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Exposes Google's implementation of WebRTC to ROS. It consists of 2 ROS nodes:

  • ros_webrtc_host
  • ros_webrtc_rosbridge

a Python library ros_webrtc to help you write your own Python based ROS WebRTC apps and 2 example ROS nodes:

  • ros_webrtc_example
  • ros_webrtc_signaling

which show how everything fits together.

dev

Get it:

~/code$ git clone [email protected]:MayfieldRoboticsPublic/ros-webrtc.git

generate a project if you want, e.g. for Eclipse CDT do:

~/code$ mkdir ros-webrtc-project
~/code$ cd ros-webrtc-project
~/code/ros-webrtc-project$ cmake -G"Eclipse CDT4 - Unix Makefiles" -D CMAKE_BUILD_TYPE=Debug ../ros-webrtc/

and setup a catkin workspace using ansible:

~$ cd ~/code/ros-webrtc/test/provision
~/code/ros-webrtc/test/provision$ ansible-galaxy install -r requirements.yml
~/code/ros-webrtc/test/provision$ ansible-playbook -i 'localhost,' -c local -K dev.yml

or use vagrant:

~$ cd ~/code/ros-webrtc
~/code/ros-webrtc$ vagrant up

test

~/code/ros-webrtc/test/provision$ cd ~/tmp/ros-webrtc-ws
~/tmp/ros-webrtc-ws$ source devel/setup.bash
~/tmp/ros-webrtc-ws$ catkin_make run_tests

and if you want compiled code coverage:

~/tmp/ros-webrtc-ws$ catkin_make -DCMAKE_BUILD_TYPE=Debug -DCOVERAGE=ON
~/tmp/ros-webrtc-ws$ catkin_make run_tests

then use e.g. lcov to view the results:

~/tmp/ros-webrtc-ws$ lcov --path . --directory . --capture --no-external --output-file coverage.info
~/tmp/ros-webrtc-ws$ lcov --remove coverage.info 'devel/*' 'test/*' --output-file coverage.info
~/tmp/ros-webrtc-ws$ lcov --list coverage.info

demo

Let's walkthrough an example. Start by launching the demo:

~$ cd ~/tmp/ros-webrtc-ws
~/tmp/ros-webrtc-ws$ source devel/setup.bash
~/tmp/ros-webrtc-ws$ roslaunch ros_webrtc ros_webrtc.launch
...

If your webcam is somewhere other than /dev/video0 (e.g. /dev/video2) set that when launching:

~/tmp/ros-webrtc-ws$ ROS_WEBRTC_WEBCAM=id:///dev/video2 roslaunch ros_webrtc ros_webrtc.launch

This all leaves you with a few ros_webrtc nodes:

~/tmp/ros-webrtc-ws$ rosnode list
/ros_webrtc/host
/ros_webrtc_example/example
/ros_webrtc_example/signaling
/rosout

/ros_webrtc/host

This ros_webrtc_host instance exposes a build of Google's implementation of WebRTC to ROS using an interface similar to the one exposed to browsers.

So to e.g. create an RTCPeerConnection you'd use this ros_webrtc_host ROS service:

~/tmp/ros-webrtc-ws$ rosservice info /ros_webrtc/create_peer_connection
Node: /ros_webrtc/host
URI: rosrpc://ai-gazelle:34929
Type: ros_webrtc/CreatePeerConnection
Args: session_id peer_id sdp_constraints video_sources audio_sources

which has type ros_webrtc/CreatePeerConnection:

~/tmp/ros-webrtc-ws$ rossrv info ros_webrtc/CreatePeerConnection
rossrv show ros_webrtc/CreatePeerConnection
string session_id
string peer_id
ros_webrtc/MediaConstraints sdp_constraints
  ros_webrtc/Constraint[] mandatory
    string key
    string value
  ros_webrtc/Constraint[] optional
    string key
    string value
string[] video_sources
string[] audio_sources
---

/ros_webrtc_example/signaling

Initiating a peer connection and negotiating how and what to send over it is referred to as signaling in WebRTC. You can do that anyway you like (e.g. an internet facing pub/sub service) as long that the peer's can send each other signaling messages.

The example ROS node ros_webrtc_signaling is a simple WebSocket sever that does that and is suitable for testing. The peers (e.g. a browser and a ros_webrtc_example ROS node) will both connect to ros_webrtc_signaling and exchange signaling messages.

Just as the browser RTCPeerConnection has no knowledge of signaling, neither does ros_webrtc_host.

/ros_webrtc_example/example

A ros_webrtc_example ROS node intended to show how ROS WebRTC app might be implemented using helpers from the ros_webrtc Python library.

It connects to signaling and can be called by another peer. In that case a signaling message will be received from the other peer via signaling.

Alternatively ros_webrtc_example can call another peer. In that case signaling message will be sent from the other peer via signaling.

/ros_webrtc/rosbridge_*

You shouldn't see instances of the ros_webrtc_rosbridge ROS node yet as they tunnel the ROS protocol over an RTCDataChannel using rosbridge.

test site

In another terminal serve the test site which we'll use later to setup a peer connection between the browser and ros_webrtc:

~$ cd ~/code/ros-webrtc/test/fixtures/site
~/code/ros-webrtc/test/fixtures/site$ grunt clean build connect watch
...

connect!

Finally, it's time to connect. Let start by initiating a peer connection to ros_webrtc_example from a compatible browser using the test site:

http://localhost:8080/#cd0bdd0b147c4ba4bea16ca3cb35c140/call/{host-name}

where:

  • cd0bdd0b147c4ba4bea16ca3cb35c140 is a random identifier for the browser
  • {host-name} is the host name of your local machine (e.g. whatever $ hostname prints).

