9680805bdb
The "encoder-setup" signal must also be emitted for the encoders used in discovery pipelines in order for the default settings to be applied. This otherwise meant that for instance the x264 encoder would use a 60 frames latency, greatly delaying startup. Part-of: <https://gitlab.freedesktop.org/gstreamer/gst-plugins-rs/-/merge_requests/1289> |
||
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.. | ||
examples | ||
gstwebrtc-api | ||
protocol | ||
signalling | ||
src | ||
build.rs | ||
Cargo.toml | ||
LICENSE-MPL-2.0 | ||
README.md |
webrtcsink and webrtcsrc
All-batteries included GStreamer WebRTC producer and consumer, that try their best to do The Right Thing™.
It also provides a flexible and all-purposes WebRTC signalling server (gst-webrtc-signalling-server) and a Javascript API (gstwebrtc-api) to produce and consume compatible WebRTC streams from a web browser.
Use case
The webrtcbin element in GStreamer is extremely flexible and powerful, but
using it can be a difficult exercise. When all you want to do is serve a fixed
set of streams to any number of consumers, webrtcsink
(which wraps
webrtcbin
internally) can be a useful alternative.
Features
webrtcsink
implements the following features:
-
Built-in signaller: when using the default signalling server, this element will perform signalling without requiring application interaction. This makes it usable directly from
gst-launch
. -
Application-provided signalling:
webrtcsink
can be instantiated by an application with a custom signaller. That signaller must be a GObject, and must implement theSignallable
interface as defined here. The default signaller can be used as an example.An example project is also available to use as a boilerplate for implementing and using a custom signaller.
-
Sandboxed consumers: when a consumer is added, its encoder / payloader / webrtcbin elements run in a separately managed pipeline. This provides a certain level of sandboxing, as opposed to having those elements running inside the element itself.
It is important to note that at this moment, encoding is not shared between consumers. While this is not on the roadmap at the moment, nothing in the design prevents implementing this optimization.
-
Congestion control: the element leverages transport-wide congestion control feedback messages in order to adapt the bitrate of individual consumers' video encoders to the available bandwidth.
-
Configuration: the level of user control over the element is slowly expanding, consult
gst-inspect-1.0
for more information on the available properties and signals. -
Packet loss mitigation: webrtcsink now supports sending protection packets for Forward Error Correction, modulating the amount as a function of the available bandwidth, and can honor retransmission requests. Both features can be disabled via properties.
It is important to note that full control over the individual elements used by
webrtcsink
is not on the roadmap, as it will act as a black box in that
respect, for example webrtcsink
wants to reserve control over the bitrate for
congestion control.
A signal is now available however for the application to provide the initial
configuration for the encoders webrtcsink
instantiates.
If more granular control is required, applications should use webrtcbin
directly, webrtcsink
will focus on trying to just do the right thing, although
it might expose more interfaces to guide and tune the heuristics it employs.
Building
Make sure to install the development packages for some codec libraries beforehand, such as libx264, libvpx and libopusenc, exact names depend on your distribution.
cargo build
Usage
Open three terminals. In the first one, run the signalling server:
WEBRTCSINK_SIGNALLING_SERVER_LOG=debug cargo run --bin gst-webrtc-signalling-server
In the second one, run a web browser client (can produce and consume streams):
cd gstwebrtc-api
npm install
npm start
In the third one, run a webrtcsink producer from a GStreamer pipeline:
export GST_PLUGIN_PATH=$PWD/target/debug:$GST_PLUGIN_PATH
gst-launch-1.0 webrtcsink name=ws meta="meta,name=gst-stream" videotestsrc ! ws. audiotestsrc ! ws.
The webrtcsink produced stream will appear in the former web page (automatically opened at https://localhost:9090) under the name "gst-stream", if you click on it you should see a test video stream and hear a test tone.
You can also produce WebRTC streams from the web browser and consume them with a GStreamer pipeline. Click on the "Start Capture" button and copy the "Client ID" value.
Then open a new terminal and run:
export GST_PLUGIN_PATH=$PWD/target/debug:$GST_PLUGIN_PATH
gst-launch-1.0 playbin uri=gstwebrtc://127.0.0.1:8443?peer-id=[Client ID]
Replacing the "peer-id" value with the previously copied "Client ID" value. You should see the playbin element opening a window and showing you the content produced by the web page.
Configuration
The webrtcsink element itself can be configured through its properties, see
gst-inspect-1.0 webrtcsink
for more information about that, in addition the
default signaller also exposes properties for configuring it, in
particular setting the signalling server address, those properties
can be accessed through the gst::ChildProxy
interface, for example
with gst-launch:
gst-launch-1.0 webrtcsink signaller::uri="ws://127.0.0.1:8443" ..
