3.7. Edge-Cloud TLS communication on WAN

Warning

In this example it is assumed the reader has basic knowledge of TLS concepts since terms like CA, Public-key cryptography, RSA, and Diffie-Hellman are not explained in detail.

3.7.1. Background

This tutorial builds on the previous one (Edge-Cloud communication on WAN), further showing how to secure the edge-cloud TCP communication channel with TLS protocol. It is recommended to follow these tutorials in order, as some concepts or installations may be already covered.

Warning

This tutorial is intended for WAN communication. However, if communication through a LAN is your only option, it is still possible to follow the tutorial by changing the ROS 2 Domain Ids so that each ROS 2 node uses a different Domain (0 and 1). This way the ROS 2 nodes are logically isolated and will not discover other nodes out of their ROS 2 Domain.

Following, all the elements involved in this architecture will be studied, starting with the edge robot, continuing with the controller hosted in the cloud also built as a ROS 2 node and concluding with the intermediate elements that enable communication over the Internet.

The image below describes the scenario presented in this tutorial.

../../../../_images/edge_cloud_wan_tls.png

Several key elements can be observed in it:

  1. ROS 2 Application. Turtlesim is the application used for this tutorial. Turtlesim is a ROS 2 application, first developed for ROS, aimed at teaching the basic concepts of ROS 2 such as publish/subscribe, services and actions. The edge robot will then be a turtlesim_node, which is a simulator of a robot making use of these communication methods.

  2. ROS 2 Device Controller. This is a ROS 2 application that sends commands to the edge robot. A basic C++ application has been developed for this tutorial that sends publications under the topic on which the turtlesim_node listens. By means of these publications (commands) from the controller, and the feedback information that the controller receives from the turtlesim_node, it is possible to control this node automatically without the need for user intervention which facilitates the deployment of the scenario at hand. The key feature of the DDS Router is that it is easy to configure, allowing to connect different networks with ROS 2 applications without requiring to apply any changes to the developer’s software or applications.

  3. ROS 2 Router / DDS Router. eProsima ROS 2 Router, a.k.a DDS Router, is an end-user software application that enables the connection of distributed ROS 2 networks (see DDS Router documentation here). That is, ROS 2 nodes such as publishers and subscribers, or clients and services, deployed in one geographic location and using a dedicated local network will be able to communicate with other ROS 2 nodes deployed in different geographic areas on their own dedicated local networks as if they were all on the same network through the use of DDS Router.

    This internet connection will be established using TCP protocol secured with TLS. This means that the data connection between both servers will be guaranteed to be secured, and the data encrypted.

    This example presents two routers that enable Internet communication:

    • DDS Router Cloud. It plays the server role in the communication. It will expose a public network address to which the nodes connect to establish communication. This DDS Router will work as the TLS Server, which means it must be authenticated in order for the client to trust and connect it.

    • DDS Router Edge. This is the DDS Router that is deployed on the edge robot side. This way it is possible for the robot to communicate out-of-the-box with an external server. This DDS Router will work as the TLS Client, so it must accept the Server CA in order to authenticate it before the communication is established.

    In the following steps it will be explained how to configure TLS in both sides, so the communication is secured.

3.7.2. Prerequisites

This tutorial will require two machines (Robot 1 and Cloud Server) deployed on different networks (LAN 1 and Cloud). It is possible to simulate the scenario by deploying everything needed on the same machine and two virtual networks but let’s focus on the case of a real deployment.

It is also necessary to have previously installed Vulcanexus using one of the following installation methods:

Note

OpenSSL, required in this tutorial to generate security keys and certificates, is already part of Vulcanexus toolset.

3.7.3. TLS configuration

Let us first generate the TLS credentials with which DDS Router instances will be configured. In this example, Elliptic Curve (EC) keys will be generated, and with/without password versions of the commands will be provided.

These files should be generated in cloud machine, or in a neutral host. The Cloud machine requires to hold the private key, as some other TLS files, while the Edge machine only requires to know the CA so it can assure it is communicating with a trusted server.

3.7.3.1. Certification Authority (CA)

Create first a mock CA that will be used to generate a certificate for the DDS Router Cloud:

# Generate the Certificate Authority (CA) Private Key > ca.key
openssl ecparam -name prime256v1 -genkey -noout -out ca.key
# openssl ecparam -name prime256v1 -genkey | openssl ec -aes256 -out ca.key -passout pass:cakey # with password

# Generate the Certificate Authority Certificate > ca.crt
openssl req -new -x509 -sha256 -key ca.key -out ca.crt -days 365 -config ca.cnf
# openssl req -new -x509 -sha256 -key ca.key -out ca.crt -days 365 -config ca.cnf -passin pass:cakey # with password

3.7.3.2. DDS Router Cloud Certificate

We can now generate a certificate for the DDS Router Cloud instance following the steps below:

