Migrating from older PyO3 versions
This guide can help you upgrade code through breaking changes from one PyO3 version to the next. For a detailed list of all changes, see the CHANGELOG.
from 0.15.* to 0.16
Drop support for older technologies
PyO3 0.16 has increased minimum Rust version to 1.48 and minimum Python version to 3.7. This enables use of newer language features (enabling some of the other additions in 0.16) and simplifies maintenance of the project.
### #[pyproto]
has been deprecated
In PyO3 0.15, the #[pymethods]
attribute macro gained support for implementing "magic methods" such as __str__
(aka "dunder" methods). This implementation was not quite finalized at the time, with a few edge cases to be decided upon. The existing #[pyproto]
attribute macro was left untouched, because it covered these edge cases.
In PyO3 0.16, the #[pymethods]
implementation has been completed and is now the preferred way to implement magic methods. To allow the PyO3 project to move forward, #[pyproto]
has been deprecated (with expected removal in PyO3 0.18).
Migration from #[pyproto]
to #[pymethods]
is straightforward; copying the existing methods directly from the #[pyproto]
trait implementation is all that is needed in most cases.
Before:
use pyo3::prelude::*;
use pyo3::class::{PyBasicProtocol, PyIterProtocol};
use pyo3::types::PyString;
#[pyclass]
struct MyClass { }
#[pyproto]
impl PyBasicProtocol for MyClass {
fn __str__(&self) -> &'static [u8] {
b"hello, world"
}
}
#[pyproto]
impl PyIterProtocol for MyClass {
fn __iter__(slf: PyRef<self>) -> PyResult<&PyAny> {
PyString::new(slf.py(), "hello, world").iter()
}
}
After
use pyo3::prelude::*;
use pyo3::types::PyString;
#[pyclass]
struct MyClass { }
impl MyClass {
fn __str__(&self) -> &'static [u8] {
b"hello, world"
}
fn __iter__(slf: PyRef<self>) -> PyResult<&PyAny> {
PyString::new(slf.py(), "hello, world").iter()
}
}
Removed PartialEq
for object wrappers
The Python object wrappers Py
and PyAny
had implementations of PartialEq
so that object_a == object_b
would compare the Python objects for pointer
equality, which corresponds to the is
operator, not the ==
operator in
Python. This has been removed in favor of a new method: use
object_a.is(object_b)
. This also has the advantage of not requiring the same
wrapper type for object_a
and object_b
; you can now directly compare a
Py<T>
with a &PyAny
without having to convert.
To check for Python object equality (the Python ==
operator), use the new
method eq()
.
Container magic methods now match Python behavior
In PyO3 0.15, __getitem__
, __setitem__
and __delitem__
in #[pymethods]
would generate only the mapping implementation for a #[pyclass]
. To match the Python behavior, these methods now generate both the mapping and sequence implementations.
This means that classes implementing these #[pymethods]
will now also be treated as sequences, same as a Python class
would be. Small differences in behavior may result:
- PyO3 will allow instances of these classes to be cast to
PySequence
as well asPyMapping
. - Python will provide a default implementation of
__iter__
(if the class did not have one) which repeatedly calls__getitem__
with integers (starting at 0) until anIndexError
is raised.
To explain this in detail, consider the following Python class:
class ExampleContainer:
def __len__(self):
return 5
def __getitem__(self, idx: int) -> int:
if idx < 0 or idx > 5:
raise IndexError()
return idx
This class implements a Python sequence.
The __len__
and __getitem__
methods are also used to implement a Python mapping. In the Python C-API, these methods are not shared: the sequence __len__
and __getitem__
are defined by the sq_len
and sq_item
slots, and the mapping equivalents are mp_len
and mp_subscript
. There are similar distinctions for __setitem__
and __delitem__
.
Because there is no such distinction from Python, implementing these methods will fill the mapping and sequence slots simultaneously. A Python class with __len__
implemented, for example, will have both the sq_len
and mp_len
slots filled.
The PyO3 behavior in 0.16 has been changed to be closer to this Python behavior by default.
wrap_pymodule!
now respects privacy correctly
Prior to PyO3 0.16 the wrap_pymodule!
macro could use modules declared in Rust modules which were not reachable.
For example, the following code was legal before 0.16, but in 0.16 is rejected because the wrap_pymodule!
macro cannot access the private_submodule
function:
#![allow(unused)] fn main() { mod foo { use pyo3::prelude::*; #[pymodule] fn private_submodule(_py: Python, m: &PyModule) -> PyResult<()> { Ok(()) } } use pyo3::prelude::*; use foo::*; #[pymodule] fn my_module(_py: Python, m: &PyModule) -> PyResult<()> { m.add_wrapped(wrap_pymodule!(private_submodule))?; Ok(()) } }
To fix it, make the private submodule visible, e.g. with pub
or pub(crate)
.
