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# webrtcsink and webrtcsrc
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All-batteries included GStreamer WebRTC producer and consumer, that try their
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best to do The Right Thing™.
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It also provides a flexible and all-purposes WebRTC signalling server
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([gst-webrtc-signalling-server](signalling/src/bin/server.rs)) and a Javascript
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API ([gstwebrtc-api](gstwebrtc-api)) to produce and consume compatible WebRTC
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streams from a web browser.
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## Use case
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The [webrtcbin] element in GStreamer is extremely flexible and powerful, but
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using it can be a difficult exercise. When all you want to do is serve a fixed
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set of streams to any number of consumers, `webrtcsink` (which wraps
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`webrtcbin` internally) can be a useful alternative.
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[webrtcbin]: https://gstreamer.freedesktop.org/documentation/webrtc/index.html
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## Features
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`webrtcsink` implements the following features:
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* Built-in signaller: when using the default signalling server, this element
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will perform signalling without requiring application interaction.
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This makes it usable directly from `gst-launch`.
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* Application-provided signalling: `webrtcsink` can be instantiated by an
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application with a custom signaller. That signaller must be a GObject, and
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must implement the `Signallable` interface as defined
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[here](src/webrtcsink/mod.rs). The [default signaller](src/signaller/mod.rs)
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can be used as an example.
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An [example project] is also available to use as a boilerplate for
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implementing and using a custom signaller.
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* Sandboxed consumers: when a consumer is added, its encoder / payloader /
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webrtcbin elements run in a separately managed pipeline. This provides a
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certain level of sandboxing, as opposed to having those elements running
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inside the element itself.
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It is important to note that at this moment, encoding is not shared between
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consumers. While this is not on the roadmap at the moment, nothing in the
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design prevents implementing this optimization.
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* Congestion control: the element leverages transport-wide congestion control
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feedback messages in order to adapt the bitrate of individual consumers' video
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encoders to the available bandwidth.
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* Configuration: the level of user control over the element is slowly expanding,
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consult `gst-inspect-1.0` for more information on the available properties and
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signals.
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* Packet loss mitigation: webrtcsink now supports sending protection packets for
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Forward Error Correction, modulating the amount as a function of the available
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bandwidth, and can honor retransmission requests. Both features can be
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disabled via properties.
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It is important to note that full control over the individual elements used by
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`webrtcsink` is *not* on the roadmap, as it will act as a black box in that
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respect, for example `webrtcsink` wants to reserve control over the bitrate for
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congestion control.
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A signal is now available however for the application to provide the initial
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configuration for the encoders `webrtcsink` instantiates.
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If more granular control is required, applications should use `webrtcbin`
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directly, `webrtcsink` will focus on trying to just do the right thing, although
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it might expose more interfaces to guide and tune the heuristics it employs.
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2021-12-20 23:32:51 +00:00
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[example project]: https://github.com/centricular/webrtcsink-custom-signaller
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## Building
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> Make sure to install the development packages for some codec libraries
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> beforehand, such as libx264, libvpx and libopusenc, exact names depend
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> on your distribution.
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``` shell
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cargo build
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```
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## Usage
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Open three terminals. In the first one, run the signalling server:
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``` shell
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cd signalling
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WEBRTCSINK_SIGNALLING_SERVER_LOG=debug cargo run --bin gst-webrtc-signalling-server
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```
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In the second one, run a web browser client (can produce and consume streams):
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``` shell
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cd gstwebrtc-api
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npm install
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npm start
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```
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In the third one, run a webrtcsink producer from a GStreamer pipeline:
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``` shell
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export GST_PLUGIN_PATH=<path-to-gst-plugins-rs>/target/debug:$GST_PLUGIN_PATH
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gst-launch-1.0 webrtcsink name=ws meta="meta,name=gst-stream" videotestsrc ! ws. audiotestsrc ! ws.
