In the first half of the course we'll learn how to simulate mobile robots, sensors, actuators. How to do mapping localization and navigation.
In the second half of the course we'll learn about the simulation of robotic arms with direct and inverse kinematics.
Detailed description and requirements of the final project can be found on this link.
Registration deadline for projects: week 5
Submission deadline: week 14
- Project teams should consist of 3, maximum 4 members.
- The project submission will take place live (on Teams) in 15+5 minutes
- The project documentation should be in Markdown format on GitHub (no PPT required!)
- What is ROS(2)?
- Required softwares
- Basics of ROS2
3.1. Running some examples
3.2. Create a colcon workspace
3.3. Let's write the simplest possiblehello_world
in python
3.4. Create a python publisher
3.5. Create a C++ publisher
3.6. Create a python subscriber
3.7. Create a C++ subscriber
3.8. Launchfiles
3.9. Remap - Parameters
4.1. Set the parameter from a launchfile
4.2. A more advanced example for setting parameters - Services
5.1. Service server
5.2. Service client
5.3. Use services and parameters with turtlesim - Recap
6.1. Useful Linux commands
6.2. Useful ROS2 commands
ROS, or Robot Operating System, is an open-source framework designed to facilitate the development of robotic applications. It provides a collection of tools, libraries, and conventions that simplify the process of designing complex robot behaviors across a wide variety of robotic platforms.
ROS was initially developed in 2007 by the Stanford Artificial Intelligence Laboratory and continued by Willow Garage, with the goal of providing a common platform for research and development in robotics. The primary motivation was to create a standard framework that could support a broad range of robotic applications, promote code reuse, and foster collaboration within the robotics community.
Key reasons for ROS development include:
- Standardization: Creating a common platform that simplifies the integration of different hardware and software components.
- Modularity: Enabling the development of modular and reusable software components (nodes) that can be easily shared and adapted for various robotic systems.
- Community Collaboration: Encouraging collaboration among researchers and developers, resulting in a vast collection of tools and libraries.
ROS 2 was developed to address the limitations of ROS 1 and meet the growing demands for industrial and commercial robotics applications. The development began around 2014 and aimed to enhance the capabilities of ROS, particularly in areas such as security, real-time performance, and support for multi-robot systems. In practice, the biggest difference is in the underlying middleware, ROS1 uses a custom transport layer and message-passing system that was not designed for real-time or distributed applications (see ROS1's roscore
).
The latest ROS1 release is ROS Noetic which was intended to be used on Ubuntu 20.04.
Ubuntu 24.04 LTS
In the course we'll use ROS2 Jazzy Jalisco, which requires Ubuntu 24.04 for the smoothest operation.
You have a couple of options, but the most recommended is the native install of the operating system.
- Native install
- Windows 11 WSL2 (Windows Subsystem Linux): instructions
- Virtual machine, recommended: VMware fusion is now free for personal use
- Docker container
- Using an online environment e.g. The Construct
The options 1. and 2. are the most preferred solutions, in an exotic case like mine, if you want to install Ubuntu 24.04 in virtual machine on Apple silicon this is a very good tutorial.
Pro tip if you want to mount directories from your host system into your guest Ubuntu 24.04 running in VMware fusion, more details on this link:
/usr/bin/vmhgfs-fuse .host:/BME/ROS2-lessons /home/david/ros2_ws/src/ROS2-lessons -o subtype=vmhgfs-fuse,allow_other
Visual Studio Code
The recommended code editor during the course is Visual Studio Code, but it's up to your choice if you want to go with your different editor. Depending on your Ubuntu install method you might install it natively on Ubuntu, in your virtual environment or on your host operating system.
Recommended extensions to install:
- Markdown All in One
- C/C++
- Python
- CMake Tools
- Remote - SSH - if you work on physical robots, too
- Remote - WSL - if you do the course using WSL2
GitHub and a git client
The course materials are available on GitHub, and the submissions of your final projects shall also use GitHub. You'll need a very good excuse why to use alternative git solutions like GitLab.
So I encourage everyone to register your GitHub accounts, and if you are there don't forget to sign up for the GitHub Student Developer Pack which gives you a bunch of powerful developer tools for free.
I recommend to use a graphical git client that can boost your experience with git, in my optinion the best one is GitKraken, which is not a free software, but you get the pro version as part of the GitHub Student Developr Pack! If you prefer using git as a cli tool then no worries, it's absoluetely all right.
Markdown
Markdown is not a standalone software but rather a lightweight, plain-text formatting language used to create formatted documents. It was created by John Gruber in 2004 with the goal of being easy to read and write, using simple syntax to style text, create lists, links, images, and more. It is widely used for writing documentation, readme files, and content for static websites.
Basic Markdown Syntax
- Headings:
#
Heading 1,##
Heading 2, etc. - Bold:
**bold text**
or__bold text__
- Italic:
*italic text*
or_italic text_
- Lists:
- Unordered:
- Item
or* Item
- Ordered:
1. Item
- Links:
[Link text](URL)
- Images:
![Alt text](Image URL)
- Code: Inline code or code blocks using triple backticks (```)
- Unordered:
GitHub Flavored Markdown (GFM)
GitHub Flavored Markdown (GFM) is a variant of Markdown used by GitHub to provide additional features and syntax that are not available in standard Markdown. It includes:
- Tables:
| Column 1 | Column 2 | |----------|----------| | Row 1 | Data | | Row 2 | Data |
- Task lists:
- [x] Task 1 - [ ] Task 2
- Strikethrough:
~~strikethrough text~~
- Syntax highlighting in a specific language:
```python def hello_world(): print("Hello, world!")
- Tables of Contents
- @mentions for users, references to issues, and pull requests using #number
Most of the tips and tricks that you might need for your own project documentation can be found in the source of this readme that you read right now, feel free to use any snippets from it!
A good terminal
It's up to your choice which terminal tool would you like to use, but I strongly recommend one that support multiple split windows in a single unified window, because we will use a lot of terminals! On Linux, I can recommend terminator
:
In case you use WSL2, the built-in Windows terminal also support multiple panes and works really well!
And finally, install ROS2 Jazzy
ROS always had very good and detailed installed guides, it's not anything different for ROS2's Jazzy release.
The installation steps can be found here, with Ubuntu 24.04 it can be installed simply through pre-built, binary deb
packages.
