ext/pybind11/docs/advanced/smart_ptrs.rst - testing/jenkins-gem5-prod - Git at Google

 Smart pointers
 ##############

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

 Given a class ``Example`` with Python bindings, it's possible to return
 instances wrapped in C++11 unique pointers, like so

 .. 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);

 In other words, there is nothing special that needs to be done. While returning
 unique pointers in this way is allowed, it is *illegal* to use them as function
 arguments. For instance, the following function signature cannot be processed
 by pybind11.

 .. code-block:: cpp

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

 The above signature would imply that Python needs to give up ownership of an
 object that is passed to this function, which is generally not possible (for
 instance, the object might be referenced elsewhere).

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

 The binding generator for classes, :class:`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 named ``Type`` is ``std::unique_ptr<Type>``, which means that the object
 is deallocated when Python's reference count goes to zero.

 It is possible to switch to other types of reference counting wrappers or smart
 pointers, which is useful in codebases that rely on them. For instance, the
 following snippet causes ``std::shared_ptr`` to be used instead.

 .. code-block:: cpp

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

 Note that any particular class can only be associated with a single holder type.

 One potential stumbling block when using holder types is that they need to be
 applied consistently. Can you guess what's broken about the following binding
 code?

 .. code-block:: cpp

     class Child { };

     class Parent {
     public:
        Parent() : child(std::make_shared<Child>()) { }
        Child *get_child() { return child.get(); }  /* Hint: ** DON'T DO THIS ** */
     private:
         std::shared_ptr<Child> child;
     };

     PYBIND11_MODULE(example, m) {
         py::class_<Child, std::shared_ptr<Child>>(m, "Child");

         py::class_<Parent, std::shared_ptr<Parent>>(m, "Parent")
            .def(py::init<>())
            .def("get_child", &Parent::get_child);
     }

 The following Python code will cause undefined behavior (and likely a
 segmentation fault).

 .. code-block:: python

    from example import Parent
    print(Parent().get_child())

 The problem is that ``Parent::get_child()`` returns a pointer to an instance of
 ``Child``, but the fact that this instance is already managed by
 ``std::shared_ptr<...>`` is lost when passing raw pointers. In this case,
 pybind11 will create a second independent ``std::shared_ptr<...>`` that also
 claims ownership of the pointer. In the end, the object will be freed **twice**
 since these shared pointers have no way of knowing about each other.

 There are two ways to resolve this issue:

 1. For types that are managed by a smart pointer class, never use raw pointers
    in function arguments or return values. In other words: always consistently
    wrap pointers into their designated holder types (such as
    ``std::shared_ptr<...>``). In this case, the signature of ``get_child()``
    should be modified as follows:

 .. code-block:: cpp

     std::shared_ptr<Child> get_child() { return child; }

 2. Adjust the definition of ``Child`` by specifying
    ``std::enable_shared_from_this<T>`` (see cppreference_ for details) as a
    base class. This adds a small bit of information to ``Child`` that allows
    pybind11 to realize that there is already an existing
    ``std::shared_ptr<...>`` and communicate with it. In this case, the
    declaration of ``Child`` should look as follows:

 .. _cppreference: http://en.cppreference.com/w/cpp/memory/enable_shared_from_this

 .. code-block:: cpp

     class Child : public std::enable_shared_from_this<Child> { };

 .. _smart_pointers:

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

 pybind11 supports ``std::unique_ptr`` and ``std::shared_ptr`` right out of the
 box. For any other custom smart pointer, 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 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()``.

 .. 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.
	Smart pointers
	##############

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

	Given a class ``Example`` with Python bindings, it's possible to return
	instances wrapped in C++11 unique pointers, like so

	.. 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);

	In other words, there is nothing special that needs to be done. While returning
	unique pointers in this way is allowed, it is illegal to use them as function
	arguments. For instance, the following function signature cannot be processed
	by pybind11.

	.. code-block:: cpp

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

	The above signature would imply that Python needs to give up ownership of an
	object that is passed to this function, which is generally not possible (for
	instance, the object might be referenced elsewhere).

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

	The binding generator for classes, :class:`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 named ``Type`` is ``std::unique_ptr<Type>``, which means that the object
	is deallocated when Python's reference count goes to zero.

	It is possible to switch to other types of reference counting wrappers or smart
	pointers, which is useful in codebases that rely on them. For instance, the
	following snippet causes ``std::shared_ptr`` to be used instead.

	.. code-block:: cpp

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

	Note that any particular class can only be associated with a single holder type.

	One potential stumbling block when using holder types is that they need to be
	applied consistently. Can you guess what's broken about the following binding
	code?

	.. code-block:: cpp

	class Child { };

	class Parent {
	public:
	Parent() : child(std::make_shared<Child>()) { }
	Child get_child() { return child.get(); } / Hint: DON'T DO THIS */
	private:
	std::shared_ptr<Child> child;
	};

	PYBIND11_MODULE(example, m) {
	py::class_<Child, std::shared_ptr<Child>>(m, "Child");

	py::class_<Parent, std::shared_ptr<Parent>>(m, "Parent")
	.def(py::init<>())
	.def("get_child", &Parent::get_child);
	}

	The following Python code will cause undefined behavior (and likely a
	segmentation fault).

	.. code-block:: python

	from example import Parent
	print(Parent().get_child())

	The problem is that ``Parent::get_child()`` returns a pointer to an instance of
	``Child``, but the fact that this instance is already managed by
	``std::shared_ptr<...>`` is lost when passing raw pointers. In this case,
	pybind11 will create a second independent ``std::shared_ptr<...>`` that also
	claims ownership of the pointer. In the end, the object will be freed twice
	since these shared pointers have no way of knowing about each other.

	There are two ways to resolve this issue:

	1. For types that are managed by a smart pointer class, never use raw pointers
	in function arguments or return values. In other words: always consistently
	wrap pointers into their designated holder types (such as
	``std::shared_ptr<...>``). In this case, the signature of ``get_child()``
	should be modified as follows:

	.. code-block:: cpp

	std::shared_ptr<Child> get_child() { return child; }

	2. Adjust the definition of ``Child`` by specifying
	``std::enable_shared_from_this<T>`` (see cppreference_ for details) as a
	base class. This adds a small bit of information to ``Child`` that allows
	pybind11 to realize that there is already an existing
	``std::shared_ptr<...>`` and communicate with it. In this case, the
	declaration of ``Child`` should look as follows:

	.. _cppreference: http://en.cppreference.com/w/cpp/memory/enable_shared_from_this

	.. code-block:: cpp

	class Child : public std::enable_shared_from_this<Child> { };

	.. _smart_pointers:

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

	pybind11 supports ``std::unique_ptr`` and ``std::shared_ptr`` right out of the
	box. For any other custom smart pointer, 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 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()``.

	.. 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.