# Generate the DDS-Router Certificate Private Key > ddsrouter.key
openssl ecparam -name prime256v1 -genkey -noout -out ddsrouter.key
# openssl ecparam -name prime256v1 -genkey | openssl ec -aes256 -out ddsrouter.key -passout pass:ddsrouterpass # with password

# Generate the DDS-Router Certificate Signing Request  > ddsrouter.csr
openssl req -new -sha256 -key ddsrouter.key -out ddsrouter.csr -config ddsrouter.cnf
# openssl req -new -sha256 -key ddsrouter.key -out ddsrouter.csr -config ddsrouter.cnf -passin pass:ddsrouterpass # with password

# Generate the DDS-Router Certificate (computed on the CA side) > ddsrouter.crt
openssl x509 -req -in ddsrouter.csr -CA ca.crt -CAkey ca.key -CAcreateserial -out ddsrouter.crt -days 1000 -sha256
# openssl x509 -req -in ddsrouter.csr -CA ca.crt -CAkey ca.key -CAcreateserial -out ddsrouter.crt -days 1000 -sha256 -passin pass:cakey # with password

3.7.3.3. Diffie-Hellman Parameters

It only remains to generate the Diffie-Hellman (DF) parameters to define how OpenSSL performs the DF key-exchange:

# Generate Diffie-Hellman (DF) parameters > dh_params.pem
openssl dhparam -out dh_params.pem 2048

3.7.4. Deployment on LAN 1

First, let’s deploy the turtlesim_node and DDS Router Edge on a machine on LAN 1.

3.7.4.1. Running turtlesim_node on the edge

Setup the Vulcanexus environment to have the turtlesim_node available. For this, there are two possible options:

  1. Running the Vulcanexus Docker image.

    Run the Vulcanexus Docker image with:

    xhost local:root
    docker run \
        -it \
        --privileged \
        -e DISPLAY=$DISPLAY \
        -v /tmp/.X11-unix:/tmp/.X11-unix \
        ubuntu-vulcanexus:iron-desktop
    

    Then, within the container, source the Vulcanexus installation with:

    source /opt/vulcanexus/iron/setup.bash
    
  2. Setting up the development environment on the local host. For this second option, it is necessary to have installed the vucanexus-iron-desktop package, since this is the one that includes all the simulation tools, demos and tutorials.

    Source the following file to setup the Vulcanexus environment:

    source /opt/vulcanexus/iron/setup.bash
    

Once the environment has been setup using one of the above options, simply run the turtlesim_node.

ros2 run turtlesim turtlesim_node

And a popup window like the following should appear:

../../../../_images/turtlesim_node.png

As can be seen, it is not necessary to perform any additional configuration in the ROS 2 application.

3.7.4.2. Running DDS Router Edge

Then, to run the DDS Router Edge configure the environment as in the previous step.

Note

If deploying Vulcanexus from the Docker image, note that you will need to have a configuration file (config.yaml) for the DDS Router Edge accessible from your Docker container.

This can be achieved by mounting a shared volume when launching the container, by copying the file from the local host to the container in case it is already running, or by editing a file from the Docker container itself.

Setup the Vulcanexus environment, either in a Docker container or on the local host, running the following command:

source /opt/vulcanexus/iron/setup.bash

Let’s create a DDS Router configuration file as the one shown below.

version: v3.1

participants:

  - name: ROS_2_LAN_1
    kind: local

  - name: Router_Client
    kind: wan
    connection-addresses:
      - ip: 123.123.123.123
        port: 45678
        transport: tcp

    tls:
      ca: ca.crt

Next, the most relevant aspects of this configuration file are explained.

The participants are the interfaces of the DDS Router to communicate with other networks. In this case, we have two kinds of participants:

  • local: this is a simple participant that communicates with all ROS 2 nodes it finds. For more information about this participant please refer to the Simple Participant section of the DDS Router documentation.

  • wan: it is a participant designed for the communication between two DDS Routers. It uses the Initial Peers discovery mechanism to establish a point-to-point communication between two DDS entities, two DDS Routers in this case.

For the DDS Router Edge, a connection address shall be defined which must be the same as the one exposed by the Cloud Server. TLS configuration parameters required to establish a secure connection over TCP are provided under the tls tag. For clients, only the certificate authority (CA) needs to be provided. Please refer to DDS Router documentation for more details on how to configure TLS in a WAN participant.

Note

In this case, the DDS Router will forward all topics found in the network. However, it is important to mention that the ROS 2 topics relayed by the DDS Router can be filtered by configuring the allowlist and blocklist. If this is the case please refer to the DDS Router documentation for information on how to do this.

The following figure summarizes the deployment on the edge.

../../../../_images/edge_deployment_tls.png

Now, run the DDS Router with the configuration file created as an argument.

ddsrouter -c <path/to/file>/ddsrouter_edge.yaml

3.7.5. Deployment on Cloud

3.7.5.1. Running the turtlesim_square_move on the Cloud

Run the turtlesim_square_move in the Cloud Server machine, which is the controller of the edge turtlesim_node. This will send commands to the ROS 2 application to the edge to move the turtle and receive information about the current state of the turtle at any time.