Once the connection is established ros_webrtc_host will list it:

~/tmp/ros-webrtc-ws$ rosservice call /ros_webrtc/get_host
...
peer_connections:
  -
    session_id: 9eb17a42bbf947649f3b92f24fc7b88c
    peer_id: cd0bdd0b147c4ba4bea16ca3cb35c140
...

Notice that a peer connection is identified by 2 values:

  • a session_id and
  • a peer_id

We also have a new ros_webrtc_rosbridge node instance:

~/tmp/ros-webrtc-ws$ rosnode list /ros_webrtc
...
/ros_webrtc/rosbridge_9eb17a42bbf947649f3b92f24fc7b88c_rosbridge_cd0bdd0b147c4ba4bea16ca3cb35c140
...

which is tunneling the ROS protocol over this peer connection's rosbridge data channel . We also have a bunch of new peer connection specific service advertised by ros_webrtc_example:

~/tmp/ros-webrtc-ws$ rosservice list /ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_add_stream
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_close
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_data_channel
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_ice_candidate
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_ice_connection_state_change
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_negotiation_needed
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_remove_stream
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_set_session_description
/ros_webrtc_example/example/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/on_signaling_state_change

and invoked by ros_webrtc_host as calbacks which mirror RTCPeerConnection event handlers. Note also that these events are also published to topics which you can monitor:

~/tmp/ros-webrtc-ws$ rostopic list /ros_webrtc/
/ros_webrtc/add_stream
/ros_webrtc/chatter
/ros_webrtc/close
/ros_webrtc/data_channel
/ros_webrtc/ice_candidate
/ros_webrtc/ice_connection_state_change
/ros_webrtc/local/webcam
/ros_webrtc/negotiation_needed
/ros_webrtc/peer_connection_bond
/ros_webrtc/remove_stream
/ros_webrtc/session_aa2f63408bb444508d68bc8a60dae20c/peer_cd0bdd0b147c4ba4bea16ca3cb35c140/data_rosbridge
/ros_webrtc/set_session_description
/ros_webrtc/signaling_state_change

We can reverse the direction of the call and have ros_webrtc_example call the browser. Change the browser to:

http://localhost:8080/#cd0bdd0b147c4ba4bea16ca3cb35c140/wait

and call it from ros_webrtc_example:

~/tmp/ros-webrtc-ws$ rosservice call /ros_webrtc_example/example/call cd0bdd0b147c4ba4bea16ca3cb35c140 ''

where:

  • cd0bdd0b147c4ba4bea16ca3cb35c140 is the browser peer id to call and
  • '' is an empty string indicating ros_webrtc_example should generate a random session id for the peer connection

At this point read the commented ros_webrtc_example source to get an idea of how these connections were established and what a ROS WebRTC app looks like.

params

These are used to configure ros_webrtc_host, e.g.:

~/tmp/ros-webrtc-ws$ rosparam get /ros_webrtc
cameras:
  webcam:
    constraints:
      mandatory: {maxHeight: '480', maxWidth: '640', minHeight: '480', minWidth: '640'}
    label: webcam
    name: id:///dev/video0
    publish: true
example: {id: hostname}
ice_servers:
- {uri: 'stun:stun.services.mozilla.com:3478'}
- {uri: 'stun:stun.l.google.com:19302'}
queue_sizes: {audio: 1000, data: 1000, event: 1000, video: 1000}
session:
  constraints:
    optional: {DtlsSrtpKeyAgreement: 'true'}
trace: {file: /tmp/ros_webrtc.trace, filter: all}

cameras

This is a mapping describing the video sources of the host. Each has these fields:

  • label - string naming the video source.
  • constraints- optional - nested mapping of mandatory and optional string constraints.
  • name - string of the form {type}://{resource}.
  • publish - optional - boolean controlling whether images from this source should be published.

See Google's source for possible constraints. In the e.g. above we constrained the webcam source to have size 640x480.

The name determines where video source images come from and is one of these types:

  • name - name of the video source (e.g. name://BisonCam, NB Pro).
  • id - device file of the video source (e.g. id:///dev/video0).
  • ros - a ROS sensor_msgs/Image topic (e.g. ros:///my/image/topic).

If publish is true then ros_webrtc_host will publish source images to a sensor_msgs/Image topic (e.g. /ros_webrtc/local/webcam).

ice_servers

A list of STUN and TURN servers to use when generating ice candidates. Each is a mapping with fields:

  • uri - type and network location formatted as {sturn|turn}:{hostname}[:{port}].
  • username - optional - authentication.
  • password - optional - authentication.

trace

A mapping with these fields controlling WebRTC tracing:

  • file - path to file where traces should be written.
  • filter - optional - either a sequence of strings or a single string of trace levels used to build a filter. In the e.g. above all traces have been included.

queue_sizes

Mapping of queue sizes to use for ros_webrtc_example ROS publishers. Each field of the mapping if a type of publisher (audio, video, data and event) with an integer value for the queue size.

peer_connection/timeout

Number of seconds (as a double) to use for the peer connection bond heart-beat timeout, or 0 to disable peer connection bonding (useful when debugging).

A peer connection bond is typically formed between the local WebRTC application and ros_webrtc_host so that either side is notified if peer connection is closed out-of-band.

peer_connection/constraint

This is a nested mapping of mandatory and optional string constraints to apply to each peer connection. See Google's source for possible constraints. In the e.g. above we constrained peer connections to optionally enable DTLS-SRTP for key management.

open_media_sources

Boolean controlling whether local media sources (cameras, microphones, speakers, etc) are opened/captured on start. It is true by default.

If set to false then local media sources will only be opened when there are peer connections that need them. So e.g. they will be opened on first peer connection, closed when the last peer connection ends then re-opened when the next peer connection is created.

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