#![allow(unused)] fn main() { mod foo { use pyo3::prelude::*; #[pymodule] pub(crate) fn private_submodule(_py: Python, m: &PyModule) -> PyResult<()> { Ok(()) } } use pyo3::prelude::*; use pyo3::wrap_pymodule; use foo::*; #[pymodule] fn my_module(_py: Python, m: &PyModule) -> PyResult<()> { m.add_wrapped(wrap_pymodule!(private_submodule))?; Ok(()) } }
from 0.14.* to 0.15
Changes in sequence indexing
For all types that take sequence indices (PyList
, PyTuple
and PySequence
),
the API has been made consistent to only take usize
indices, for consistency
with Rust's indexing conventions. Negative indices, which were only
sporadically supported even in APIs that took isize
, now aren't supported
anywhere.
Further, the get_item
methods now always return a PyResult
instead of
panicking on invalid indices. The Index
trait has been implemented instead,
and provides the same panic behavior as on Rust vectors.
Note that slice indices (accepted by PySequence::get_slice
and other) still
inherit the Python behavior of clamping the indices to the actual length, and
not panicking/returning an error on out of range indices.
An additional advantage of using Rust's indexing conventions for these types is that these types can now also support Rust's indexing operators as part of a consistent API:
#![allow(unused)] fn main() { use pyo3::{Python, types::PyList}; Python::with_gil(|py| { let list = PyList::new(py, &[1, 2, 3]); assert_eq!(list[0..2].to_string(), "[1, 2]"); }); }
from 0.13.* to 0.14
auto-initialize
feature is now opt-in
For projects embedding Python in Rust, PyO3 no longer automatically initializes a Python interpreter on the first call to Python::with_gil
(or Python::acquire_gil
) unless the auto-initialize
feature is enabled.
New multiple-pymethods
feature
#[pymethods]
have been reworked with a simpler default implementation which removes the dependency on the inventory
crate. This reduces dependencies and compile times for the majority of users.
The limitation of the new default implementation is that it cannot support multiple #[pymethods]
blocks for the same #[pyclass]
. If you need this functionality, you must enable the multiple-pymethods
feature which will switch #[pymethods]
to the inventory-based implementation.
Deprecated #[pyproto]
methods
Some protocol (aka __dunder__
) methods such as __bytes__
and __format__
have been possible to implement two ways in PyO3 for some time: via a #[pyproto]
(e.g. PyBasicProtocol
for the methods listed here), or by writing them directly in #[pymethods]
. This is only true for a handful of the #[pyproto]
methods (for technical reasons to do with the way PyO3 currently interacts with the Python C-API).
In the interest of having onle one way to do things, the #[pyproto]
forms of these methods have been deprecated.
To migrate just move the affected methods from a #[pyproto]
to a #[pymethods]
block.
Before:
use pyo3::prelude::*;
use pyo3::class::basic::PyBasicProtocol;
#[pyclass]
struct MyClass { }
#[pyproto]
impl PyBasicProtocol for MyClass {
fn __bytes__(&self) -> &'static [u8] {
b"hello, world"
}
}
After:
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyclass] struct MyClass { } #[pymethods] impl MyClass { fn __bytes__(&self) -> &'static [u8] { b"hello, world" } } }
from 0.12.* to 0.13
Minimum Rust version increased to Rust 1.45
PyO3 0.13
makes use of new Rust language features stabilised between Rust 1.40 and Rust 1.45. If you are using a Rust compiler older than Rust 1.45, you will need to update your toolchain to be able to continue using PyO3.
Runtime changes to support the CPython limited API
In PyO3 0.13
support was added for compiling against the CPython limited API. This had a number of implications for all PyO3 users, described here.
The largest of these is that all types created from PyO3 are what CPython calls "heap" types. The specific implications of this are:
- If you wish to subclass one of these types from Rust you must mark it
#[pyclass(subclass)]
, as you would if you wished to allow subclassing it from Python code. - Type objects are now mutable - Python code can set attributes on them.
__module__
on types without#[pyclass(module="mymodule")]
no longer returnsbuiltins
, it now raisesAttributeError
.
from 0.11.* to 0.12
PyErr
has been reworked
In PyO3 0.12
the PyErr
type has been re-implemented to be significantly more compatible with
the standard Rust error handling ecosystem. Specifically PyErr
now implements
Error + Send + Sync
, which are the standard traits used for error types.