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```
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The webrtcsink produced stream will appear in the former web page
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(automatically opened at https://localhost:9090) under the name "gst-stream",
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if you click on it you should see a test video stream and hear a test tone.
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You can also produce WebRTC streams from the web browser and consume them with
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a GStreamer pipeline. Click on the "Start Capture" button and copy the
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"Client ID" value.
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Then open a new terminal and run:
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``` shell
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export GST_PLUGIN_PATH=<path-to-gst-plugins-rs>/target/debug:$GST_PLUGIN_PATH
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gst-launch-1.0 playbin uri=gstwebrtc://127.0.0.1:8443?peer-id=[Client ID]
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```
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Replacing the "peer-id" value with the previously copied "Client ID" value. You
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should see the playbin element opening a window and showing you the content
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produced by the web page.
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## Configuration
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The webrtcsink element itself can be configured through its properties, see
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`gst-inspect-1.0 webrtcsink` for more information about that, in addition the
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default signaller also exposes properties for configuring it, in
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particular setting the signalling server address, those properties
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can be accessed through the `gst::ChildProxy` interface, for example
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with gst-launch:
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``` shell
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gst-launch-1.0 webrtcsink signaller::uri="ws://127.0.0.1:8443" ..
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```
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### Enable 'navigation' a.k.a user interactivity with the content
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`webrtcsink` implements the [`GstNavigation`] interface which allows interacting
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with the content, for example move with your mouse, entering keys with the
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keyboard, etc... On top of that a `WebRTCDataChannel` based protocol has been
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implemented and can be activated with the `enable-data-channel-navigation=true`
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property allowing a client to send GstNavigation events using the WebRTC data channel.
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The [gstwebrtc-api](gstwebrtc-api) and `webrtcsrc` implement the protocol as well
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and they can be used as a client to control a remote sever.
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You can easily test this feature using the [`wpesrc`] element with the following pipeline
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that will start a server that allows you to navigate the GStreamer documentation:
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``` shell
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gst-launch-1.0 wpesrc location=https://gstreamer.freedesktop.org/documentation/ ! queue ! webrtcsink enable-data-channel-navigation=true meta="meta,name=web-stream"
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```
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You can control it inside the video running within your web browser (at
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https://127.0.0.1:9090 if you followed previous steps in that readme) or
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with the following GSteamer pipeline as a client:
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``` shell
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gst-launch-1.0 webrtcsrc signaller::producer-peer-id=<webrtcsink-peer-id> enable-data-channel-navigation=true ! videoconvert ! autovideosink
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```
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2021-12-24 12:26:26 +00:00
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[`GstNavigation`]: https://gstreamer.freedesktop.org/documentation/video/gstnavigation.html
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[`wpesrc`]: https://gstreamer.freedesktop.org/documentation/wpe/wpesrc.html
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2021-11-04 17:26:50 +00:00
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## Testing congestion control
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For the purpose of testing congestion in a reproducible manner, a
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[simple tool] has been used, it has been used on Linux exclusively but it is
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also documented as usable on MacOS too. Client web browser has to be launched
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on a separate machine on the LAN to test for congestion, although specific
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configurations may allow to run it on the same machine.
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Testing procedure was:
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* identify the server machine network interface (e.g. with `ifconfig` on Linux)
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* identify the client machine IP address (e.g. with `ifconfig` on Linux)
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* start the various services as explained in the Usage section (use
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`GST_DEBUG=webrtcsink:7` to get detailed logs about congestion control)
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* start playback in the client browser
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* Run a `comcast` command on the server machine, for instance:
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``` shell
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$HOME/go/bin/comcast --device=$SERVER_INTERFACE --target-bw 3000 --target-addr=$CLIENT_IP --target-port=1:65535 --target-proto=udp
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```
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* Observe the bitrate sharply decreasing, playback should slow down briefly
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then catch back up
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* Remove the bandwidth limitation, and observe the bitrate eventually increasing
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back to a maximum:
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``` shell
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$HOME/go/bin/comcast --device=$SERVER_INTERFACE --stop
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```
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For comparison, the congestion control property can be set to "disabled" on
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webrtcsink, then the above procedure applied again, the expected result is
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for playback to simply crawl down to a halt until the bandwidth limitation
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is lifted:
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``` shell
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gst-launch-1.0 webrtcsink congestion-control=disabled
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```
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[simple tool]: https://github.com/tylertreat/comcast
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2021-12-09 23:06:46 +00:00
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## Monitoring tool
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An example of client/server application for monitoring per-consumer stats
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can be found [here].