A ROS 2 application that moves the turtle by drawing a square has been developed for this purpose. The application is based on the ROS 2 tutorials, but has been slightly modified in order to make it easier to understand and adapt to the ROS 2 and modern C++ programming methods.

Then, start by creating the workspace of this application and downloading the source code:

mkdir -p turtlesim_move_ws/src && cd turtlesim_move_ws/src
git clone --branch iron https://github.com/eProsima/vulcanexus.git
mv vulcanexus/code/turtlesim .
rm -rf vulcanexus
cd ..

Once created the workspace, source the Vulcanexus environment and build the turtlesim_square_move application.

source /opt/vulcanexus/iron/setup.bash
colcon build

Note

Since the purpose of this tutorial is not to explain how to create a ROS 2 node, but rather, the communication of these in distributed environments, the code will not be discussed in detail. Stay tuned for new tutorials in which we will discuss how to configure ROS 2 nodes, publishers/subscribers, services and actions.

Then source the turtlesim_move_ws workspace:

source turtlesim_move_ws/install/setup.bash

And finally, run the application:

ros2 run turtlesim turtlesim_square_move

The important points to note in this application are the following:

  • The control application sends the movement commands to the turtlesim_node through a publisher in the geometry_msgs/msg/Twist topic. This topic expresses the velocity at which the turtle has to move divided into linear velocity (linear) and angular velocity (angular).

  • The application knows the position of the turtle on the map at any moment and whether it is stopped or moving by subscribing to the turtlesim/msg/pose topic. This topic provides information about the turtle’s coordinates (x and y) and the turtle’s rotation (theta). We can also know its linear and angular velocity (linear_velocity and angular_velocity).

3.7.5.2. Running the DDS Router Cloud

In case this device is working under a NAT, check previous tutorial for more information about how to configure the NAT to be accessible from the outside.

3.7.5.2.1. Configure the DDS Router Cloud

The DDS Router Cloud configuration file is quite similar to the DDS Router Edge configuration file, as can be seen below:

version: v3.1

participants:

  - name: ROS_2_Cloud
    kind: local

  - name: Router_Server
    kind: wan
    listening-addresses:
      - ip: 123.123.123.123
        port: 45678
        transport: tcp

    tls:
      ca: ca.crt
      password: ddsrouterpass
      private_key: ddsrouter.key
      cert: ddsrouter.crt
      dh_params: dh_params.pem

In this case there are also two participants, two communication interfaces for the DDS Router. The first one communicates the DDS Router with any ROS 2 node, while the second one enables to establish a communication channel with another DDS Router.

Even so there are some differences in the second participant that are worth mentioning:

  1. This participant sets a listening address (listening-addresses), rather than a connection address. This is because it is the participant that waits for incoming communications since it has this network address exposed and accessible from the Internet.

  2. The previously generated TLS parameters and certificates are attached under the tls tag. Note that server and client configurations differ, as explained in DDS Router documentation.

To finish, as done in the previous steps, setup the Vulcanexus environment sourcing the setup.bash file and run the DDS Router Cloud with the above configuration.

source /opt/vulcanexus/iron/setup.bash
ddsrouter -c <path/to/file>/ddsrouter_cloud.yaml

The following figure summarizes the deployment on the Cloud.

../../../../_images/cloud_deployment_tls.png

3.7.6. Results

If all the steps in this tutorial have been followed, the turtle in the turtlesim_node on the edge should move around creating a square,

../../../../_images/turtlesim_node_square.png

and the turtlesim_square_move should prompt the following traces

root@dbf79a437eb3:/turtlesim_move_ws# ros2 run turtlesim turtlesim_square_move
[INFO] [1657870899.585667136] [turtlesim_square_move]: New goal [7.544445 5.544445, 0.000000]
[INFO] [1657870901.585656311] [turtlesim_square_move]: Reached goal
[INFO] [1657870901.585767260] [turtlesim_square_move]: New goal [7.448444 5.544445, 1.570796]
[INFO] [1657870905.685637930] [turtlesim_square_move]: Reached goal
[INFO] [1657870905.685753714] [turtlesim_square_move]: New goal [7.466837 7.544360, 1.561600]
[INFO] [1657870907.885655744] [turtlesim_square_move]: Reached goal
[INFO] [1657870907.885742857] [turtlesim_square_move]: New goal [7.466837 7.544360, 3.132396]
[INFO] [1657870911.985655175] [turtlesim_square_move]: Reached goal
[INFO] [1657870911.985738726] [turtlesim_square_move]: New goal [5.467175 7.581143, 3.123200]
[INFO] [1657870914.085652821] [turtlesim_square_move]: Reached goal