rosrust is a pure Rust implementation of a ROS client library.
For all the key features, it is enough to depend on the crate itself. It's highly recommended to depend on rosrust_msg
as well, as it provides bindings for message generation.
The following dependencies are recommended to use the crate:
[dependencies]
rosrust = "0.9"
rosrust_msg = "0.1"
If using Rust 2015 edition, just depend on the library with macro usage, using:
#[macro_use]
extern crate rosrust;
Examples are written using Rust 2018, as it's the expected edition to use now.
rosrust is almost there with implementing all features of a ROS Client Library by fulfilling ROS requirements for implementing client libraries which are given in a more detailed form in the technical overview.
Mostly the missing features are related to extra tooling, like sensor_msgs/PointCloud2
and sensor_msgs/Image
encoding/decoding, TF tree handling, and other things that are external libraries in roscpp
and rospy
as well.
The API is very close to the desired final look.
Integration with catkin will be handled once a satisfying set of features has been implemented.
The API is close to reaching its final form.
There are multiple examples in the examples folder. The publisher/subscriber and service/client examples are designed to closely imitate the roscpp
tutorial.
Message generation can be done automatically by depending on rosrust_msg
, or manually using rosrust::rosmsg_include
.
The preferred way is automatic, as it allows interop between dependencies that use messages and your crate.
If you do not have ROS installed, then the message generation utilizes the ROSRUST_MSG_PATH
environment variable, which is a colon separated list of directories to search.
These directories should have the structure <ROSRUST_MSG_PATH>/<anything>/<package>/msg/<message>
or <ROSRUST_MSG_PATH>/<anything>/<package>/srv/<service>
.
For automatic message generation just depend on rosrust_msg
, with the version specified at the top of this document.
After that you'll be able to generate a sensor_msgs/Imu
message object by using rosrust_msg::sensor_msgs::Imu::default()
. All fields are always public, so you can initialize structures as literals.
Message generation is done at build time. If you have ROS installed and sourced in your shell session, you will not need to do any extra setup for this to work.
To generate messages, create a module for messages. Using something like a msg.rs
file in your project root results in importing similar to roscpp
and rospy
. The file only needs one line:
// If you wanted
// * messages: std_msgs/String, sensor_msgs/Imu
// * services: roscpp_tutorials/TwoInts
// * and all the message types used by them, like geometry_msgs/Vector3
rosrust::rosmsg_include!(std_msgs/String,sensor_msgs/Imu,roscpp_tutorials/TwoInts);
Just add this file to your project and you're done.
If you have put this in a src/msg.rs
file, this will include all the generated structures, and add them to the msg
namespace. Thus, to create a new sensor_msgs/Imu
, you call msg::sensor_msgs::Imu::default()
. All fields are always public, so you can initialize structures as literals.
If we wanted to publish a defined message (let's use std_msgs/String
) to topic chatter
ten times a second, we can do it in the following way.
fn main() {
// Initialize node
rosrust::init("talker");
// Create publisher
let chatter_pub = rosrust::publish("chatter", 100).unwrap();
let mut count = 0;
// Create object that maintains 10Hz between sleep requests
let rate = rosrust::rate(10.0);
// Breaks when a shutdown signal is sent
while rosrust::is_ok() {
// Create string message
let mut msg = rosrust_msg::std_msgs::String::default();
msg.data = format!("hello world {}", count);
// Send string message to topic via publisher
chatter_pub.send(msg).unwrap();
// Sleep to maintain 10Hz rate
rate.sleep();
count += 1;
}
}
If we wanted to subscribe to an std_msgs/UInt64
topic some_topic
, we just declare a callback. An alternative extra interface with iterators is being considered, but for now this is the only option.
