Rust reader for MPEG2 Transport Stream data
Zero-copy access to payload data within an MPEG Transport Stream.
This crate,
- implements a low-level state machine that recognises the structural elements of Transport Stream syntax
- provides traits that you should implement to define your application-specific processing of the contained data.
This version also takes in consideration the end_packet callback for the lsat packet
Dump H264 payload data as hex.
#[macro_use]
extern crate mpeg2ts_reader;
extern crate hex_slice;
use hex_slice::AsHex;
use mpeg2ts_reader::demultiplex;
use mpeg2ts_reader::packet;
use mpeg2ts_reader::pes;
use mpeg2ts_reader::psi;
use mpeg2ts_reader::StreamType;
use std::cmp;
use std::env;
use std::fs::File;
use std::io::Read;
// This macro invocation creates an enum called DumpFilterSwitch, encapsulating all possible ways
// that this application may handle transport stream packets. Each enum variant is just a wrapper
// around an implementation of the PacketFilter trait
packet_filter_switch! {
DumpFilterSwitch<DumpDemuxContext> {
// the DumpFilterSwitch::Pes variant will perform the logic actually specific to this
// application,
Pes: pes::PesPacketFilter<DumpDemuxContext,PtsDumpElementaryStreamConsumer>,
// these definitions are boilerplate required by the framework,
Pat: demultiplex::PatPacketFilter<DumpDemuxContext>,
Pmt: demultiplex::PmtPacketFilter<DumpDemuxContext>,
// this variant will be used when we want to ignore data in the transport stream that this
// application does not care about
Null: demultiplex::NullPacketFilter<DumpDemuxContext>,
}
}
// This macro invocation creates a type called DumpDemuxContext, which is our application-specific
// implementation of the DemuxContext trait.
demux_context!(DumpDemuxContext, DumpFilterSwitch);
// When the de-multiplexing process needs to create a PacketFilter instance to handle a particular
// kind of data discovered within the Transport Stream being processed, it will send a
// FilterRequest to our application-specific implementation of the do_construct() method
impl DumpDemuxContext {
fn do_construct(&mut self, req: demultiplex::FilterRequest<'_, '_>) -> DumpFilterSwitch {
match req {
// The 'Program Association Table' is is always on PID 0. We just use the standard
// handling here, but an application could insert its own logic if required,
demultiplex::FilterRequest::ByPid(packet::Pid::PAT) => {
DumpFilterSwitch::Pat(demultiplex::PatPacketFilter::default())
}
// 'Stuffing' data on PID 0x1fff may be used to pad-out parts of the transport stream
// so that it has constant overall bitrate. This causes it to be ignored if present.
demultiplex::FilterRequest::ByPid(packet::Pid::STUFFING) => {
DumpFilterSwitch::Null(demultiplex::NullPacketFilter::default())
}
// Some Transport Streams will contain data on 'well known' PIDs, which are not
// announced in PAT / PMT metadata. This application does not process any of these
// well known PIDs, so we register NullPacketFiltet such that they will be ignored
demultiplex::FilterRequest::ByPid(_) => {
DumpFilterSwitch::Null(demultiplex::NullPacketFilter::default())
}
// This match-arm installs our application-specific handling for each H264 stream
// discovered within the transport stream,
demultiplex::FilterRequest::ByStream {
stream_type: StreamType::H264,
pmt,
stream_info,
..
} => PtsDumpElementaryStreamConsumer::construct(pmt, stream_info),
// We need to have a match-arm to specify how to handle any other StreamType values
// that might be present; we answer with NullPacketFilter so that anything other than
// H264 (handled above) is ignored,
demultiplex::FilterRequest::ByStream { .. } => {
DumpFilterSwitch::Null(demultiplex::NullPacketFilter::default())
}
// The 'Program Map Table' defines the sub-streams for a particular program within the
// Transport Stream (it is common for Transport Streams to contain only one program).