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[here]: https://gitlab.freedesktop.org/gstreamer/gst-plugins-rs/-/tree/main/net/webrtc/examples
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## License
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All the rust code in this repository is licensed under the
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[Mozilla Public License Version 2.0].
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Code in [gstwebrtc-api](gstwebrtc-api) is also licensed under the
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[Mozilla Public License Version 2.0].
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2023-04-06 22:41:16 +00:00
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[Mozilla Public License Version 2.0]: http://opensource.org/licenses/MPL-2.0
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2023-03-01 23:01:43 +00:00
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## Using the AWS KVS signaller
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* Setup AWS Kinesis Video Streams
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* Create a channel from the AWS console (<https://us-east-1.console.aws.amazon.com/kinesisvideo/home?region=us-east-1#/signalingChannels/create>)
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* Start a producer:
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```
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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"
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```
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* Connect a viewer @ <https://awslabs.github.io/amazon-kinesis-video-streams-webrtc-sdk-js/examples/index.html>
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2023-04-06 22:41:16 +00:00
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## Using the WHIP Signaller
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Testing the whip signaller can be done by setting up janus and
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<https://github.com/meetecho/simple-whip-server/>.
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* Set up a [janus] instance with the videoroom plugin configured
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to expose a room with ID 1234 (configuration in `janus.plugin.videoroom.jcfg`)
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* Open the <janus/share/janus/demos/videoroomtest.html> web page, click start
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and join the room
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* Set up the [simple whip server] as explained in its README
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* Navigate to <http://localhost:7080/>, create an endpoint named room1234
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pointing to the Janus room with ID 1234
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* Finally, send a stream to the endpoint with:
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``` shell
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gst-launch-1.0 -e uridecodebin uri=file:///home/meh/path/to/video/file ! \
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videoconvert ! video/x-raw ! queue ! \
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whipwebrtcsink name=ws signaller::whip-endpoint="http://127.0.0.1:7080/whip/endpoint/room1234"
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```
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You should see a second video displayed in the videoroomtest web page.
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2023-06-21 19:54:00 +00:00
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## Using the LiveKit Signaller
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Testing the LiveKit signaller can be done by setting up [LiveKit] and creating a room.
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You can connect either by given the API key and secret:
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``` shell
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gst-launch-1.0 -e uridecodebin uri=file:///home/meh/path/to/video/file ! \
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videoconvert ! video/x-raw ! queue ! \
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livekitwebrtcsink signaller::ws-url=ws://127.0.0.1:7880 signaller::api-key=devkey signaller::secret-key=secret signaller::room-name=testroom
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```
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Or by using a separately created authentication token
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``` shell
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gst-launch-1.0 -e uridecodebin uri=file:///home/meh/path/to/video/file ! \
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videoconvert ! video/x-raw ! queue ! \
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livekitwebrtcsink signaller::ws-url=ws://127.0.0.1:7880 signaller::auth-token=mygeneratedtoken signaller::room-name=testroom
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```
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You should see a second video displayed in the videoroomtest web page.
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[LiveKit]: https://livekit.io/
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2023-04-06 22:41:16 +00:00
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[janus]: https://github.com/meetecho/janus-gateway
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[simple whip server]: https://github.com/meetecho/simple-whip-server/
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