After installing it we have to set up our ROS2 environment with the following command:
source /opt/ros/jazzy/setup.bash
By default, we have to run this command in every new shell session we start, but there is a powerful tool in Linux for such use cases. .bashrc
file is always in the user's home directory and it is used for user-specific settings for our shell sessions. You can edit .bashrc
directly in a terminal window with a basic text editor, like nano
:
david@david-ubuntu24:~$ nano .bashrc
Here, you can add your custom user-specific settings in the end of the file, that will be executed every time you initiate a new shell session. I created an example gist that you can add to the end of your file and use it during the course.
ROS2 Jazzy has an even more detailed tutorial about setting up your environment, you can check it out, too!
Your ROS2 install comes with a couple of examples as you can also read on the install page.
Let's try them!
The following command starts a simple publisher. A publisher is a component that is responsible for sending messages (in this example a string) over a specific topic (in this example the topic's name is chatter
) to other nodes in the system. It is part of the publish-subscribe communication model, where publishers send data to topics, and subscribers listen to those topics to receive the data.
Publish-subscribe models are asynchronous, one-to-many or many-to-many interactions where the publishers don't know how many subscribers there are (if any). Therefore publisher never expects any response or confirmation from the subscribers.
Now, let's run the demo publisher:
ros2 run demo_nodes_cpp talker
Your output should look like this:
david@david-ubuntu24:~$ ros2 run demo_nodes_cpp talker
[INFO] [1727116062.558281395] [talker]: Publishing: 'Hello World: 1'
[INFO] [1727116063.558177802] [talker]: Publishing: 'Hello World: 2'
[INFO] [1727116064.558010534] [talker]: Publishing: 'Hello World: 3'
[INFO] [1727116065.557939861] [talker]: Publishing: 'Hello World: 4'
[INFO] [1727116066.557849645] [talker]: Publishing: 'Hello World: 5'
Let's start a subscriber in another terminal window, which subscribes to the chatter
topic and listens to the publisher node's messages
david@david-ubuntu24:~$ ros2 run demo_nodes_py listener
[INFO] [1727116231.574662048] [listener]: I heard: [Hello World: 170]
[INFO] [1727116232.560517676] [listener]: I heard: [Hello World: 171]
[INFO] [1727116233.558907367] [listener]: I heard: [Hello World: 172]
[INFO] [1727116234.560768278] [listener]: I heard: [Hello World: 173]
[INFO] [1727116235.559821377] [listener]: I heard: [Hello World: 174]
[INFO] [1727116236.559993767] [listener]: I heard: [Hello World: 175]
Now both nodes are running we can try a few useful tools. The first on let us know what kind of nodes are running in your ROS2 system:
ros2 node list
Which gives us the following output:
david@david-ubuntu24:~/ros2_ws$ ros2 node list
/listener
/talker
If we want to know more about one of our nodes, we can use the ros2 node info /node
command:
david@david-ubuntu24:~/ros2_ws$ ros2 node info /listener
/listener
Subscribers:
/chatter: std_msgs/msg/String
Publishers:
/parameter_events: rcl_interfaces/msg/ParameterEvent
/rosout: rcl_interfaces/msg/Log
Service Servers:
/listener/describe_parameters: rcl_interfaces/srv/DescribeParameters
/listener/get_parameter_types: rcl_interfaces/srv/GetParameterTypes
/listener/get_parameters: rcl_interfaces/srv/GetParameters
/listener/get_type_description: type_description_interfaces/srv/GetTypeDescription
/listener/list_parameters: rcl_interfaces/srv/ListParameters
/listener/set_parameters: rcl_interfaces/srv/SetParameters
/listener/set_parameters_atomically: rcl_interfaces/srv/SetParametersAtomically
Service Clients:
Action Servers:
Action Clients:
At the moment the most important detail we can get about a node is if it's subscribing or publishing to any topic. Later we'll learn more about parameters and services.
In a very similar way we can also list all of our topics with ros2 topic list
command:
david@david-ubuntu24:~/ros2_ws$ ros2 topic list
/chatter
/parameter_events
/rosout
And we can get more details about a certain topic with the ros2 topic info /topic
command:
david@david-ubuntu24:~/ros2_ws$ ros2 topic info /chatter
Type: std_msgs/msg/String
Publisher count: 1
Subscription count: 1
Another powerful tool is rqt_graph
that helps us visualizing the nodes and topics in a graph.
rqt_graph
can be used as a standalone tool, or part of rqt
which can be used to build a complete dashboard to mintor and control your nodes. We'll spend a lot of time with it, at the moment let's just see the message monitoring function:
Let's see another built in example which is a simple 2D plotter game.
In a case it's not automatically installed, you can install it with the following command:
sudo apt install ros-jazzy-turtlesim
To run the main node just execute the follwoing command:
ros2 run turtlesim turtlesim_node
And in another terminal start its remote controller, you can simply drive the turtle with the arrows:
ros2 run turtlesim turtle_teleop_key
We can use the same tools as before to see the running nodes and topics, here is how does it look like in rqt_graph
.
We should notice two important things:
- turtlesim is more complex than the previous example with multiple services and parameters that we'll check in the end of this lesson.
- the turtle is controlled with a
cmd_vel
message which is a 6D vector in space. We'll use this exact same message type in the future to drive our simulated robots.
Now let's move on to create our own nodes!
To create, build and run custom nodes we need packages, but first we need a workspace where we'll maintain our future packages. There are 2 new terms we must learn about ROS2 workspaces:
ament
provides the underlying build system and tools specifically for ROS2 packages.ament_cmake
is a CMake-based build system for C/C++ nodes andament_python
provides the tools for packing and installing python nodes and libraries.colcon
(COmmand Line COLlectioN) is a general-purpose tool to build and manage entire workspaces with various build systems, including ament, cmake, make, and more.
It means that our ROS2 workspaces will be colcon workspaces
which in the backround will use ament
for building the individual packages.
If you have experience with ROS1,
colcon
andament
replaces the oldcatkin
tools.
Let's create our workspace inside our user's home directory:
mkdir -p ~/ros2_ws/src
cd ~/ros2_ws
A workspace always must contain a
src
folder where we maintain the source files of our packages, later, during building colcon will create further folders for binaries and other output files.
