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Only released in EOL distros:  

Package Summary

rosR

Package Summary

rosR

Package Summary

rosR

Package Summary

The rosR package

  • Maintainer status: maintained
  • Maintainer: Andre Dietrich <dietrich AT ivs.cs.uni-magdeburg DOT de>
  • Author:
  • License: BSD
  • Source: git https://gitlab.com/OvGU-ESS/rosR.git (branch: master)

http://svn.code.sf.net/p/ivs-ros-pkg/code/trunk/rosR/misc/rosR.png

Overview

This package provides an simple interface of standard ros-functionalities for the programming language R. We hope that it might be useful to make the R capabilities for statistical analyses and visualization also usable for the robotic community. In contrast to other language implementations, such as rospy, rosjava, etc. this is not a pure R implementation, it is a mixture of pure R, SWIG generated functions, and system commands. This combination was required to overcome some limitations of R, such as single threaded, lacking support for sockets and handling of raw streams. Nevertheless, this package can be used to define and use typical ROS publishers and subscribers in R, messages are automatically and online generated from the definition files, and it integrates the possibility to read and therefore analyse bag-files in R. We will explain this in more detail within the next sections.

See also rosR_demos.

Introduction

video ... comming soon

Installation

We divided this section into two parts. For those who come from the ROS side, it will be probably easy to install and to use this packet (of course they will probably have to cope with the R-code). Coming from the R side with no experience about ROS, it will be hard to install and run this package.

ROS-Side

If you have already some expertise on working with ROS, then you can install rosR just like any ordinary ros-package. Three additional dependencies are required before you can compile it:

$ sudo apt-get install swig3.0

$ sudo apt-get install r-base

$ sudo apt-get install r-cran-rcpp

Then simply download the rosR package via git from the repository and run catkin_make.

That's all folks!

R-Side

Within this subsection we will describe all steps that are required to install ros-groovy under an Ubuntu 12.04 32-bit (with long time support) and then our extension for the R-programming language (especially for users with totally no ROS experience). The first steps were taken from the manual (http://wiki/groovy/Installation/Ubuntu) and we guess, you already have installed Ubuntu on your PC.

Preparation

First of all we will have to add the required ros-repositories. Therefore simply copy and execute the following command in your terminal:

$ sudo sh -c 'echo "deb http://packages.ros.org/ros/ubuntu precise main" > /etc/apt/sources.list.d/ros-latest.list'

And afterwards set up the keys with:

$ wget http://packages.ros.org/ros.key -O - | sudo apt-key add -

Installing all Requirements

While the ROS-base installation should be sufficient enough to build and run rosR, we strongly recommend to use the desktop-install:

$ sudo apt-get install ros-groovy-desktop

There are also some other things necessary:

$ sudo apt-get install r-base      # R base system
$ sudo apt-get install r-cran-rcpp # the R-development package
$ sudo apt-get install swig2.0     # to generate the ros-wrapper for R
$ sudo apt-get install subversion  # svn, to be able to download our package

Environment Setup

To be able to run ROS commands and to build our package, you now will have to set some environment parameters. So choose your preferred editor (in our case vim) to edit the .bashrc. Insert at the end of the .bashrc the following statements:

# to set all required variables
source /opt/ros/groovy/setup.bash
export ROS_MASTER_URI=http://localhost:11311/
# this is the path where we will install and run our local packages
export ROS_PACKAGE_PATH=$HOME/ros-projects:$ROS_PACKAGE_PATH

To instantiate all required variables, simply run (this happens only once, afterwards all stuff is initialized automatically, due to the .bashrc)

$ source ~/.bashrc

For sake of completeness also run the following commands:

$ sudo rosdep init
$ rosdep update

Install rosR

Now we will have to create a local directory, where we will put in all of our local ros-packages. We already defined it within the .bashrc but now we will have to create it:

$ mkdir $HOME/ros-projects

and step into the your newly created package path:

$ cd $HOME/ros-projects

Download the rosR language extension from our repository via svn:

$ svn co http://svn.code.sf.net/p/ivs-ros-pkg/code/trunk/rosR

go into:

$ cd rosR

and finaly run

$ rosmake

If the compilation process is finished (and hopefully everything was okay, as in our case) you will be able to run the first examples with

$ roslaunch rosR random.launch

and if you had previously installed ros-desktop, then also the following example should work:

$ roslaunch rosR sensor.launch

Publish Subscribe

R–Publisher

Defining a publisher in R is nearly as simple as in Python. First of all you will have to load this package into your R environment, what can be done with the following command:

> source(paste(system("rospack find rosR",intern=T),"/lib/ros.R",sep=""),chdir=T)

This looks a bit complex, but have trust, this is the only complex command that is required. We did not develop a package that can be directly installed in R but more a ros package and therefore it can be somewhere on your systems, as ros packages do it normaly. Therefore the commandline program rospack is involved to find the location of your rosR installation. But thats all, now you can use all of our ros-functions in R.

