docs/advanced/smart_ptrs.rst - third_party/github/pybind/pybind11 - Git at Google

 .. _py_class_holder:

 Smart pointers & ``py::class_``
 ###############################

 The binding generator for classes, ``py::class_``, can be passed a template
 type that denotes a special *holder* type that is used to manage references to
 the object. If no such holder type template argument is given, the default for
 a type ``T`` is ``std::unique_ptr<T>``.

 .. note::

     A ``py::class_`` for a given C++ type ``T`` — and all its derived types —
     can only use a single holder type.


 .. _smart_holder:

 ``py::smart_holder``
 ====================

 Starting with pybind11v3, ``py::smart_holder`` is built into pybind11. It is
 the recommended ``py::class_`` holder for most situations. However, for
 backward compatibility it is **not** the default holder, and there are no
 plans to make it the default holder in the future.

 It is extremely easy to use the safer and more versatile ``py::smart_holder``:
 simply add ``py::smart_holder`` to ``py::class_``:

 * ``py::class_<T>`` to

 * ``py::class_<T, py::smart_holder>``.

 .. note::

     A shorthand, ``py::classh<T>``, is provided for
     ``py::class_<T, py::smart_holder>``. The ``h`` in ``py::classh`` stands
     for **smart_holder** but is shortened for brevity, ensuring it has the
     same number of characters as ``py::class_``. This design choice facilitates
     easy experimentation with ``py::smart_holder`` without introducing
     distracting whitespace noise in diffs.

 The ``py::smart_holder`` functionality includes the following:

 * Support for **two-way** Python/C++ conversions for both
   ``std::unique_ptr<T>`` and ``std::shared_ptr<T>`` **simultaneously**.

 * Passing a Python object back to C++ via ``std::unique_ptr<T>``, safely
   **disowning** the Python object.

 * Safely passing "trampoline" objects (objects with C++ virtual function
   overrides implemented in Python, see :ref:`overriding_virtuals`) via
   ``std::unique_ptr<T>`` or ``std::shared_ptr<T>`` back to C++:
   associated Python objects are automatically kept alive for the lifetime
   of the smart-pointer.

 * Full support for ``std::enable_shared_from_this`` (`cppreference
   <http://en.cppreference.com/w/cpp/memory/enable_shared_from_this>`_).


 ``std::unique_ptr``
 ===================

 This is the default ``py::class_`` holder and works as expected in
 most situations. However, handling base-and-derived classes involves a
 ``reinterpret_cast``, which is, strictly speaking, undefined behavior.
 Also note that the ``std::unique_ptr`` holder only supports passing a
 ``std::unique_ptr`` from C++ to Python, but not the other way around.
 For example, the following code works as expected with ``py::class_<Example>``:

 .. code-block:: cpp

     std::unique_ptr<Example> create_example() { return std::unique_ptr<Example>(new Example()); }

 .. code-block:: cpp

     m.def("create_example", &create_example);

 However, this will fail with ``py::class_<Example>`` (but works with
 ``py::class_<Example, py::smart_holder>``):

 .. code-block:: cpp

     void do_something_with_example(std::unique_ptr<Example> ex) { ... }

 .. note::

     The ``reinterpret_cast`` mentioned above is `here
     <https://github.com/pybind/pybind11/blob/30eb39ed79d1e2eeff15219ac00773034300a5e6/include/pybind11/cast.h#L235>`_.
     For completeness: The same cast is also applied to ``py::smart_holder``,
     but that is safe, because ``py::smart_holder`` is not templated.


 ``std::shared_ptr``
 ===================

 It is possible to use ``std::shared_ptr`` as the holder, for example:

 .. code-block:: cpp

     py::class_<Example, std::shared_ptr<Example> /* <- holder type */>(m, "Example");

 Compared to using ``py::class_<Example, py::smart_holder>``, there are two noteworthy disadvantages:

 * Because a ``py::class_`` for a given C++ type ``T`` can only use a
   single holder type, ``std::unique_ptr<T>`` cannot even be passed from C++
   to Python. This will become apparent only at runtime, often through a
   segmentation fault.

 * Similar to the ``std::unique_ptr`` holder, the handling of base-and-derived
   classes involves a ``reinterpret_cast`` that has strictly speaking undefined
   behavior, although it works as expected in most situations.