While this has necessitated the removal of a number of APIs, the resulting PyErr
type should now
be much more easier to work with. The following sections list the changes in detail and how to
migrate to the new APIs.
PyErr::new
and PyErr::from_type
now require Send + Sync
for their argument
For most uses no change will be needed. If you are trying to construct PyErr
from a value that is
not Send + Sync
, you will need to first create the Python object and then use
PyErr::from_instance
.
Similarly, any types which implemented PyErrArguments
will now need to be Send + Sync
.
PyErr
's contents are now private
It is no longer possible to access the fields .ptype
, .pvalue
and .ptraceback
of a PyErr
.
You should instead now use the new methods PyErr::ptype
, PyErr::pvalue
and PyErr::ptraceback
.
PyErrValue
and PyErr::from_value
have been removed
As these were part the internals of PyErr
which have been reworked, these APIs no longer exist.
If you used this API, it is recommended to use PyException::new_err
(see the section on
Exception types).
Into<PyResult<T>>
for PyErr
has been removed
This implementation was redundant. Just construct the Result::Err
variant directly.
Before:
let result: PyResult<()> = PyErr::new::<TypeError, _>("error message").into();
After (also using the new reworked exception types; see the following section):
#![allow(unused)] fn main() { use pyo3::{PyResult, exceptions::PyTypeError}; let result: PyResult<()> = Err(PyTypeError::new_err("error message")); }
Exception types have been reworked
Previously exception types were zero-sized marker types purely used to construct PyErr
. In PyO3
0.12, these types have been replaced with full definitions and are usable in the same way as PyAny
, PyDict
etc. This
makes it possible to interact with Python exception objects.
The new types also have names starting with the "Py" prefix. For example, before:
let err: PyErr = TypeError::py_err("error message");
After:
use pyo3::{PyErr, PyResult, Python, type_object::PyTypeObject};
use pyo3::exceptions::{PyBaseException, PyTypeError};
Python::with_gil(|py| -> PyResult<()> {
let err: PyErr = PyTypeError::new_err("error message");
// Uses Display for PyErr, new for PyO3 0.12
assert_eq!(err.to_string(), "TypeError: error message");
// Now possible to interact with exception instances, new for PyO3 0.12
let instance: &PyBaseException = err.instance(py);
assert_eq!(instance.getattr("__class__")?, PyTypeError::type_object(py).as_ref());
Ok(())
}).unwrap();
FromPy
has been removed
To simplify the PyO3 conversion traits, the FromPy
trait has been removed. Previously there were
two ways to define the to-Python conversion for a type:
FromPy<T> for PyObject
and IntoPy<PyObject> for T
.
Now there is only one way to define the conversion, IntoPy
, so downstream crates may need to
adjust accordingly.
Before:
use pyo3::prelude::*;
struct MyPyObjectWrapper(PyObject);
impl FromPy<MyPyObjectWrapper> for PyObject {
fn from_py(other: MyPyObjectWrapper, _py: Python) -> Self {
other.0
}
}
After
#![allow(unused)] fn main() { use pyo3::prelude::*; struct MyPyObjectWrapper(PyObject); impl IntoPy<PyObject> for MyPyObjectWrapper { fn into_py(self, _py: Python) -> PyObject { self.0 } } }
Similarly, code which was using the FromPy
trait can be trivially rewritten to use IntoPy
.
Before:
use pyo3::prelude::*;
Python::with_gil(|py| {
let obj = PyObject::from_py(1.234, py);
})
After:
#![allow(unused)] fn main() { use pyo3::prelude::*; Python::with_gil(|py| { let obj: PyObject = 1.234.into_py(py); }) }
PyObject
is now a type alias of Py<PyAny>
This should change very little from a usage perspective. If you implemented traits for both
PyObject
and Py<T>
, you may find you can just remove the PyObject
implementation.
AsPyRef
has been removed
As PyObject
has been changed to be just a type alias, the only remaining implementor of AsPyRef
was Py<T>
. This removed the need for a trait, so the AsPyRef::as_ref
method has been moved to
Py::as_ref
.
This should require no code changes except removing use pyo3::AsPyRef
for code which did not use
pyo3::prelude::*
.