The constructor creates an object, which represents the subscriber lifetime. Upon the destruction of this object, the topic is unsubscribed as well.
fn main() {
// Initialize node
rosrust::init("listener");
// Create subscriber
// The subscriber is stopped when the returned object is destroyed
let _subscriber_raii = rosrust::subscribe("chatter", 100, |v: rosrust_msg::std_msgs::UInt64| {
// Callback for handling received messages
rosrust::ros_info!("Received: {}", v.data);
}).unwrap();
// Block the thread until a shutdown signal is received
rosrust::spin();
}
Creating a service is the easiest out of all the options. Just define a callback for each request. Let's use the roscpp_tutorials/AddTwoInts
service on the topic /add_two_ints
.
fn main() {
// Initialize node
rosrust::init("add_two_ints_server");
// Create service
// The service is stopped when the returned object is destroyed
let _service_raii =
rosrust::service::<rosrust_msg::roscpp_tutorials::TwoInts, _>("add_two_ints", move |req| {
// Callback for handling requests
let sum = req.a + req.b;
// Log each request
rosrust::ros_info!("{} + {} = {}", req.a, req.b, sum);
Ok(rosrust_msg::roscpp_tutorials::TwoIntsRes { sum })
}).unwrap();
// Block the thread until a shutdown signal is received
rosrust::spin();
}
Clients can handle requests synchronously and asynchronously. The sync method behaves like a function, while the async approach is via reading data afterwards. The async consumes the passed parameter, since we're passing the parameter between threads. It's more common for users to pass and drop a parameter, so this being the default prevents needless cloning.
Let's call requests from the AddTwoInts
service on the topic /add_two_ints
.
The numbers shall be provided as command line arguments.
We're also depending on env_logger
here to log ros_info
messages to the standard output.
use std::{env, time};
fn main() {
env_logger::init();
// Fetch args that are not meant for rosrust
let args: Vec<_> = rosrust::args();
if args.len() != 3 {
eprintln!("usage: client X Y");
return;
}
let a = args[1].parse::<i64>().unwrap();
let b = args[2].parse::<i64>().unwrap();
// Initialize node
rosrust::init("add_two_ints_client");
// Wait ten seconds for the service to appear
rosrust::wait_for_service("add_two_ints", Some(time::Duration::from_secs(10))).unwrap();
// Create client for the service
let client = rosrust::client::<rosrust_msg::roscpp_tutorials::TwoInts>("add_two_ints").unwrap();
// Synchronous call that blocks the thread until a response is received
ros_info!(
"{} + {} = {}",
a,
b,
client
.req(&rosrust_msg::roscpp_tutorials::TwoIntsReq { a, b })
.unwrap()
.unwrap()
.sum
);
// Asynchronous call that can be resolved later on
let retval = client.req_async(rosrust_msg::roscpp_tutorials::TwoIntsReq { a, b });
rosrust::ros_info!("{} + {} = {}", a, b, retval.read().unwrap().unwrap().sum);
}
There are a lot of methods provided, so we'll just give a taste of all of them here. Get requests return results, so you can use unwrap_or
to handle defaults.
We're also depending on env_logger
here to log ros_info
messages to the standard output.
fn main() {
env_logger::init();
// Initialize node
rosrust::init("param_test");
// Create parameter, go through all methods, and delete it
let param = rosrust::param("~foo").unwrap();
rosrust::ros_info!("Handling ~foo:");
rosrust::ros_info!("Exists? {:?}", param.exists()); // false
param.set(&42u64).unwrap();
rosrust::ros_info!("Get: {:?}", param.get::<u64>().unwrap());
rosrust::ros_info!("Get raw: {:?}", param.get_raw().unwrap());
rosrust::ros_info!("Search: {:?}", param.search().unwrap());
rosrust::ros_info!("Exists? {}", param.exists().unwrap());
param.delete().unwrap();
rosrust::ros_info!("Get {:?}", param.get::<u64>().unwrap_err());
rosrust::ros_info!("Get with default: {:?}", param.get::<u64>().unwrap_or(44u64));
rosrust::ros_info!("Exists? {}", param.exists().unwrap());
}
Logging is provided through macros ros_debug!()
, ros_info!()
, ros_warn!()
, ros_error!()
, ros_fatal!()
.
Setting verbosity levels and throttled logging have yet to come!
Similar to rospy
and roscpp
, you can use the command line to remap topics and private parameters. Private parameters should be provided in a YAML format.
For more information, look at the official wiki, since the attempt was to 100% immitate this interface.
You can get a vector of the leftover command line argument strings with rosrust::args()
, allowing easy argument parsing. This includes the first argument, the application name.
rosrust is distributed under the MIT license.