Python functions
The #[pyfunction]
attribute is used to define a Python function from a Rust function. Once defined, the function needs to be added to a module using the wrap_pyfunction!
macro.
The following example defines a function called double
in a Python module called my_extension
:
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyfunction] fn double(x: usize) -> usize { x * 2 } #[pymodule] fn my_extension(py: Python<'_>, m: &PyModule) -> PyResult<()> { m.add_function(wrap_pyfunction!(double, m)?)?; Ok(()) } }
This chapter of the guide explains full usage of the #[pyfunction]
attribute. In this first section, the following topics are covered:
There are also additional sections on the following topics:
Function options
The #[pyo3]
attribute can be used to modify properties of the generated Python function. It can take any combination of the following options:
-
Overrides the name exposed to Python.
In the following example, the Rust function
no_args_py
will be added to the Python modulemodule_with_functions
as the Python functionno_args
:#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyfunction] #[pyo3(name = "no_args")] fn no_args_py() -> usize { 42 } #[pymodule] fn module_with_functions(py: Python<'_>, m: &PyModule) -> PyResult<()> { m.add_function(wrap_pyfunction!(no_args_py, m)?)?; Ok(()) } Python::with_gil(|py| { let m = pyo3::wrap_pymodule!(module_with_functions)(py); assert!(m.getattr(py, "no_args").is_ok()); assert!(m.getattr(py, "no_args_py").is_err()); }); }
-
Defines the function signature in Python. See Function Signatures.
-
#[pyo3(text_signature = "...")]
Overrides the PyO3-generated function signature visible in Python tooling (such as via
inspect.signature
). See the corresponding topic in the Function Signatures subchapter. -
Set this option to make PyO3 pass the containing module as the first argument to the function. It is then possible to use the module in the function body. The first argument must be of type
&PyModule
.The following example creates a function
pyfunction_with_module
which returns the containing module's name (i.e.module_with_fn
):#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyfunction] #[pyo3(pass_module)] fn pyfunction_with_module(module: &PyModule) -> PyResult<&str> { module.name() } #[pymodule] fn module_with_fn(py: Python<'_>, m: &PyModule) -> PyResult<()> { m.add_function(wrap_pyfunction!(pyfunction_with_module, m)?) } }
Per-argument options
The #[pyo3]
attribute can be used on individual arguments to modify properties of them in the generated function. It can take any combination of the following options:
-
Set this on an option to specify a custom function to convert the function argument from Python to the desired Rust type, instead of using the default
FromPyObject
extraction. The function signature must befn(&PyAny) -> PyResult<T>
whereT
is the Rust type of the argument.The following example uses
from_py_with
to convert the input Python object to its length:#![allow(unused)] fn main() { use pyo3::prelude::*; fn get_length(obj: &PyAny) -> PyResult<usize> { let length = obj.len()?; Ok(length) } #[pyfunction] fn object_length( #[pyo3(from_py_with = "get_length")] argument: usize ) -> usize { argument } Python::with_gil(|py| { let f = pyo3::wrap_pyfunction!(object_length)(py).unwrap(); assert_eq!(f.call1((vec![1, 2, 3],)).unwrap().extract::<usize>().unwrap(), 3); }); }
Advanced function patterns
Calling Python functions in Rust
You can pass Python def
'd functions and built-in functions to Rust functions PyFunction
corresponds to regular Python functions while PyCFunction
describes built-ins such as
repr()
.
You can also use PyAny::is_callable
to check if you have a callable object. is_callable
will
return true
for functions (including lambdas), methods and objects with a __call__
method.
You can call the object with PyAny::call
with the args as first parameter and the kwargs
(or None
) as second parameter. There are also PyAny::call0
with no args and PyAny::call1
with only positional args.
Calling Rust functions in Python
The ways to convert a Rust function into a Python object vary depending on the function:
- Named functions, e.g.
fn foo()
: add#[pyfunction]
and then usewrap_pyfunction!
to get the correspondingPyCFunction
. - Anonymous functions (or closures), e.g.
foo: fn()
either:- use a
#[pyclass]
struct which stores the function as a field and implement__call__
to call the stored function. - use
PyCFunction::new_closure
to create an object directly from the function.
- use a
Accessing the FFI functions
In order to make Rust functions callable from Python, PyO3 generates an extern "C"
function whose exact signature depends on the Rust signature. (PyO3 chooses the optimal
Python argument passing convention.) It then embeds the call to the Rust function inside this
FFI-wrapper function. This wrapper handles extraction of the regular arguments and the keyword
arguments from the input PyObject
s.
The wrap_pyfunction
macro can be used to directly get a PyCFunction
given a
#[pyfunction]
and a PyModule
: wrap_pyfunction!(rust_fun, module)
.
#[pyfn]
shorthand
There is a shorthand to #[pyfunction]
and wrap_pymodule!
: the function can be placed inside the module definition and
annotated with #[pyfn]
. To simplify PyO3, it is expected that #[pyfn]
may be removed in a future release (See #694).
An example of #[pyfn]
is below:
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pymodule] fn my_extension(py: Python<'_>, m: &PyModule) -> PyResult<()> { #[pyfn(m)] fn double(x: usize) -> usize { x * 2 } Ok(()) } }
#[pyfn(m)]
is just syntactic sugar for #[pyfunction]
, and takes all the same options
documented in the rest of this chapter. The code above is expanded to the following:
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pymodule] fn my_extension(py: Python<'_>, m: &PyModule) -> PyResult<()> { #[pyfunction] fn double(x: usize) -> usize { x * 2 } m.add_function(wrap_pyfunction!(double, m)?)?; Ok(()) } }