// We just use the standard handling here, but an application could insert its own
// logic if required,
demultiplex::FilterRequest::Pmt {
pid,
program_number,
} => DumpFilterSwitch::Pmt(demultiplex::PmtPacketFilter::new(pid, program_number)),
// Ignore 'Network Information Table', if present,
demultiplex::FilterRequest::Nit { .. } => {
DumpFilterSwitch::Null(demultiplex::NullPacketFilter::default())
}
}
}
}
// Implement the ElementaryStreamConsumer to just dump and PTS/DTS timestamps to stdout
pub struct PtsDumpElementaryStreamConsumer {
pid: packet::Pid,
len: Option<usize>,
}
impl PtsDumpElementaryStreamConsumer {
fn construct(
_pmt_sect: &psi::pmt::PmtSection,
stream_info: &psi::pmt::StreamInfo,
) -> DumpFilterSwitch {
let filter = pes::PesPacketFilter::new(PtsDumpElementaryStreamConsumer {
pid: stream_info.elementary_pid(),
len: None,
});
DumpFilterSwitch::Pes(filter)
}
}
impl pes::ElementaryStreamConsumer for PtsDumpElementaryStreamConsumer {
fn start_stream(&mut self) {}
fn begin_packet(&mut self, header: pes::PesHeader) {
match header.contents() {
pes::PesContents::Parsed(Some(parsed)) => {
match parsed.pts_dts() {
Ok(pes::PtsDts::PtsOnly(Ok(pts))) => {
print!("{:?}: pts {:#08x} ", self.pid, pts.value())
}
Ok(pes::PtsDts::Both {
pts: Ok(pts),
dts: Ok(dts),
}) => print!(
"{:?}: pts {:#08x} dts {:#08x} ",
self.pid,
pts.value(),
dts.value()
),
_ => (),
}
let payload = parsed.payload();
self.len = Some(payload.len());
println!(
"{:02x}",
payload[..cmp::min(payload.len(), 16)].plain_hex(false)
)
}
pes::PesContents::Parsed(None) => (),
pes::PesContents::Payload(payload) => {
self.len = Some(payload.len());
println!(
"{:?}: {:02x}",
self.pid,
payload[..cmp::min(payload.len(), 16)].plain_hex(false)
)
}
}
}
fn continue_packet(&mut self, data: &[u8]) {
println!(
"{:?}: continues {:02x}",
self.pid,
data[..cmp::min(data.len(), 16)].plain_hex(false)
);
self.len = self.len.map(|l| l + data.len());
}
fn end_packet(&mut self) {
println!("{:?}: end of packet length={:?}", self.pid, self.len);
}
fn continuity_error(&mut self) {}
}
fn main() {
// open input file named on command line,
let name = env::args().nth(1).unwrap();
let mut f = File::open(&name).expect(&format!("file not found: {}", &name));
// create the context object that stores the state of the transport stream demultiplexing
// process
let mut ctx = DumpDemuxContext::new();
// create the demultiplexer, which will use the ctx to create a filter for pid 0 (PAT)
let mut demux = demultiplex::Demultiplex::new(&mut ctx);
// consume the input file,
let mut buf = [0u8; 188 * 1024];
loop {
match f.read(&mut buf[..]).expect("read failed") {
0 => break,
n => demux.push(&mut ctx, &buf[0..n]),
}
}
}
Comparing this crate to a couple of others which you might use to read a Transport Stream -- mpeg2ts and ffmpg-sys:
The benchmarks producing the above chart data are in the shootout
folder. (If the benchmarks are giving
an unfair representation of relative performance, that's a mistake -- please raise a bug!)
The conditions of the test are,
- the data is already in memory (no network/disk access)
- test dataset is larger than CPU cache
- processing is happening on a single core (no multiprocessing of the stream).
Not all Transport Stream features are supported yet. Here's a summary of what's available, and what's yet to come:
- Framing
- ISO/IEC 13818-1 188-byte packets
- m2ts 192-byte packets (would be nice if an external crate could support, at least)
- recovery after loss of synchronisation
- Transport Stream packet
- Fixed headers
- Adaptation field
- TS-level scrambling (values of
transport_scrambling_control
other than0
) not supported
- Program Specific Information tables
- Section syntax
- 'Multi-section' tables
- PAT - Program Association Table
- PMT - Program Mapping Table
- TSDT - Transport Stream Description Table
- Packetised Elementary Stream syntax
- PES_packet_data
- PTS/DTS
- ESCR
- ES_rate
- DSM_trick_mode
- additional_copy_info
- PES_CRC
- PES_extension
- Descriptors
- video_stream_descriptor
- audio_stream_descriptor
- hierarchy_descriptor
- registration_descriptor
- data_stream_alignment_descriptor
- target_background_grid_descriptor
- video_window_descriptor
- ca_descriptor
- iso_639_language_descriptor
- system_clock_descriptor
- multiplex_buffer_utilization_descriptor
- copyright_descriptor
- maximum_bitrate_descriptor
- private_data_indicator_descriptor
- smoothing_buffer_descriptor
- std_descriptor
- ibp_descriptor
- mpeg4_video_descriptor
- mpeg4_audio_descriptor
- iod_descriptor
- sl_descriptor
- fmc_descriptor
- external_es_id_descriptor
- muxcode_descriptor
- fmxbuffersize_descriptor
- multiplexbuffer_descriptor
- AVC_video_descriptor