As in most programs you start with the initialization of your new ros node and so we do:

> ros.Init("R_node")

And the new node appears... Let us now generate the publisher:

> publisher <- ros.Publisher("chatter", "std_msgs/String")

Simply call ros.Publisher with the new topic, in our case “chatter”, and the message type that is transmitted “std_msgs/String”. In the same way it is also possible to define a new message:

> message <- ros.Message("std_msgs/String")

Messages in our case are always defined as list, that may include further list. So it is possible to set and get messages values in a similar war, as you know you know it from other ros language implementations:

> message$data <- "hello world"

Now we can pass this message to the publisher as follows:

> ros.WriteMessage(publisher, message)

And that was all … cange the content of your message and republish it:

> message$data <- "hello world"

Have look at some complete examples in folder nodes/test/publisher.R

R-Subscriber

Creating a subscriber is as simple creating a publisher. At first you have to load the package, initialize the node and then create the subscriber:

> source(paste(system("rospack find rosR",intern=T),"/lib/ros.R",sep=""),chdir=T)
> ros.Init("R_node2")
> subscriber <- ros.Subscriber("chatter", "std_msgs/String")

As mentioned before, R is single threaded, and calling callback functions is nearly not possible. To circumvent this tiny drawback, you have to poll, if a new messages was received or not. Therefore, you have to call:

> ros.SpinOnce()
NULL

to fill the subscriber with possibly new messages. The receipt of a new message can than be identified by calling the following method:

> ros.SubscriberHasNewMessage(subscriber)
[1] TRUE

This function call will return TRUE if a new message was received otherwise FALSE. If a new message was received, this can simply be read with:

> message <- ros.ReadMessage(subscriber)
> print(message$data)
[1] hello world

Check out the examples in folder rosR/nodes.

Messages

The subscriber generates automatically the correct message format. If you publish a message it is recommended to use function:

> msg <- ros.Message("std_msgs/String")

If you want to get a message of another format, like for example a laserscan, you wil get the following result:

> msg <- ros.Message("sensor_msgs/LaserScan")

A message in this case is always a composition of lists, therefor single elements are accessed with "$". Thus, the structure of a message is quite similar to the structures in other languages, but instead of a point, you have to use a dollar. Changing and reading the header sequence would than be done as follows:

> print(msg$header$seq)
[[1]]
integer(0)
> msg$header$seq <- 100
> print(msg$header$seq)
[1] 100

The handling of arrays is a bit tricky, because in the background these are handled as C structures std::vector. Thus, the size of our new LaserScan is currently 0:

> length(msg$ranges)
[1] 0

and you can add new elements and read these values in the normal manner:

> append(msg$ranges, c(1,2,3,4,5,6,7))
> length(msg$ranges)
[1] 7
> msg$ranges[2:4]
[1] 2 3 4
> msg$ranges[2:4] <- c(4,3,2)
> msg$ranges
[1] 1 4 3 2 5 6 7

But calling functions like sum(msg$ranges) or median(msg$ranges) will not work, unless you define it in file lib/std_vector.R, or you call:

> sum(scan$ranges[1:7])
[1] 28
> median(scan$ranges[1:7])
[1] 4

This generates a copy of the structures within the std::vector and returns a R vector:

> typeof(msg$ranges)
[1] "S4"
> typeof(msg$ranges[1:7])
[1] "double"

Otherwise it would slow down the conversion of messages, just think of a camera image with 800x600 pixels with 24bits … The handling of std::vectors in R is defined in lib/std_vector.R you are free to add new functionality ...

Other Functions

Bag-Files

At the moment it is only possible to load bagfiles into R. Use therefore the following function:

> bag <- ros.BagRead(file, c("topic_1", "topic_2", ..., "topic_n"))

You will receive a list, containing the messages, the timestamps, topics, and datatypes of every message:

> bag$topic[2]
> bag$message[2]$... # handled in the same way, as a normal message
> bag$datatype[2]

Misc

There is also other functionality defined in src/ros.cpp and lib/ros.R like:

> ros.TimeNow()
> ros.Info("info")
> ros.Debug("...")
> ros.Error("...")
> ros.Warn("...")

<<Hits: execution failed [decimal] (see also the log)>>/<<Hits: execution failed [decimal] (see also the log)>>


2024-11-09 16:11