Let's go into the src
folder and create our first python package
ros2 pkg create --build-type ament_python bme_ros2_tutorials_py
During package creation we should define if it's a C/C++ (
ament_cmake
) or a python (ament_python
) package. If we don't do it, the default is alwaysament_cmake
!
Let's create a scripts
folder inside our new package, add an empty file __init__.py
and add our first node, hello_world.py
.
We can create files in Linux in several different ways, just a few examples:
- Right click in the folder using the desktop environment
- Through the development environment, in our case Visual Studio Code
- From command line in the current folder using the
touch
command:touch hello_world.py
At this point our workspace should look like this (if it was not built yet):
david@david-ubuntu24:~/ros2_ws$ tree -L 4
.
└── src
└── bme_ros2_tutorials_py
└── scripts
├── __init__.py
└── hello_world.py
It's always recommended to fill out the
description
,maintainer
with your name and email address andlicense
fields in yourpackage.xml
andsetup.py
files. I personally prefer a highly permissive license in non-commercial packages of mine, likeBSD
orApache License 2.0
.
#!/usr/bin/env python3
# Main entry point, args is a parameter that is used to pass arguments to the main function
def main(args=None):
print("Hello, world!")
# Check if the script is being run directly
if __name__ == '__main__':
main()
Although this is a python script that doesn't require any compilation, we have to make sure that ament
will pack, copy and install our node. Note that we are not running python scripts directly from its source folder!
Let's edit setup.py
that was automatically generated when we defined that our package will use ament_python
.
-
Add an entry point for every python node:
... entry_points={ 'console_scripts': [ 'py_hello_world = scripts.hello_world:main' ], }, ...
-
If your scripts folder already has a
__init__.py
file,find_packages()
should find it, but if it doesn't happen you can anytime simply edit packages variable like this:... #packages=find_packages(exclude=['test']), packages=[package_name, 'scripts'], ...
After this our first node in our first package is ready for build! Build must be initiated always in the root of our workspace!
cd ~/ros2_ws
And here we can execute the colcon build
command.
After a successful build we have to update our environnment with the freshly built package, to do this we have to run the following command:
source install/setup.bash
As we did with the base ROS2 environment we can add this to the .bashrc
, too:
source ~/ros2_ws/install/setup.bash
And now we are ready to run our first node:
ros2 run bme_ros2_tutorials_py py_hello_world
Athough we could run our first node, it was a plain python script, not using any components of ROS. Let's upgrade hello world to a more ROS-like hello world. We import the rclpy
which is the ROS2 python API and we start using the most basic functions of rclpy
like init()
, create_node()
and shutdown()
. If you want to already deep-dive in the the API functions you can find more details here.
#!/usr/bin/env python3
import rclpy # Import ROS2 python interface
# Main entry point, args is a parameter that is used to pass arguments to the main function
def main(args=None):
rclpy.init(args=args) # Initialize the ROS2 python interface
node = rclpy.create_node('python_hello_world') # Node constructor, give it a name
node.get_logger().info("Hello, ROS2!") # Use the ROS2 node's built in logger
node.destroy_node() # Node destructor
rclpy.shutdown() # Shut the ROS2 python interface down
# Check if the script is being run directly
if __name__ == '__main__':
main()
We don't have to do anything with setup.py
but we have to re-build the colcon workspace!
After that we can run our node:
ros2 run bme_ros2_tutorials_py py_hello_world
Let's make our first publisher in python, we create a new file in scripts
folder: publisher.py
.
We start expanding the usage of the ROS2 API with publishing related functions.
#!/usr/bin/env python3
import rclpy
from std_msgs.msg import String # Import 'String' from ROS2 standard messages
import time
def main(args=None):
rclpy.init(args=args)
node = rclpy.create_node('python_publisher')
# Register the node as publisher
# It will publish 'String' type to the topic named 'topic' (with a queue size of 10)
publisher = node.create_publisher(String, 'topic', 10)
msg = String() # Initialize msg as a 'String' instance
i = 0
while rclpy.ok(): # Breaks the loop on ctrl+c
msg.data = f'Hello, world: {i}' # Write the actual string into msg's data field
i += 1
node.get_logger().info(f'Publishing: "{msg.data}"')
publisher.publish(msg) # Let the node publish the msg according to the publisher setup
time.sleep(0.5) # Python wait function in seconds
node.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()
We have to edit setup.py
, registering our new node as entry point:
...
entry_points={
'console_scripts': [
'py_hello_world = scripts.hello_world:main',
'py_publisher = scripts.publisher:main'
],
},
...
Don't forget to rebuild the workspace and we can run our new node:
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_py py_publisher
[INFO] [1727526317.470055907] [python_publisher]: Publishing: "Hello, world: 0"
[INFO] [1727526317.971461827] [python_publisher]: Publishing: "Hello, world: 1"
[INFO] [1727526318.473896872] [python_publisher]: Publishing: "Hello, world: 2"
[INFO] [1727526318.977439178] [python_publisher]: Publishing: "Hello, world: 3"
We can observe the published topic through rqt
's topic monitor:
Or we can use a simple but powerful tool, the topic echo
:
david@david-ubuntu24:~$ ros2 topic echo /topic
data: 'Hello, world: 23'
---
data: 'Hello, world: 24'
---
data: 'Hello, world: 25'
The above publisher node is very simple and looks exactly how we impelent nodes in ROS1. But ROS2 provides more powerful API functions and also places a greater emphasis on object-oriented programming. So let's create another publisher but in a more OOP way and using the timer functions of the ROS2 API. The other important API function is rclpy.spin(node)
which keeps the node running until we don't force quit it with ctrl+c
.
