.
/// The stream handles demuxing, decryption, and codec parsing internally.
pub fn new(
reader: Box<dyn SectorReader>,
title: DiscTitle,
decrypt_keys: crate::decrypt::DecryptKeys,
batch_sectors: u16,
content_format: crate::disc::ContentFormat,
) -> Self {
let extents = title.extents.clone();
let mut pids = Vec::new();
let mut parsers = Vec::new();
let mut pid_to_track = Vec::new();
for (idx, s) in title.streams.iter().enumerate() {
let (pid, codec) = match s {
crate::disc::Stream::Video(v) => (v.pid, v.codec),
crate::disc::Stream::Audio(a) => (a.pid, a.codec),
crate::disc::Stream::Subtitle(s) => (s.pid, s.codec),
};
pids.push(pid);
pid_to_track.push((pid, idx));
parsers.push((pid, super::codec::parser_for_codec(codec, None)));
}
let mut ts_demuxer = None;
let mut ps_demuxer = None;
match content_format {
crate::disc::ContentFormat::MpegPs => {
ps_demuxer = Some(super::ps::PsDemuxer::new());
}
crate::disc::ContentFormat::BdTs => {
let ts_pids: Vec<u16> = pids.clone();
if !ts_pids.is_empty() {
ts_demuxer = Some(super::ts::TsDemuxer::new(&ts_pids));
}
}
}
Self {
reader,
title,
disc: None,
decrypt_keys,
extents,
current_extent: 0,
current_offset: 0,
read_buf: Vec::with_capacity(batch_sectors as usize * 2048),
buf_valid: 0,
batch_sectors,
errors: 0,
skip_errors: false,
event_fn: None,
eof: false,
ts_demuxer,
ps_demuxer,
parsers,
pending_frames: std::collections::VecDeque::new(),
pid_to_track,
}
}
/// Set event handler for sector-level events (binary search, skip, recover).
pub fn on_event(&mut self, f: impl Fn(Event) + Send + 'static) {
self.event_fn = Some(Box::new(f));
}
fn emit(&self, kind: EventKind) {
if let Some(ref f) = self.event_fn {
f(Event { kind });
}
}
/// Skip decryption — return raw encrypted bytes.
pub fn set_raw(&mut self) {
self.decrypt_keys = crate::decrypt::DecryptKeys::None;
}
/// Get the scanned Disc (for listing all titles).
pub fn disc(&self) -> Option<&Disc> {
self.disc.as_ref()
}
/// Binary search to isolate failing sectors within a batch.
/// Good sub-batches read fast. Bad sectors get 3 retries × 5s — max 15s per sector.
/// No full Drive::read() recovery — that only runs on the initial batch attempt.
fn read_with_binary_search(&mut self, lba: u32, count: u16) -> io::Result<()> {
if count <= 1 {
// Single sector — light recovery: 3 attempts, 5s sleep between
let offset = self.buf_valid;
for attempt in 0..3u32 {
if attempt > 0 {
std::thread::sleep(std::time::Duration::from_secs(5));
}
if self
.reader
.read_sectors(lba, 1, &mut self.read_buf[offset..offset + 2048], false)
.is_ok()
{
self.emit(EventKind::SectorRecovered { sector: lba as u64 });
self.buf_valid += 2048;
return Ok(());
}
}
// 3 attempts failed
if self.skip_errors {
self.emit(EventKind::SectorSkipped { sector: lba as u64 });
self.read_buf[offset..offset + 2048].fill(0);
self.buf_valid += 2048;
self.errors += 1;
return Ok(());
} else {
return Err(crate::error::Error::DiscRead { sector: lba as u64 }.into());
}
}
// Try this sub-batch as a whole (fast read, no recovery)
let bytes = count as usize * 2048;
let offset = self.buf_valid;
if self
.reader
.read_sectors(
lba,
count,
&mut self.read_buf[offset..offset + bytes],
false,
)
.is_ok()
{
self.buf_valid += bytes;
return Ok(());
}
// Sub-batch failed — split in half and recurse
self.emit(EventKind::BinarySearch {
sector: lba as u64,
batch_size: count,
});
let half = count / 2;
let half = half - (half % 3).min(half);
let half = half.max(1);
let remainder = count - half;
self.read_with_binary_search(lba, half)?;
if remainder > 0 {
self.read_with_binary_search(lba + half as u32, remainder)?;
}
Ok(())
}
fn fill_extents(&mut self) -> io::Result<bool> {
if self.current_extent >= self.extents.len() {
return Ok(false);
}
let ext_start = self.extents[self.current_extent].start_lba;
let ext_sectors = self.extents[self.current_extent].sector_count;
let remaining = ext_sectors.saturating_sub(self.current_offset);
if remaining == 0 {
self.current_extent += 1;
self.current_offset = 0;
return self.fill_extents();
}
let mut sectors = remaining.min(self.batch_sectors as u32) as u16;
// Align to 3-sector AACS units when possible, but never drop
// trailing sectors at extent boundaries. decrypt_sectors() safely
// skips partial units (chunks shorter than ALIGNED_UNIT_LEN).
if sectors >= 3 {
sectors -= sectors % 3;
}
let lba = ext_start + self.current_offset;
let bytes = sectors as usize * 2048;
self.read_buf.resize(bytes, 0);
if self
.reader
.read_sectors(lba, sectors, &mut self.read_buf[..bytes], false)
.is_ok()
{
// Fast path: batch succeeded
self.buf_valid = bytes;
} else {
// Batch failed fast — binary search to isolate bad sectors.
