# Using reticulate in an R Package

If you write an R package that wraps one or more Python packages, it’s likely that you’ll be importing Python modules within the .onLoad method of your package so that you can have convenient access to them within the rest of the package source code.

When you do this, you should use the delay_load flag to the import() function, for example:

# global reference to scipy (will be initialized in .onLoad)
scipy <- NULL

# use superassignment to update global reference to scipy
scipy <<- reticulate::import("scipy", delay_load = TRUE)
}

Using the delay_load flag has two important benefits:

1. It allows you to successfully load your package even when Python / Python packages are not installed on the target system (this is particularly important when testing on CRAN build machines).

2. It allows users to specify a desired location for Python before interacting with your package. For example:

library(mypackage)
reticulate::use_virtualenv("~/pythonenvs/userenv")
# call functions from mypackage

Without the delay_load, Python would be loaded immediately and the user’s call to use_virtualenv would have no effect.

## Installing Python Dependencies

Your R package likely depends on the installation of one or more Python packages. As a convenience to your users, you may want to provide a high-level R function to allow users to install these Python packages. It’s furthermore beneficial if multiple R packages that depend on Python packages install their dependencies in the same Python environment (so that they can be easily used together).

The py_install() function provides a high-level interface for installing one or more Python packages. The packages will by default be installed within a virtualenv or Conda environment named “r-reticulate”. For example:

library(reticulate)
py_install("scipy")

You can document the use of this function along with your package or alternatively provide a wrapper function for py_install(). For example:

install_scipy <- function(method = "auto", conda = "auto") {
reticulate::py_install("scipy", method = method, conda = conda)
}

While reticulate is capable of binding to any Python environment available on a system, it’s much more straightforward for users if there is a common environment used by R packages with convenient high-level functions provided for installation. We therefore strongly recommend that R package developers use the approach described here.

## Checking and Testing on CRAN

If you use reticulate in another R package you need to account for the fact that when your package is submitted to CRAN, the CRAN test servers may not have Python, NumPy, or whatever other Python modules you are wrapping in your package. If you don’t do this then your package may fail to load and/or pass its tests when run on CRAN.

There are two things you should do to ensure your package is well behaved on CRAN:

1. Use the delay_load option (as described above) to ensure that the module (and Python) is loaded only on its first use. For example:

# python 'scipy' module I want to use in my package
scipy <- NULL

# delay load foo module (will only be loaded when accessed via $) scipy <<- import("scipy", delay_load = TRUE) } 2. When writing tests, check to see if your module is available and if it isn’t then skip the test. For example, if you are using the testthat package, you might do this: # helper function to skip tests if we don't have the 'foo' module skip_if_no_scipy <- function() { have_scipy <- py_module_available("scipy") if (!have_scipy) skip("scipy not available for testing") } # then call this function from all of your tests test_that("Things work as expected", { skip_if_no_scipy() # test code here... }) ## Implementing S3 Methods Python objects exposed by reticulate carry their Python classes into R, so it’s possible to write S3 methods to customize e.g. the str or print behavior for a given class (note that it’s not typically necessary that you do this since the default str and print methods call PyObject_Str, which typically provides an acceptable default behavior). If you do decide to implement custom S3 methods for a Python class it’s important to keep in mind that when an R session ends the connection to Python objects is lost, so when the .RData saved from one R session is restored in a subsequent R session the Python objects are effectively lost (technically they become NULL R externalptr objects). By default when you attempt to interact with a Python object from a previous session (a NULL R externalptr) an error is thrown. If you want to do something more customized in your S3 method you can use the py_is_null_xptr() function. For example: method.MyModule.MyPythonClass <- function(x, y, ...) { if (py_is_null_xptr(x)) # whatever is appropriate else # interact with the object } Note that this check isn’t required, as by default an R error will occur. If it’s desirable to avoid this error for any reason then you can use py_is_null_xptr() to do so. The reticulate package exports a py_str generic method which is called from the str method only after doing appropriate validation (if the object is NULL then <pointer: 0x0> is returned). You can implement the py_str method as follows: #' @importFrom reticulate py_str #' @export py_str.MyModule.MyPythonClass <- function(object, ...) { # interact with the object to generate the string } The print and summary methods for Python objects both call the str method by default, so if you implement py_str() you will automatically inherit implementations for those methods. ### Converting between R and Python reticulate provides the generics r_to_py() for converting R objects into Python objects, and py_to_r() for converting Python objects back into R objects. Package authors can provide methods for these generics to convert Python and R objects otherwise not handled by reticulate. reticulate provides conversion operators for some of the most commonly used Python objects, including: • Built-in Python objects (lists, dictionaries, numbers, strings, tuples) • NumPy arrays, • Pandas objects (Index, Series, DataFrame), • Python datetime objects. If you see that reticulate is missing support for conversion of one or more objects from these packages, please let us know and we’ll try to implement the missing converter. For Python packages not in this set, you can provide conversion operators in your own extension package. ### Writing your own r_to_py() methods r_to_py() accepts a convert argument, which controls how objects generated from the created Python object are converted. To illustrate, consider the difference between these two cases: library(reticulate) # [convert = TRUE] => convert Python objects to R when appropriate sys <- import("sys", convert = TRUE) class(sys$path)
# [1] "character"

# [convert = FALSE] => always return Python objects
sys <- import("sys", convert = FALSE)
class(sys\$path)
# [1] "python.builtin.list" "python.builtin.object"

This is accomplished through the use of a convert flag, which is set on the Python object wrappers used by reticulate. Therefore, if you’re writing a method r_to_py.foo() for an object of class foo, you should take care to preserve the convert flag on the generated object. This is typically done by:

1. Passing convert along to the appropriate lower-level r_to_py() method;

2. Explicitly setting the convert attribute on the returned Python object.

As an example of the second:

# suppose 'make_python_object()' creates a Python object
# from R objects of class 'my_r_object'.
r_to_py.my_r_object <- function(x, convert) {
object <- make_python_object(x)
assign("convert", convert, envir = object)
object
}

## Using Travis-CI

Travis-CI is a commonly used platform for continuous integration and testing of R packages. Making it work with reticulate is pretty simple - all you need to do is add a before_install section to a standard R .travis.yml file that asks Travis to guarantee the testing machine has numpy (which reticulate depends on) and any Python modules you’re interacting with that don’t ship with the language itself:

before_install:
- pip install numpy any_other_dependencies go_here