#!/usr/bin/env python3
import rclpy
from rclpy.node import Node # Import ROS2 Node as parent for our own node class
from std_msgs.msg import String
class MyPublisherNode(Node):
def __init__(self):
super().__init__("python_publisher_oop")
self.publisher_ = self.create_publisher(String, 'topic', 10)
self.timer = self.create_timer(0.5, self.timer_callback) # Timer callback, period in seconds, not frequency!
self.i = 0
self.msg = String()
self.get_logger().info("Publisher OOP has been started.")
def timer_callback(self): # Timer callback function implementation
self.msg.data = f"Hello, world: {self.i}"
self.i += 1
self.get_logger().info(f'Publishing: "{self.msg.data}"')
self.publisher_.publish(self.msg)
def main(args=None):
rclpy.init(args=args)
node = MyPublisherNode() # node is now a custom class based on ROS2 Node
rclpy.spin(node) # Keeps the node running until it's closed with ctrl+c
node.destroy_node()
rclpy.shutdown()
if __name__ == "__main__":
main()
As we did previously, edit setup.py
, build the workspace and run our new node:
ros2 run bme_ros2_tutorials_py py_publisher_oop
In ROS1 it was very straightforward to mix nodes written in different languages. In ROS2 although it's not impossible, it requires more manual editing of package metadata because we define for ament
what is the package's build type. To keep it simple, let's create a new package, but on this link you can see an example how to mix both python and C++ nodes within the same package.
ros2 pkg create --build-type ament_cmake bme_ros2_tutorials_cpp
Let's create publisher.cpp
in src
folder of the new package, this follows the object-oriented patterns as our previous python node, including the ROS2 timer. This time we work with the ROS2 C++ API, rclcpp
, the available API functions are pretty much identical to the rclpy
.
#include "rclcpp/rclcpp.hpp"
#include "std_msgs/msg/string.hpp"
class MyPublisherNode : public rclcpp::Node
{
public:
MyPublisherNode() : Node("cpp_publisher"), count_(0)
{
publisher_ = this->create_publisher<std_msgs::msg::String>("topic", 10);
timer_ = this->create_wall_timer(std::chrono::milliseconds(500),
std::bind(&MyPublisherNode::publishString, this));
RCLCPP_INFO(this->get_logger(), "CPP publisher has been started.");
}
private:
void publishString()
{
auto msg = std_msgs::msg::String();
msg.data = "Hello, world: " + std::to_string(this->count_++);
RCLCPP_INFO(this->get_logger(), "Publishing: '%s'", msg.data.c_str());
publisher_->publish(msg);
}
size_t count_;
rclcpp::Publisher<std_msgs::msg::String>::SharedPtr publisher_;
rclcpp::TimerBase::SharedPtr timer_;
};
int main(int argc, char **argv)
{
rclcpp::init(argc, argv);
rclcpp::spin(std::make_shared<MyPublisherNode>());
rclcpp::shutdown();
return 0;
}
To properly set up our node in the package's metadata files we have to edit the CMakeLists.txt
:
find_package(rclcpp REQUIRED)
find_package(std_msgs REQUIRED)
add_executable(publisher_cpp src/publisher.cpp)
ament_target_dependencies(publisher_cpp rclcpp std_msgs)
install(TARGETS
publisher_cpp
DESTINATION lib/${PROJECT_NAME})
After that we can build the workspace with colcon build
, since it's a new package we have to source the environment and after the we can run our new node:
ros2 run bme_ros2_tutorials_cpp publisher_cpp
If sourcing the environment of your workspace is already in the
.bashrc
it's just easier to close and open a new terminal session.
We can use the same tools as before to observe the published data by our new C++ node like topic list
, topic echo
or a graphical tool like rqt
.
Let's create a new file subscriber.py
in the scripts folder of our python package. First let's make the very simple implementation and after that we'll implement a more OOP version of it. Here we extend our knowledge with more API functions related to subscriptions.
#!/usr/bin/env python3
import rclpy
from std_msgs.msg import String
def main(args=None):
rclpy.init(args=args)
node = rclpy.create_node('python_subscriber')
def subscriber_callback(msg): # Subscriber callback will be invoked every time when a message arrives to the topic it has subsctibed
node.get_logger().info(f"I heard: {msg.data}")
# Register the node as a subscriber on a certain topic: 'topic' (with a certain data type: String)
# and assign the callback function that will be invoked when a message arrives to the topic
# with a queue size of 10 which determines how many incoming messages can be held in the subscriber’s
# queue while waiting to be processed by the callback function
subscriber = node.create_subscription(String, 'topic', subscriber_callback, 10)
node.get_logger().info("Subsciber has been started.")
rclpy.spin(node)
node.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()
Add the node to the setup.py
file as a new entry point
...
entry_points={
'console_scripts': [
'py_hello_world = scripts.hello_world:main',
'py_publisher = scripts.publisher:main',
'py_publisher_oop = scripts.publisher_oop:main',
'py_subscriber = scripts.subscriber:main'
],
},
...
Then, re-build the workspace and we can start using our new node!
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_py py_subscriber
[INFO] [1727606328.416973729] [python_subscriber]: Subsciber has been started.
If we don't start a publisher, then our subscriber is just keep listening to the /topic
but the callback function is not invoked. The node doesn't stop running because of the rclpy.spin(node)
API function.
Let's start our C++ publisher in another terminal window:
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_cpp publisher_cpp
[INFO] [1727606744.184678739] [cpp_publisher]: CPP publisher has been started.
[INFO] [1727606744.685934650] [cpp_publisher]: Publishing: 'Hello, world: 0'
[INFO] [1727606745.185073828] [cpp_publisher]: Publishing: 'Hello, world: 1'
[INFO] [1727606745.686288921] [cpp_publisher]: Publishing: 'Hello, world: 2'
[INFO] [1727606746.186169881] [cpp_publisher]: Publishing: 'Hello, world: 3'
And let's see what happens with the subscriber! It's subscription callback function is invoked every time when the publisher puts a data onto the /topic
.
david@david-ubuntu24:~/ros2_ws$ ros2 run bme_ros2_tutorials_py py_subscriber
[INFO] [1727606614.099180007] [python_subscriber]: Subsciber has been started.
[INFO] [1727606744.695260304] [python_subscriber]: I heard: Hello, world: 0
[INFO] [1727606745.187956805] [python_subscriber]: I heard: Hello, world: 1
[INFO] [1727606745.689289484] [python_subscriber]: I heard: Hello, world: 2
[INFO] [1727606746.188467429] [python_subscriber]: I heard: Hello, world: 3
We can also observe it with rqt_graph
:
And we can also observe the language agnostic approach of ROS2, without any additional effort its middleware provides the interface between the 2 nodes which were written in different programming languages.
Let's make our subscriber more OOP using our previous template from the publisher. Compared to the OOP publisher we need to replace the timer callback with a subscription callback and that's all!