Before:
use pyo3::{AsPyRef, Py, types::PyList};
pyo3::Python::with_gil(|py| {
let list_py: Py<PyList> = PyList::empty(py).into();
let list_ref: &PyList = list_py.as_ref(py);
})
After:
#![allow(unused)] fn main() { use pyo3::{Py, types::PyList}; pyo3::Python::with_gil(|py| { let list_py: Py<PyList> = PyList::empty(py).into(); let list_ref: &PyList = list_py.as_ref(py); }) }
from 0.10.* to 0.11
Stable Rust
PyO3 now supports the stable Rust toolchain. The minimum required version is 1.39.0.
#[pyclass]
structs must now be Send
or unsendable
Because #[pyclass]
structs can be sent between threads by the Python interpreter, they must implement
Send
or declared as unsendable
(by #[pyclass(unsendable)]
).
Note that unsendable
is added in PyO3 0.11.1
and Send
is always required in PyO3 0.11.0
.
This may "break" some code which previously was accepted, even though it could be unsound. There can be two fixes:
-
If you think that your
#[pyclass]
actually must beSend
able, then let's implementSend
. A common, safer way is using thread-safe types. E.g.,Arc
instead ofRc
,Mutex
instead ofRefCell
, andBox<dyn Send + T>
instead ofBox<dyn T>
.Before:
#![allow(unused)] fn main() { use pyo3::prelude::*; use std::rc::Rc; use std::cell::RefCell; #[pyclass] struct NotThreadSafe { shared_bools: Rc<RefCell<Vec<bool>>>, closure: Box<dyn Fn()> } }
After:
#![allow(unused)] fn main() { #![allow(dead_code)] use pyo3::prelude::*; use std::sync::{Arc, Mutex}; #[pyclass] struct ThreadSafe { shared_bools: Arc<Mutex<Vec<bool>>>, closure: Box<dyn Fn() + Send> } }
In situations where you cannot change your
#[pyclass]
to automatically implementSend
(e.g., when it contains a raw pointer), you can useunsafe impl Send
. In such cases, care should be taken to ensure the struct is actually thread safe. See the Rustnomicon for more. -
If you think that your
#[pyclass]
should not be accessed by another thread, you can useunsendable
flag. A class marked withunsendable
panics when accessed by another thread, making it thread-safe to expose an unsendable object to the Python interpreter.Before:
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyclass] struct Unsendable { pointers: Vec<*mut std::os::raw::c_char>, } }
After:
#![allow(unused)] fn main() { #![allow(dead_code)] use pyo3::prelude::*; #[pyclass(unsendable)] struct Unsendable { pointers: Vec<*mut std::os::raw::c_char>, } }
All PyObject
and Py<T>
methods now take Python
as an argument
Previously, a few methods such as Object::get_refcnt
did not take Python
as an argument (to
ensure that the Python GIL was held by the current thread). Technically, this was not sound.
To migrate, just pass a py
argument to any calls to these methods.
Before:
#![allow(unused)] fn main() { pyo3::Python::with_gil(|py| { py.None().get_refcnt(); }) }
After:
#![allow(unused)] fn main() { pyo3::Python::with_gil(|py| { py.None().get_refcnt(py); }) }
from 0.9.* to 0.10
ObjectProtocol
is removed
All methods are moved to PyAny
.
And since now all native types (e.g., PyList
) implements Deref<Target=PyAny>
,
all you need to do is remove ObjectProtocol
from your code.
Or if you use ObjectProtocol
by use pyo3::prelude::*
, you have to do nothing.
Before:
#![allow(unused)] fn main() { use pyo3::ObjectProtocol; pyo3::Python::with_gil(|py| { let obj = py.eval("lambda: 'Hi :)'", None, None).unwrap(); let hi: &pyo3::types::PyString = obj.call0().unwrap().downcast().unwrap(); assert_eq!(hi.len().unwrap(), 5); }) }
After:
#![allow(unused)] fn main() { pyo3::Python::with_gil(|py| { let obj = py.eval("lambda: 'Hi :)'", None, None).unwrap(); let hi: &pyo3::types::PyString = obj.call0().unwrap().downcast().unwrap(); assert_eq!(hi.len().unwrap(), 5); }) }
No #![feature(specialization)]
in user code
While PyO3 itself still requires specialization and nightly Rust,
now you don't have to use #![feature(specialization)]
in your crate.
from 0.8.* to 0.9
#[new]
interface
PyRawObject
is now removed and our syntax for constructors has changed.
Before:
#![allow(unused)] fn main() { #[pyclass] struct MyClass {} #[pymethods] impl MyClass { #[new] fn new(obj: &PyRawObject) { obj.init(MyClass { }) } } }
After:
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyclass] struct MyClass {} #[pymethods] impl MyClass { #[new] fn new() -> Self { MyClass {} } } }
Basically you can return Self
or Result<Self>
directly.