// Light recovery only (3x5s per sector, no full Drive::read).
self.buf_valid = 0;
self.read_with_binary_search(lba, sectors)?;
}
self.current_offset += sectors as u32;
if self.current_offset >= ext_sectors {
self.current_extent += 1;
self.current_offset = 0;
}
Ok(true)
}
}
impl crate::pes::Stream for DiscStream {
fn read(&mut self) -> io::Result<Option<crate::pes::PesFrame>> {
if let Some(frame) = self.pending_frames.pop_front() {
return Ok(Some(frame));
}
if self.eof {
return Ok(None);
}
loop {
if !self.fill_extents()? {
self.eof = true;
// Flush demuxer — last PES packet may still be in the assembler
if let Some(ref mut demuxer) = self.ts_demuxer {
for pes in &demuxer.flush() {
if let Some((_, track)) =
self.pid_to_track.iter().find(|(pid, _)| *pid == pes.pid)
{
if let Some((_, parser)) =
self.parsers.iter_mut().find(|(pid, _)| *pid == pes.pid)
{
for frame in parser.parse(pes) {
self.pending_frames.push_back(
crate::pes::PesFrame::from_codec_frame(*track, frame),
);
}
}
}
}
}
// PS demuxer flush (DVD)
if let Some(ref mut demuxer) = self.ps_demuxer {
for ps in &demuxer.flush() {
let track = match ps.stream_id {
0xE0..=0xEF => 0,
0xC0..=0xDF => 1,
0xBD => ps
.sub_stream_id
.map(|s| (s & 0x1F) as usize + 1)
.unwrap_or(1),
_ => continue,
};
if track >= self.title.streams.len() {
continue;
}
let pid = self
.pid_to_track
.iter()
.find(|(_, idx)| *idx == track)
.map(|(p, _)| *p)
.unwrap_or(0);
let pes = super::ts::PesPacket {
pid,
pts: ps.pts.map(|p| p as i64),
dts: ps.dts.map(|d| d as i64),
data: ps.data.clone(),
};
if let Some((_, parser)) = self.parsers.iter_mut().find(|(p, _)| *p == pid)
{
for frame in parser.parse(&pes) {
self.pending_frames.push_back(
crate::pes::PesFrame::from_codec_frame(track, frame),
);
}
}
}
}
return Ok(self.pending_frames.pop_front());
}
let bytes = self.buf_valid;
if let Err(e) =
crate::decrypt::decrypt_sectors(&mut self.read_buf[..bytes], &self.decrypt_keys, 0)
{
return Err(e.into());
}
if let Some(ref mut demuxer) = self.ts_demuxer {
let packets = demuxer.feed(&self.read_buf[..bytes]);
for pes in &packets {
if let Some((_, track)) =
self.pid_to_track.iter().find(|(pid, _)| *pid == pes.pid)
{
if let Some((_, parser)) =
self.parsers.iter_mut().find(|(pid, _)| *pid == pes.pid)
{
for frame in parser.parse(pes) {
self.pending_frames.push_back(
crate::pes::PesFrame::from_codec_frame(*track, frame),
);
}
}
}
}
} else if let Some(ref mut demuxer) = self.ps_demuxer {
let packets = demuxer.feed(&self.read_buf[..bytes]);
for ps in &packets {
let track = match ps.stream_id {
0xE0..=0xEF => 0,
0xC0..=0xDF => 1,
0xBD => ps
.sub_stream_id
.map(|s| (s & 0x1F) as usize + 1)
.unwrap_or(1),
_ => continue,
};
if track >= self.title.streams.len() {
continue;
}
// Convert PsPacket to PesPacket for codec parser (same as BD-TS path)
let pid = self
.pid_to_track
.iter()
.find(|(_, idx)| *idx == track)
.map(|(p, _)| *p)
.unwrap_or(0);
let pes = super::ts::PesPacket {
pid,
pts: ps.pts.map(|p| p as i64),
dts: ps.dts.map(|d| d as i64),
data: ps.data.clone(),
};
if let Some((_, parser)) = self.parsers.iter_mut().find(|(p, _)| *p == pid) {
for frame in parser.parse(&pes) {
self.pending_frames
.push_back(crate::pes::PesFrame::from_codec_frame(track, frame));
}
}
}
}
self.buf_valid = 0;
if let Some(frame) = self.pending_frames.pop_front() {
return Ok(Some(frame));
}
}
}
fn write(&mut self, _frame: &crate::pes::PesFrame) -> io::Result<()> {
Err(crate::error::Error::StreamReadOnly.into())
}
fn finish(&mut self) -> io::Result<()> {
Ok(())
}
fn info(&self) -> &DiscTitle {
&self.title
}
fn codec_private(&self, track: usize) -> Option<Vec<u8>> {
let pid = self
.pid_to_track
.iter()
.find(|(_, idx)| *idx == track)
.map(|(pid, _)| *pid)?;
self.parsers
.iter()
.find(|(p, _)| *p == pid)
.and_then(|(_, parser)| parser.codec_private())
}
fn headers_ready(&self) -> bool {
for (idx, s) in self.title.streams.iter().enumerate() {
if let crate::disc::Stream::Video(v) = s {
if !v.secondary && self.codec_private(idx).is_none() {
return false;
}
}
}
true
}
}