#!/usr/bin/env python3
import rclpy
from rclpy.node import Node
from std_msgs.msg import String
class MySubscriberNode(Node):
def __init__(self):
super().__init__("python_subsciber_oop")
self.subscriber_ = self.create_subscription(String, 'topic', self.subscriber_callback, 10)
self.get_logger().info("Subsciber OOP has been started.")
def subscriber_callback(self, msg):
self.get_logger().info(f"I heard: {msg.data}")
def main(args=None):
rclpy.init(args=args)
node = MySubscriberNode()
rclpy.spin(node)
node.destroy_node()
rclpy.shutdown()
if __name__ == "__main__":
main()
Now let's create a new file in the src
directory of the bme_ros2_tutorials_cpp
, we can name it subscriber.cpp
.
#include "rclcpp/rclcpp.hpp"
#include "std_msgs/msg/string.hpp"
class MySubscriberNode : public rclcpp::Node
{
public:
MySubscriberNode() : Node("cpp_subscriber")
{
subscriber_ = this->create_subscription<std_msgs::msg::String>(
"topic", 10, std::bind(&MySubscriberNode::subscriber_callback, this, std::placeholders::_1));
}
private:
void subscriber_callback(const std_msgs::msg::String & msg) const
{
RCLCPP_INFO(this->get_logger(), "I heard: '%s'", msg.data.c_str());
}
rclcpp::Subscription<std_msgs::msg::String>::SharedPtr subscriber_;
};
int main(int argc, char **argv)
{
rclcpp::init(argc, argv);
auto node = std::make_shared<MySubscriberNode>();
rclcpp::spin(node);
rclcpp::shutdown();
return 0;
}
Add it to the CMakeLists.txt
:
add_executable(publisher_cpp src/publisher.cpp)
add_executable(subscriber_cpp src/subscriber.cpp)
ament_target_dependencies(publisher_cpp rclcpp std_msgs)
ament_target_dependencies(subscriber_cpp rclcpp std_msgs)
install(TARGETS
publisher_cpp
subscriber_cpp
DESTINATION lib/${PROJECT_NAME})
Re-build the workspace and we can try the new node. Let's start also a publisher and observe the behavior of the new C++ subscriber with the tools we already know!
As you noticed with the previous examples we have to use as many terminals as many nodes we start. With a simple publisher and subscriber this isn't really a problem, but in more complex robotic systems, it's quite common to use ROS nodes in the range of hundreds. Therefore ROS provides an efficient interface to launch multiple nodes together and even change their topics or parameters during launch time instead of changing the actuals nodes themselves.
Compared to ROS1 it's also slightly more complicated to bundle these launchfiles with our nodes, so as a best practice, I recommend creating an individual pakage only for your launcfiles.
Let's create a new package without specifying the build type (by default it's ament_cmake
).
ros2 pkg create bme_ros2_tutorials_bringup
Now let's create a launch
folder within this new package.
We can freely delete include and src folders:
If you want to delete a folder from command line that is not empty you can use the
rm -rf folder
command
rm -rf include/ src/
Add the following to the CMakeLists.txt
to install the content of launch
when we build the workspce:
install(DIRECTORY
launch
DESTINATION share/${PROJECT_NAME}
)
Create a new launch file, and let's call it publisher_subscriber.py
, in ROS2 the launchfiles are special python scripts instead of the XML
files we used in ROS1!
touch publisher_subscriber.py
Let's create our template that we can re-use in the future with only one publisher first. When we add a node to the launch file we must define the the package
, the node
and a chosen name
.
#!/usr/bin/env python3
from launch import LaunchDescription
from launch_ros.actions import Node
def generate_launch_description():
ld = LaunchDescription()
publisher_node = Node(
package="bme_ros2_tutorials_py",
executable="py_publisher",
name="my_publisher"
)
ld.add_action(publisher_node)
return ld
Build and don't forget to source the workspace because we added a new package!
After it we can execute our launchfile with the ros2 launch
command:
david@david-ubuntu24:~$ ros2 launch bme_ros2_tutorials_bringup publisher_subscriber.py
[INFO] [launch]: All log files can be found below /home/david/.ros/log/2024-09-29-14-17-29-864407-david-ubuntu24-41228
[INFO] [launch]: Default logging verbosity is set to INFO
[INFO] [py_publisher-1]: process started with pid [41231]
[py_publisher-1] [INFO] [1727612250.056173684] [my_publisher]: Publishing: "Hello, world: 0"
[py_publisher-1] [INFO] [1727612250.559170990] [my_publisher]: Publishing: "Hello, world: 1"
[py_publisher-1] [INFO] [1727612251.061618736] [my_publisher]: Publishing: "Hello, world: 2"
We can notice that our node is now called my_publisher
instead of python_publisher
as we coded in the node itself earlier. With launch files we can easily rename our nodes for better handling and organizing as our application scales up.
We can use the node list
tool to list our nodes and the output will look like this:
david@david-ubuntu24:~/ros2_ws$ ros2 node list
/my_publisher
Every time when we add a node to the launch file we also have to register it with the ld.add_action()
function:
from launch import LaunchDescription
from launch_ros.actions import Node
def generate_launch_description():
ld = LaunchDescription()
publisher_node = Node(
package="bme_ros2_tutorials_py",
executable="py_publisher",
name="my_publisher",
)
subscriber_node = Node(
package="bme_ros2_tutorials_py",
executable="py_subscriber",
name="my_subscriber",
)
ld.add_action(publisher_node)
ld.add_action(subscriber_node)
return ld
Don't forget to rebuild the workspace so the changed launchfile will be installed, after that we can run it!
david@david-ubuntu24:~$ ros2 launch bme_ros2_tutorials_bringup publisher_subscriber.py
[INFO] [launch]: All log files can be found below /home/david/.ros/log/2024-09-29-14-20-15-603371-david-ubuntu24-41380
[INFO] [launch]: Default logging verbosity is set to INFO
[INFO] [py_publisher-1]: process started with pid [41383]
[INFO] [py_subscriber-2]: process started with pid [41384]
[py_publisher-1] [INFO] [1727612415.811451529] [my_publisher]: Publishing: "Hello, world: 0"
[py_subscriber-2] [INFO] [1727612415.811459737] [my_subscriber]: Subsciber has been started.
