This document roughly describes the high-level architecture of PyO3. If you want to become familiar with the codebase you are in the right place!
PyO3 provides a bridge between Rust and Python, based on the Python/C API.
Thus, PyO3 has low-level bindings of these API as its core.
On top of that, we have higher-level bindings to operate Python objects safely.
Also, to define Python classes and functions in Rust code, we have trait PyClass
and a set of
protocol traits (e.g., PyIterProtocol
) for supporting object protocols (i.e., __dunder__
methods).
Since implementing PyClass
requires lots of boilerplate, we have a proc-macro #[pyclass]
.
To summarize, there are six main parts to the PyO3 codebase.
- Low-level bindings of Python/C API.
- Bindings to Python objects.
PyClass
and related functionalities.src/pycell.rs
,src/pyclass.rs
, and more
- Procedural macros to simplify usage for users.
build.rs
andpyo3-build-config
pyo3-ffi
contains wrappers of the Python/C API. This is currently done by hand rather than
automated tooling because:
- it gives us best control about how to adapt C conventions to Rust, and
- there are many Python interpreter versions we support in a single set of files.
We aim to provide straight-forward Rust wrappers resembling the file structure of
cpython/Include
.
However, we still lack some APIs and are continuously updating the module to match the file contents upstream in CPython. The tracking issue is #1289, and contribution is welcome.
In the pyo3-ffi
crate, there is lots of conditional compilation such as #[cfg(Py_LIMITED_API)]
,
#[cfg(Py_3_7)]
, and #[cfg(PyPy)]
.
Py_LIMITED_API
corresponds to #define Py_LIMITED_API
macro in Python/C API.
With Py_LIMITED_API
, we can build a Python-version-agnostic binary called an
abi3 wheel.
Py_3_7
means that the API is available from Python >= 3.7.
There are also Py_3_8
, Py_3_9
, and so on.
PyPy
means that the API definition is for PyPy.
Those flags are set in build.rs
.
src/types
contains bindings to built-in types
of Python, such as dict
and list
.
For historical reasons, Python's object
is called PyAny
in PyO3 and located in src/types/any.rs
.
Currently, PyAny
is a straightforward wrapper of ffi::PyObject
, defined as:
#[repr(transparent)]
pub struct PyAny(UnsafeCell<ffi::PyObject>);
Concrete Python objects are implemented by wrapping PyAny
, e.g.,:
#[repr(transparent)]
pub struct PyDict(PyAny);
These types are not intended to be accessed directly, and instead are used through the Py<T>
and Bound<T>
smart pointers.
We have some macros in src/types/mod.rs
which make it easier to implement APIs for concrete Python types.
src/pycell.rs
, src/pyclass.rs
, and src/type_object.rs
contain types and
traits to make #[pyclass]
work.
Also, src/pyclass_init.rs
and [src/impl_/pyclass.rs
] have related functionalities.
To realize object-oriented programming in C, all Python objects have ob_base: PyObject
as their
first field in their structure definition. Thanks to this guarantee, casting *mut A
to *mut PyObject
is valid if A
is a Python object.
To ensure this guarantee, we have a wrapper struct PyCell<T>
in src/pycell.rs
which is roughly:
#[repr(C)]
pub struct PyCell<T: PyClass> {
ob_base: crate::ffi::PyObject,
inner: T,
}
Thus, when copying a Rust struct to a Python object, we first allocate PyCell
on the Python heap and then
move T
into it.
Also, PyCell
provides RefCell-like methods
to ensure Rust's borrow rules.
See the documentation for more.
PyCell<T>
requires that T
implements PyClass
.
This trait is somewhat complex and derives many traits, but the most important one is PyTypeInfo
in src/type_object.rs
.
PyTypeInfo
is also implemented for built-in types.
In Python, all objects have their types, and types are also objects of type
.
For example, you can see type({})
shows dict
and type(type({}))
shows type
in Python REPL.
T: PyTypeInfo
implies that T
has a corresponding type object.
Python has some built-in special methods called dunder methods, such as __iter__
.
They are called "slots" in the abstract objects layer in
Python/C API.
We provide a way to implement those protocols similarly, by recognizing special
names in #[pymethods]
, with a few new ones for slots that can not be
implemented in Python, such as GC support.
pyo3-macros
provides five proc-macro APIs: pymodule
, pyfunction
, pyclass
,
pymethods
, and #[derive(FromPyObject)]
.
pyo3-macros-backend
has the actual implementations of these APIs.
src/impl_
contains #[doc(hidden)]
functionality used in code generated by these proc-macros,
such as parsing function arguments.
PyO3 supports a wide range of OSes, interpreters and use cases. The correct environment must be
detected at build time in order to set up relevant conditional compilation correctly. This logic
is captured in the pyo3-build-config
crate, which is a build-dependency
of pyo3
and
pyo3-macros
, and can also be used by downstream users in the same way.
In pyo3-build-config
's build.rs
the build environment is detected and inlined into the crate
as a "config file". This works in all cases except for cross-compiling, where it is necessary to
capture this from the pyo3
build.rs
to get some extra environment variables that Cargo doesn't
set for build dependencies.
The pyo3
build.rs
also runs some safety checks such as ensuring the Python version detected is
actually supported.
Some of the functionality of pyo3-build-config
:
- Find the interpreter for build and detect the Python version.
- We have to set some version flags like
#[cfg(Py_3_7)]
. - If the interpreter is PyPy, we set
#[cfg(PyPy)
. - If the
PYO3_CONFIG_FILE
environment variable is set then that file's contents will be used instead of any detected configuration. - If the
PYO3_NO_PYTHON
environment variable is set then the interpreter detection is bypassed entirely and only abi3 extensions can be built.
- We have to set some version flags like
- Check if we are building a Python extension.
- If we are building an extension (e.g., Python library installable by
pip
), we don't linklibpython
. Currently we use theextension-module
feature for this purpose. This may change in the future. See #1123.
- If we are building an extension (e.g., Python library installable by
- Cross-compiling configuration
- If
TARGET
architecture andHOST
architecture differ, we can find cross compile information from environment variables (PYO3_CROSS_LIB_DIR
,PYO3_CROSS_PYTHON_VERSION
andPYO3_CROSS_PYTHON_IMPLEMENTATION
) or system files. When cross compiling extension modules it is often possible to make it work without any additional user input. - When an experimental feature
generate-import-lib
is enabled, thepyo3-ffi
build script can generatepython3.dll
import libraries for Windows targets automatically via an externalpython3-dll-a
crate. This enables the users to cross compile Python extensions for Windows without having to install any Windows Python libraries.
- If