For more, see the constructor section of this guide.
PyCell
PyO3 0.9 introduces PyCell
, which is a RefCell
-like object wrapper
for ensuring Rust's rules regarding aliasing of references are upheld.
For more detail, see the
Rust Book's section on Rust's rules of references
For #[pymethods]
or #[pyfunction]
s, your existing code should continue to work without any change.
Python exceptions will automatically be raised when your functions are used in a way which breaks Rust's
rules of references.
Here is an example.
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyclass] struct Names { names: Vec<String> } #[pymethods] impl Names { #[new] fn new() -> Self { Names { names: vec![] } } fn merge(&mut self, other: &mut Names) { self.names.append(&mut other.names) } } Python::with_gil(|py| { let names = PyCell::new(py, Names::new()).unwrap(); pyo3::py_run!(py, names, r" try: names.merge(names) assert False, 'Unreachable' except RuntimeError as e: assert str(e) == 'Already borrowed' "); }) }
Names
has a merge
method, which takes &mut self
and another argument of type &mut Self
.
Given this #[pyclass]
, calling names.merge(names)
in Python raises
a PyBorrowMutError
exception, since it requires two mutable borrows of names
.
However, for #[pyproto]
and some functions, you need to manually fix the code.
Object creation
In 0.8 object creation was done with PyRef::new
and PyRefMut::new
.
In 0.9 these have both been removed.
To upgrade code, please use
PyCell::new
instead.
If you need PyRef
or PyRefMut
, just call .borrow()
or .borrow_mut()
on the newly-created PyCell
.
Before:
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyclass] struct MyClass {} Python::with_gil(|py| { let obj_ref = PyRef::new(py, MyClass {}).unwrap(); }) }
After:
#![allow(unused)] fn main() { use pyo3::prelude::*; #[pyclass] struct MyClass {} Python::with_gil(|py| { let obj = PyCell::new(py, MyClass {}).unwrap(); let obj_ref = obj.borrow(); }) }
Object extraction
For PyClass
types T
, &T
and &mut T
no longer have FromPyObject
implementations.
Instead you should extract PyRef<T>
or PyRefMut<T>
, respectively.
If T
implements Clone
, you can extract T
itself.
In addition, you can also extract &PyCell<T>
, though you rarely need it.
Before:
let obj: &PyAny = create_obj();
let obj_ref: &MyClass = obj.extract().unwrap();
let obj_ref_mut: &mut MyClass = obj.extract().unwrap();
After:
#![allow(unused)] fn main() { use pyo3::prelude::*; use pyo3::types::IntoPyDict; #[pyclass] #[derive(Clone)] struct MyClass {} #[pymethods] impl MyClass { #[new]fn new() -> Self { MyClass {} }} Python::with_gil(|py| { let typeobj = py.get_type::<MyClass>(); let d = [("c", typeobj)].into_py_dict(py); let create_obj = || py.eval("c()", None, Some(d)).unwrap(); let obj: &PyAny = create_obj(); let obj_cell: &PyCell<MyClass> = obj.extract().unwrap(); let obj_cloned: MyClass = obj.extract().unwrap(); // extracted by cloning the object { let obj_ref: PyRef<MyClass> = obj.extract().unwrap(); // we need to drop obj_ref before we can extract a PyRefMut due to Rust's rules of references } let obj_ref_mut: PyRefMut<MyClass> = obj.extract().unwrap(); }) }
#[pyproto]
Most of the arguments to methods in #[pyproto]
impls require a
FromPyObject
implementation.
So if your protocol methods take &T
or &mut T
(where T: PyClass
),
please use PyRef
or PyRefMut
instead.
Before:
#![allow(unused)] fn main() { use pyo3::prelude::*; use pyo3::class::PySequenceProtocol; #[pyclass] struct ByteSequence { elements: Vec<u8>, } #[pyproto] impl PySequenceProtocol for ByteSequence { fn __concat__(&self, other: &Self) -> PyResult<Self> { let mut elements = self.elements.clone(); elements.extend_from_slice(&other.elements); Ok(Self { elements }) } } }
After:
use pyo3::prelude::*;
use pyo3::class::PySequenceProtocol;
#[pyclass]
struct ByteSequence {
elements: Vec<u8>,
}
#[pyproto]
impl PySequenceProtocol for ByteSequence {
fn __concat__(&self, other: PyRef<'p, Self>) -> PyResult<Self> {
let mut elements = self.elements.clone();
elements.extend_from_slice(&other.elements);
Ok(Self { elements })
}
}