Enable 'navigation' a.k.a user interactivity with the content
webrtcsink
implements the GstNavigation
interface which allows interacting
with the content, for example move with your mouse, entering keys with the
keyboard, etc... On top of that a WebRTCDataChannel
based protocol has been
implemented and can be activated with the enable-data-channel-navigation=true
property. The gstwebrtc-api implements the protocol and you
can easily test this feature using the wpesrc
for example.
As an example, the following pipeline allows you to navigate the GStreamer documentation inside the video running within your web browser (at https://127.0.0.1:9090 if you followed previous steps in that readme):
gst-launch-1.0 wpesrc location=https://gstreamer.freedesktop.org/documentation/ ! queue ! webrtcsink enable-data-channel-navigation=true meta="meta,name=web-stream"
Testing congestion control
For the purpose of testing congestion in a reproducible manner, a simple tool has been used, it has been used on Linux exclusively but it is also documented as usable on MacOS too. Client web browser has to be launched on a separate machine on the LAN to test for congestion, although specific configurations may allow to run it on the same machine.
Testing procedure was:
-
identify the server machine network interface (e.g. with
ifconfig
on Linux) -
identify the client machine IP address (e.g. with
ifconfig
on Linux) -
start the various services as explained in the Usage section (use
GST_DEBUG=webrtcsink:7
to get detailed logs about congestion control) -
start playback in the client browser
-
Run a
comcast
command on the server machine, for instance:$HOME/go/bin/comcast --device=$SERVER_INTERFACE --target-bw 3000 --target-addr=$CLIENT_IP --target-port=1:65535 --target-proto=udp
-
Observe the bitrate sharply decreasing, playback should slow down briefly then catch back up
-
Remove the bandwidth limitation, and observe the bitrate eventually increasing back to a maximum:
$HOME/go/bin/comcast --device=$SERVER_INTERFACE --stop
For comparison, the congestion control property can be set to "disabled" on webrtcsink, then the above procedure applied again, the expected result is for playback to simply crawl down to a halt until the bandwidth limitation is lifted:
gst-launch-1.0 webrtcsink congestion-control=disabled
Monitoring tool
An example of client/server application for monitoring per-consumer stats can be found here.
License
All the rust code in this repository is licensed under the Mozilla Public License Version 2.0.
Code in gstwebrtc-api is also licensed under the Mozilla Public License Version 2.0.
Using the AWS KVS signaller
-
Setup AWS Kinesis Video Streams
-
Create a channel from the AWS console (https://us-east-1.console.aws.amazon.com/kinesisvideo/home?region=us-east-1#/signalingChannels/create)
-
Start a producer:
AWS_ACCESS_KEY_ID="XXX" AWS_SECRET_ACCESS_KEY="XXX" gst-launch-1.0 videotestsrc pattern=ball ! video/x-raw, width=1280, height=720 ! videoconvert ! textoverlay text="Hello from GStreamer!" ! videoconvert ! awskvswebrtcsink name=ws signaller::channel-name="XXX"
- Connect a viewer @ https://awslabs.github.io/amazon-kinesis-video-streams-webrtc-sdk-js/examples/index.html
Using the WHIP Signaller
Testing the whip signaller can be done by setting up janus and https://github.com/meetecho/simple-whip-server/.
-
Set up a janus instance with the videoroom plugin configured to expose a room with ID 1234 (configuration in
janus.plugin.videoroom.jcfg
) -
Open the <janus/share/janus/demos/videoroomtest.html> web page, click start and join the room
-
Set up the simple whip server as explained in its README
-
Navigate to http://localhost:7080/, create an endpoint named room1234 pointing to the Janus room with ID 1234
-
Finally, send a stream to the endpoint with:
gst-launch-1.0 -e uridecodebin uri=file:///home/meh/path/to/video/file ! \
videoconvert ! video/x-raw ! queue ! \
whipwebrtcsink name=ws signaller::whip-endpoint="http://127.0.0.1:7080/whip/endpoint/room1234"
You should see a second video displayed in the videoroomtest web page.
Using the LiveKit Signaller
Testing the LiveKit signaller can be done by setting up LiveKit and creating a room.
You can connect either by given the API key and secret:
gst-launch-1.0 -e uridecodebin uri=file:///home/meh/path/to/video/file ! \
videoconvert ! video/x-raw ! queue ! \
livekitwebrtcsink signaller::ws-url=ws://127.0.0.1:7880 signaller::api-key=devkey signaller::secret-key=secret signaller::room-name=testroom
Or by using a separately created authentication token
gst-launch-1.0 -e uridecodebin uri=file:///home/meh/path/to/video/file ! \
videoconvert ! video/x-raw ! queue ! \
livekitwebrtcsink signaller::ws-url=ws://127.0.0.1:7880 signaller::auth-token=mygeneratedtoken signaller::room-name=testroom
You should see a second video displayed in the videoroomtest web page.