[py_subscriber-2] [INFO] [1727612415.811878677] [my_subscriber]: I heard: Hello, world: 0
[py_publisher-1] [INFO] [1727612416.313222973] [my_publisher]: Publishing: "Hello, world: 1"
[py_subscriber-2] [INFO] [1727612416.315340170] [my_subscriber]: I heard: Hello, world: 1
We can see that both nodes started and their logging to the standard output is combined in this single terminal window.
We can verify this with node list
or using rqt_graph
visually:
david@david-ubuntu24:~$ ros2 node list
/my_publisher
/my_subscriber
We can also verify the used topics with the topic list
tool:
david@david-ubuntu24:~$ ros2 topic list
/parameter_events
/rosout
/topic
But with launch files we can not just rename our nodes, we can also re-map topics, let's try to remap the existing /topic
to /another_topic
:
Let's add remapping to the publisher:
publisher_node = Node(
package="bme_ros2_tutorials_py",
executable="py_publisher",
name="my_publisher",
remappings=[
("topic", "another_topic")
]
)
After build we can run the modified launch file and verify the topics with topic list
:
david@david-ubuntu24:~$ ros2 topic list
/another_topic
/parameter_events
/rosout
/topic
Also our subsriber's callback function is not triggered because it's still listening to the /topic
while the publisher sends its messages to /another_topic
, we can see it visually that our two nodes are now unconnected with rqt_grap
:
We can also use the node info
cli tool to check what are the published topics and the subscriptions for a specific node:
ros2 node info /my_publisher
Add re-mapping in the same way to the subscriber, too:
...
remappings=[
("topic", "another_topic")
]
...
And we'll see that they are connected again, through the /another_topic
.
Now let's add more publishers and subscribers, also start mixing our C++ and python nodes:
from launch import LaunchDescription
from launch_ros.actions import Node
def generate_launch_description():
ld = LaunchDescription()
cpp_publisher_node = Node(
package="bme_ros2_tutorials_cpp",
executable="publisher_cpp",
name="my_cpp_publisher",
)
py_publisher_node = Node(
package="bme_ros2_tutorials_py",
executable="py_publisher",
name="my_py_publisher",
remappings=[
("topic", "another_topic")
]
)
py_subscriber_node1 = Node(
package="bme_ros2_tutorials_py",
executable="py_subscriber",
name="my_py_subscriber1",
)
py_subscriber_node2 = Node(
package="bme_ros2_tutorials_py",
executable="py_subscriber_oop",
name="my_py_subscriber2",
)
cpp_subscriber_node1 = Node(
package="bme_ros2_tutorials_cpp",
executable="subscriber_cpp",
name="my_cpp_subscriber1",
remappings=[
("topic", "another_topic")
]
)
ld.add_action(cpp_publisher_node)
ld.add_action(py_publisher_node)
ld.add_action(py_subscriber_node1)
ld.add_action(py_subscriber_node2)
ld.add_action(cpp_subscriber_node1)
return ld
Rebuild the workspace and let's see them visually with rqt_graph
:
ROS2 provides an interface to custom parameters of nodes, we can list the parameters, get or set their value with the param list
, param get
and param set
cli tools.
Let's see what kind of parameters do we have for our existing nodes, start our C++ publisher:
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_cpp publisher_cpp
And in a separate terminal execute ros2 param list /cpp_publisher
:
david@david-ubuntu24:~$ ros2 param list /cpp_publisher
qos_overrides./parameter_events.publisher.depth
qos_overrides./parameter_events.publisher.durability
qos_overrides./parameter_events.publisher.history
qos_overrides./parameter_events.publisher.reliability
start_type_description_service
use_sim_time
Although this list a couple of parameters, these are default parameters that were set up by the ROS2 C++ API, let's write another python publisher node where this time we add a parameter with the ROS2 API. Let's use our OOP publisher as the template:
#!/usr/bin/env python3
import rclpy
from rclpy.node import Node
from std_msgs.msg import String
class MyPublisherNode(Node):
def __init__(self):
super().__init__("python_publisher_with_parameter")
self.declare_parameter("published_text", "MOGI") # Add a parameter with a default value
self.text_ = self.get_parameter("published_text").value # Copy the parameter value into the text_ variable
self.publisher_ = self.create_publisher(String, 'topic', 10)
self.timer = self.create_timer(0.5, self.timer_callback)
self.i = 0
self.msg = String()
self.get_logger().info("Publisher OOP has been started.")
def timer_callback(self):
self.msg.data = f"{self.text_}: {self.i}" # use the text_ variable for the String message
self.i += 1
self.get_logger().info(f'Publishing: "{self.msg.data}"')
self.publisher_.publish(self.msg)
def main(args=None):
rclpy.init(args=args)
node = MyPublisherNode()
rclpy.spin(node)
node.destroy_node()
rclpy.shutdown()
if __name__ == "__main__":
main()
Now, let's see the parameters with the param list
tool:
david@david-ubuntu24:~$ ros2 param list /python_publisher_with_parameter
published_text
start_type_description_service
use_sim_time
The published_text
parameter is now visible for ROS2.
Parameter handling is a key difference between ROS1 and ROS2, in ROS1 it was a centralized functionality of the ROS master (
ros_core
), every node reported it's parameters to the global parameter server and we could change their parameters only through this parameter server. In ROS2, there is no parameter server anymore and the handling of parameters is node-specific and decentralized.
Let's see how can we get the value of this parameter using param get
tool:
david@david-ubuntu24:~$ ros2 param get /python_publisher_with_parameter published_text
String value is: MOGI
Now let's try to modify the parameter value from MOGI
to BME
:
ros2 param set /python_publisher_with_parameter published_text BME
As we experience it doesn't work because we set the self.text_
variable in the constructor, so it's value is not dynamically read from the parameter set by the API.
This is not necessarily a mistake, if we only want to set these parameters at startup instead of changing them runtime. For example setting up a topic's name or the frequency of a timer is often used as startup parameters.
This time we want to dynamically change the text so let's move this line into the timer_callback()
instead of the constructor:
self.text_ = self.get_parameter("published_text").value
Rebuild the workspace, start the node and modify the parameter as before. As we expected we could change the published text runtime through the ROS2 param
API.
[INFO] [1727616903.755729829] [python_publisher_with_parameter]: Publishing: "MOGI: 3"
[INFO] [1727616904.254593308] [python_publisher_with_parameter]: Publishing: "MOGI: 4"
[INFO] [1727616904.754490094] [python_publisher_with_parameter]: Publishing: "BME: 5"
[INFO] [1727616905.255873125] [python_publisher_with_parameter]: Publishing: "BME: 6"
Now, let's create a new launch file (publisher_param.py
) that starts our latest node with a custom parameter.