 .. _smart_pointers:

 Custom smart pointers
 =====================

 For custom smart pointers (e.g. ``c10::intrusive_ptr`` in pytorch), transparent
 conversions can be enabled using a macro invocation similar to the following.
 It must be declared at the top namespace level before any binding code:

 .. code-block:: cpp

     PYBIND11_DECLARE_HOLDER_TYPE(T, SmartPtr<T>)

 The first argument of :func:`PYBIND11_DECLARE_HOLDER_TYPE` should be a
 placeholder name that is used as a template parameter of the second argument.
 Thus, feel free to use any identifier, but use it consistently on both sides;
 also, don't use the name of a type that already exists in your codebase.

 The macro also accepts a third optional boolean parameter that is set to false
 by default. Specify

 .. code-block:: cpp

     PYBIND11_DECLARE_HOLDER_TYPE(T, SmartPtr<T>, true)

 if ``SmartPtr<T>`` can always be initialized from a ``T*`` pointer without the
 risk of inconsistencies (such as multiple independent ``SmartPtr`` instances
 believing that they are the sole owner of the ``T*`` pointer). A common
 situation where ``true`` should be passed is when the ``T`` instances use
 *intrusive* reference counting.

 Please take a look at the :ref:`macro_notes` before using this feature.

 By default, pybind11 assumes that your custom smart pointer has a standard
 interface, i.e. provides a ``.get()`` member function to access the underlying
 raw pointer. If this is not the case, pybind11's ``holder_helper`` must be
 specialized:

 .. code-block:: cpp

     // Always needed for custom holder types
     PYBIND11_DECLARE_HOLDER_TYPE(T, SmartPtr<T>)

     // Only needed if the type's `.get()` goes by another name
     namespace PYBIND11_NAMESPACE { namespace detail {
         template <typename T>
         struct holder_helper<SmartPtr<T>> { // <-- specialization
             static const T *get(const SmartPtr<T> &p) { return p.getPointer(); }
         };
     }}

 The above specialization informs pybind11 that the custom ``SmartPtr`` class
 provides ``.get()`` functionality via ``.getPointer()``.

 .. note::

     The two noteworthy disadvantages mentioned under the ``std::shared_ptr``
     section apply similarly to custom smart pointer holders, but there is no
     established safe alternative in this case.

 .. seealso::

     The file :file:`tests/test_smart_ptr.cpp` contains a complete example
     that demonstrates how to work with custom reference-counting holder types
     in more detail.
	.. _py_class_holder:

	Smart pointers & ``py::class_``
	###############################

	The binding generator for classes, ``py::class_``, can be passed a template
	type that denotes a special holder type that is used to manage references to
	the object. If no such holder type template argument is given, the default for
	a type ``T`` is ``std::unique_ptr<T>``.

	.. note::

	A ``py::class_`` for a given C++ type ``T`` — and all its derived types —
	can only use a single holder type.


	.. _smart_holder:

	``py::smart_holder``
	====================

	Starting with pybind11v3, ``py::smart_holder`` is built into pybind11. It is
	the recommended ``py::class_`` holder for most situations. However, for
	backward compatibility it is not the default holder, and there are no
	plans to make it the default holder in the future.

	It is extremely easy to use the safer and more versatile ``py::smart_holder``:
	simply add ``py::smart_holder`` to ``py::class_``:

	* ``py::class_<T>`` to

	* ``py::class_<T, py::smart_holder>``.

	.. note::

	A shorthand, ``py::classh<T>``, is provided for
	``py::class_<T, py::smart_holder>``. The ``h`` in ``py::classh`` stands
	for smart_holder but is shortened for brevity, ensuring it has the
	same number of characters as ``py::class_``. This design choice facilitates
	easy experimentation with ``py::smart_holder`` without introducing
	distracting whitespace noise in diffs.

	The ``py::smart_holder`` functionality includes the following:

	* Support for two-way Python/C++ conversions for both
	``std::unique_ptr<T>`` and ``std::shared_ptr<T>`` simultaneously.

	* Passing a Python object back to C++ via ``std::unique_ptr<T>``, safely
	disowning the Python object.

	* Safely passing "trampoline" objects (objects with C++ virtual function
	overrides implemented in Python, see :ref:`overriding_virtuals`) via
	``std::unique_ptr<T>`` or ``std::shared_ptr<T>`` back to C++:
	associated Python objects are automatically kept alive for the lifetime
	of the smart-pointer.

	* Full support for ``std::enable_shared_from_this`` (`cppreference
	<http://en.cppreference.com/w/cpp/memory/enable_shared_from_this>`_).