#!/usr/bin/env python3
from launch import LaunchDescription
from launch_ros.actions import Node
def generate_launch_description():
ld = LaunchDescription()
cpp_publisher_node = Node(
package="bme_ros2_tutorials_py",
executable="python_publisher_with_parameter",
name="my_publisher",
parameters=[{"published_text": "Parameter_from_launch"}]
)
ld.add_action(cpp_publisher_node)
return ld
Rebuild the workspace and launch the file:
david@david-ubuntu24:~$ ros2 launch bme_ros2_tutorials_bringup publisher_param.py
[INFO] [launch]: All log files can be found below /home/david/.ros/log/2024-09-29-15-50-33-210526-david-ubuntu24-44682
[INFO] [launch]: Default logging verbosity is set to INFO
[INFO] [py_publisher_with_param-1]: process started with pid [44685]
[py_publisher_with_param-1] [INFO] [1727617833.429100542] [my_publisher]: Publisher OOP has been started.
[py_publisher_with_param-1] [INFO] [1727617833.926650915] [my_publisher]: Publishing: "Parameter_from_launch: 0"
[py_publisher_with_param-1] [INFO] [1727617834.426182680] [my_publisher]: Publishing: "Parameter_from_launch: 1"
Some parameters are usually set in the constructor like a topic's name or the frequency of a publisher. Now let's see a more advanced example for changing the frequency runtime. Using this for changing a period is more a workaround than an API feature. On parameter change we will cancel the existing timer and start another one with the new parameter. Let's upgrade our exisiting node with the changes:
#!/usr/bin/env python3
import rclpy
from rclpy.node import Node
from std_msgs.msg import String
from rcl_interfaces.msg import SetParametersResult
class MyPublisherNode(Node):
def __init__(self):
super().__init__("python_publisher_with_parameter")
self.declare_parameter("published_text", "MOGI") # Add a parameter with a default value
self.declare_parameter("timer_period", 1.0) # Add the timer_period parameter with default 1s
self.timer_period = self.get_parameter('timer_period').value # Get the startup value of the timer_period
self.publisher_ = self.create_publisher(String, 'topic', 10)
# Use the startup value of self.timer_period to start a timer
self.timer = self.create_timer(self.timer_period, self.timer_callback)
# Set a callback to listen for changes to the 'timer_period' parameter
self.add_on_set_parameters_callback(self.update_timer_period_callback)
self.i = 0
self.msg = String()
self.get_logger().info("Publisher OOP has been started.")
def timer_callback(self):
self.text_ = self.get_parameter("published_text").value # Copy the parameter value into the text_ variable
self.msg.data = f"{self.text_}: {self.i}" # use the text_ variable for the String message
self.i += 1
self.get_logger().info(f'Publishing: "{self.msg.data}"')
self.publisher_.publish(self.msg)
def update_timer_period_callback(self, params):
result = SetParametersResult(successful=True)
for param in params:
if param.name == 'timer_period' and param.type_ == rclpy.Parameter.Type.DOUBLE:
new_period = param.value
self.get_logger().info(f'Updating timer period to {new_period} seconds')
# Cancel the old timer and create a new one with the updated period
self.timer.cancel() # Cancel the existing timer
self.timer = self.create_timer(new_period, self.timer_callback) # Create a new timer
return result
# Return success, so updates are seen via get_parameter()
return result
def main(args=None):
rclpy.init(args=args)
node = MyPublisherNode()
rclpy.spin(node)
node.destroy_node()
rclpy.shutdown()
if __name__ == "__main__":
main()
If we want we can change the startup parameter for the period from a launch file by adding another parameter:
...
parameters=[{"published_text": "Parameter_from_launch"},
{"timer_period": 0.5}]
...
Don't forget to rebuild the workspace and let's see what happens if we run the following command:
david@david-ubuntu24:~$ ros2 param set /python_publisher_with_parameter timer_period 5.0
Set parameter successful
In our other terinal:
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_py python_publisher_with_parameter
[INFO] [1727620325.796053193] [python_publisher_with_parameter]: Publisher OOP has been started.
...
[INFO] [1727620335.792876945] [python_publisher_with_parameter]: Publishing: "MOGI: 9"
[INFO] [1727620335.894037660] [python_publisher_with_parameter]: Updating timer period to 5.0 seconds
[INFO] [1727620340.897785232] [python_publisher_with_parameter]: Publishing: "MOGI: 10"
[INFO] [1727620345.895518460] [python_publisher_with_parameter]: Publishing: "MOGI: 11"
Previously we met the publish-subscribe communication model, as a recap let's see how we defined it in the beginning of this lesson:
Publish-subscribe models are asynchronous, one-to-many or many-to-many interactions where the publishers don't know how many subscribers there are (if any). Therefore publisher never expects any response or confirmation from the subscribers.
Services are the opposite in many ways and are suitable for different use-cases:
- Services are synchronous communications where a client sends a request to the server, the server processes the request and returns a response.
- This is a one-to-one only interaction.
- The communication only ends when the request was handled and response is returned.
- Services are suitable for one-time and request-response operations.
Before we write a server or client we have to create the service definition. In ROS2 usually we place custom messages, services and actions in a separate package. Let's create the bme_ros2_tutorials_interfaces
package:
ros2 pkg create bme_ros2_tutorials_interfaces
The package must be an ament_cmake
package, we can either define it with --build-type ament_cmake
in the pkg create
command or we can rely on the default settings of it.
Let's create an srv
folder, we will store our service here and we are free to delete the src
and include
folders.
In the srv
folder we create a our service file CustomCalc.srv
with the following request-response structure:
int64 a
int64 b
---
int64 result
We have to edit CMakeLists.txt
, add the following lines:
find_package(rosidl_default_generators REQUIRED)
rosidl_generate_interfaces(${PROJECT_NAME}
"srv/CustomCalc.srv"
)
And also edit packge.xml
, add the following lines:
<buildtool_depend>rosidl_default_generators</buildtool_depend>
<exec_depend>rosidl_default_runtime</exec_depend>
<member_of_group>rosidl_interface_packages</member_of_group>
Then we can build the workspace. And we also have to source the environment because we added a new package!