	``std::unique_ptr``
	===================

	This is the default ``py::class_`` holder and works as expected in
	most situations. However, handling base-and-derived classes involves a
	``reinterpret_cast``, which is, strictly speaking, undefined behavior.
	Also note that the ``std::unique_ptr`` holder only supports passing a
	``std::unique_ptr`` from C++ to Python, but not the other way around.
	For example, the following code works as expected with ``py::class_<Example>``:

	.. code-block:: cpp

	std::unique_ptr<Example> create_example() { return std::unique_ptr<Example>(new Example()); }

	.. code-block:: cpp

	m.def("create_example", &create_example);

	However, this will fail with ``py::class_<Example>`` (but works with
	``py::class_<Example, py::smart_holder>``):

	.. code-block:: cpp

	void do_something_with_example(std::unique_ptr<Example> ex) { ... }

	.. note::

	The ``reinterpret_cast`` mentioned above is `here
	<https://github.com/pybind/pybind11/blob/30eb39ed79d1e2eeff15219ac00773034300a5e6/include/pybind11/cast.h#L235>`_.
	For completeness: The same cast is also applied to ``py::smart_holder``,
	but that is safe, because ``py::smart_holder`` is not templated.


	``std::shared_ptr``
	===================

	It is possible to use ``std::shared_ptr`` as the holder, for example:

	.. code-block:: cpp

	py::class_<Example, std::shared_ptr<Example> /* <- holder type */>(m, "Example");

	Compared to using ``py::class_<Example, py::smart_holder>``, there are two noteworthy disadvantages:

	* Because a ``py::class_`` for a given C++ type ``T`` can only use a
	single holder type, ``std::unique_ptr<T>`` cannot even be passed from C++
	to Python. This will become apparent only at runtime, often through a
	segmentation fault.

	* Similar to the ``std::unique_ptr`` holder, the handling of base-and-derived
	classes involves a ``reinterpret_cast`` that has strictly speaking undefined
	behavior, although it works as expected in most situations.


	.. _smart_pointers:

	Custom smart pointers
	=====================

	For custom smart pointers (e.g. ``c10::intrusive_ptr`` in pytorch), transparent
	conversions can be enabled using a macro invocation similar to the following.
	It must be declared at the top namespace level before any binding code:

	.. code-block:: cpp

	PYBIND11_DECLARE_HOLDER_TYPE(T, SmartPtr<T>)

	The first argument of :func:`PYBIND11_DECLARE_HOLDER_TYPE` should be a
	placeholder name that is used as a template parameter of the second argument.
	Thus, feel free to use any identifier, but use it consistently on both sides;
	also, don't use the name of a type that already exists in your codebase.

	The macro also accepts a third optional boolean parameter that is set to false
	by default. Specify

	.. code-block:: cpp

	PYBIND11_DECLARE_HOLDER_TYPE(T, SmartPtr<T>, true)

	if ``SmartPtr<T>`` can always be initialized from a ``T*`` pointer without the
	risk of inconsistencies (such as multiple independent ``SmartPtr`` instances
	believing that they are the sole owner of the ``T*`` pointer). A common
	situation where ``true`` should be passed is when the ``T`` instances use
	intrusive reference counting.

	Please take a look at the :ref:`macro_notes` before using this feature.

	By default, pybind11 assumes that your custom smart pointer has a standard
	interface, i.e. provides a ``.get()`` member function to access the underlying
	raw pointer. If this is not the case, pybind11's ``holder_helper`` must be
	specialized:

	.. code-block:: cpp

	// Always needed for custom holder types
	PYBIND11_DECLARE_HOLDER_TYPE(T, SmartPtr<T>)

	// Only needed if the type's `.get()` goes by another name
	namespace PYBIND11_NAMESPACE { namespace detail {
	template <typename T>
	struct holder_helper<SmartPtr<T>> { // <-- specialization
	static const T *get(const SmartPtr<T> &p) { return p.getPointer(); }
	};
	}}

	The above specialization informs pybind11 that the custom ``SmartPtr`` class
	provides ``.get()`` functionality via ``.getPointer()``.

	.. note::

	The two noteworthy disadvantages mentioned under the ``std::shared_ptr``
	section apply similarly to custom smart pointer holders, but there is no
	established safe alternative in this case.

	.. seealso::

	The file :file:`tests/test_smart_ptr.cpp` contains a complete example
	that demonstrates how to work with custom reference-counting holder types
	in more detail.