We can verify if our service was successfully created with the ros2 interface package
cli tool:
david@david-ubuntu24:~$ ros2 interface package bme_ros2_tutorials_interfaces
bme_ros2_tutorials_interfaces/srv/CustomCalc
If it shows the name of our service we can even look inside with the interface show
tool:
david@david-ubuntu24:~$ ros2 interface show bme_ros2_tutorials_interfaces/srv/CustomCalc
int64 a
int64 b
---
int64 result
Create the following python node service_server.py
:
#!/usr/bin/env python3
from bme_ros2_tutorials_interfaces.srv import CustomCalc # Import our own custom service
import rclpy
from rclpy.node import Node
class MyService(Node):
def __init__(self):
super().__init__('my_service')
# Create a service server with a callback function
self.srv = self.create_service(CustomCalc, 'custom_calc', self.custom_calc_callback)
# A service callback has request and response parameters
def custom_calc_callback(self, request, response):
response.result = request.a + request.b
self.get_logger().info('Incoming request\na: %d b: %d' % (request.a, request.b))
return response
def main():
rclpy.init()
my_service_server = MyService()
rclpy.spin(my_service_server)
rclpy.shutdown()
if __name__ == '__main__':
main()
We have to add the new entry point to the setup.py
:
'py_service_server = scripts.service_server:main'
And we also have to edit package.xml
because now our package depends on our other interface package:
<depend>bme_ros2_tutorials_interfaces</depend>
Rebuild the workspace and run the new node:
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_py py_service_server
Now our node is running in the background waiting for a service call. Before we write our service client we can test it with rqt
, we can add the Service Caller
plugin, set the a
and b
parameters and call it.
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_py py_service_server
[INFO] [1727625404.997418704] [my_service]: Incoming request
a: 5 b: 2
If you are interested in writing a service server in C++ you can check out the official tutorials about it.
Create the following python node service_client.py
:
#!/usr/bin/env python3
import sys
from bme_ros2_tutorials_interfaces.srv import CustomCalc # Import our own custom service
import rclpy
from rclpy.node import Node
class MyServiceClientAsync(Node):
def __init__(self):
super().__init__('my_service_client_async')
# Create a service client
self.cli = self.create_client(CustomCalc, 'custom_calc')
# Check if service server is online
while not self.cli.wait_for_service(timeout_sec=1.0):
self.get_logger().info('service not available, waiting again...')
# Create the service request
self.req = CustomCalc.Request()
def send_request(self, a, b):
self.req.a = a
self.req.b = b
# Call the service with the 2 parameters in the request and return result
return self.cli.call_async(self.req)
def main():
rclpy.init()
my_service_client = MyServiceClientAsync()
future = my_service_client.send_request(int(sys.argv[1]), int(sys.argv[2]))
# Spin only until response arrives
rclpy.spin_until_future_complete(my_service_client, future)
response = future.result()
my_service_client.get_logger().info(
'Result of custom_calc: for %d + %d = %d' %
(int(sys.argv[1]), int(sys.argv[2]), response.result))
my_service_client.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()
We have to add the new entry point to the setup.py
:
'py_service_client = scripts.service_client:main'
Rebuild the workspace then first, start the service server:
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_py py_service_server
Then run the service client with 2 numbers as command line arguments:
david@david-ubuntu24:~$ ros2 run bme_ros2_tutorials_py py_service_client 3 4
[INFO] [1727626843.911245336] [my_service_client_async]: Result of custom_calc: for 3 + 4 = 7
Let's return to turtlesim
, now we understand the ROS2 parameters and service calls. Start turtlesim
in a terminal window:
ros2 run turtlesim turtlesim_node
Then run the turtle_teleop_key
in another terminal window:
ros2 run turtlesim turtle_teleop_key
And start rqt
in a 3rd terminal window. Now let's drive the turtle around, then we can play with the /clear
and /turtle1/set_pen
services.
In another terminal window we can also check out turtlesim
's parameters. First let's see what kind of parameters does it have:
david@david-ubuntu24:~$ ros2 param list /turtlesim
background_b
background_g
background_r
holonomic
qos_overrides./parameter_events.publisher.depth
qos_overrides./parameter_events.publisher.durability
qos_overrides./parameter_events.publisher.history
qos_overrides./parameter_events.publisher.reliability
start_type_description_service
use_sim_time
Then let's see for example background_b
parameter:
david@david-ubuntu24:~$ ros2 param get /turtlesim background_b
Integer value is: 255
And now let's try to change is:
david@david-ubuntu24:~/ros2_ws$ ros2 param set /turtlesim background_b 50
Set parameter successful
Before we deep dive into the simulation environment, let's do a recap about the most important Linux and ROS2 commands.
Command | Description |
---|---|
sudo |
execute commands with elevated privileges |
apt |
Debian based distributions' package manager |
apt update |
updates the local package index from the online repositories |
apt upgrade |
It installs the new versions of packages based on the information from apt update |
nano |
simple text editor that operated inside a terminal |
ls |
list the contents of a directory |
cd |
change the current directory |
~ |
tilde represents the user's home directory, can be used together with ls or cd |
mkdir |
create a new directory |
rm -rf |
rm removes a file or an empty folder -r means recursive (useful for folder systems) and -f is force deletion without prompting |
touch |
creates a new file |
chmod +x |
make a file executable |
tree |
list the contents of the file system under the current directory |
Command | Description |
---|---|
ros2 node list, info |
list or obtain more information about node(s) |
ros2 topic list, info, echo |
list or obtain more information about topic(s), echo can subscribe onto a topic within the terminal window |
ros2 run *package* *node* |
starts a ROS2 node from a certain package |
ros2 pkg create |
create a ROS2 package, we can define the --build-type to ament_cmake or ament_python build system for the package |
rqt |
opens rqt a graphical tool to intercat with topics, services and more |
rqt_graph |
a visual tool to see the pub-sub connections between nodes |
colcon build |
builds the worspace |
source /opt/ros/jazzy/setup.bash |
source ROS2 environment, it's recommended to put into .bashrc |
ros2 launch *package* *launchfile* |
starts a ROS2 launch file from a crtain package |
ros2 param list, get, set |
list, get or set the parameters of a node |
ros2 interface package, show |
list or obtain more information about the services of a package |