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

 STL containers
 ##############

 Automatic conversion
 ====================

 When including the additional header file :file:`pybind11/stl.h`, conversions
 between ``std::vector<>``/``std::list<>``/``std::array<>``,
 ``std::set<>``/``std::unordered_set<>``, and
 ``std::map<>``/``std::unordered_map<>`` and the Python ``list``, ``set`` and
 ``dict`` data structures are automatically enabled. The types ``std::pair<>``
 and ``std::tuple<>`` are already supported out of the box with just the core
 :file:`pybind11/pybind11.h` header.

 The major downside of these implicit conversions is that containers must be
 converted (i.e. copied) on every Python->C++ and C++->Python transition, which
 can have implications on the program semantics and performance. Please read the
 next sections for more details and alternative approaches that avoid this.

 .. note::

     Arbitrary nesting of any of these types is possible.

 .. seealso::

     The file :file:`tests/test_stl.cpp` contains a complete
     example that demonstrates how to pass STL data types in more detail.

 .. _cpp17_container_casters:

 C++17 library containers
 ========================

 The :file:`pybind11/stl.h` header also includes support for ``std::optional<>``
 and ``std::variant<>``. These require a C++17 compiler and standard library.
 In C++14 mode, ``std::experimental::optional<>`` is supported if available.

 Various versions of these containers also exist for C++11 (e.g. in Boost).
 pybind11 provides an easy way to specialize the ``type_caster`` for such
 types:

 .. code-block:: cpp

     // `boost::optional` as an example -- can be any `std::optional`-like container
     namespace pybind11 { namespace detail {
         template <typename T>
         struct type_caster<boost::optional<T>> : optional_caster<boost::optional<T>> {};
     }}

 The above should be placed in a header file and included in all translation units
 where automatic conversion is needed. Similarly, a specialization can be provided
 for custom variant types:

 .. code-block:: cpp

     // `boost::variant` as an example -- can be any `std::variant`-like container
     namespace pybind11 { namespace detail {
         template <typename... Ts>
         struct type_caster<boost::variant<Ts...>> : variant_caster<boost::variant<Ts...>> {};

         // Specifies the function used to visit the variant -- `apply_visitor` instead of `visit`
         template <>
         struct visit_helper<boost::variant> {
             template <typename... Args>
             static auto call(Args &&...args) -> decltype(boost::apply_visitor(args...)) {
                 return boost::apply_visitor(args...);
             }
         };
     }} // namespace pybind11::detail

 The ``visit_helper`` specialization is not required if your ``name::variant`` provides
 a ``name::visit()`` function. For any other function name, the specialization must be
 included to tell pybind11 how to visit the variant.

 .. note::

     pybind11 only supports the modern implementation of ``boost::variant``
     which makes use of variadic templates. This requires Boost 1.56 or newer.
     Additionally, on Windows, MSVC 2017 is required because ``boost::variant``
     falls back to the old non-variadic implementation on MSVC 2015.

 .. _opaque:

 Making opaque types
 ===================

 pybind11 heavily relies on a template matching mechanism to convert parameters
 and return values that are constructed from STL data types such as vectors,
 linked lists, hash tables, etc. This even works in a recursive manner, for
 instance to deal with lists of hash maps of pairs of elementary and custom
 types, etc.

 However, a fundamental limitation of this approach is that internal conversions
 between Python and C++ types involve a copy operation that prevents
 pass-by-reference semantics. What does this mean?

 Suppose we bind the following function

 .. code-block:: cpp

     void append_1(std::vector<int> &v) {
        v.push_back(1);
     }

 and call it from Python, the following happens:

 .. code-block:: pycon

    >>> v = [5, 6]
    >>> append_1(v)
    >>> print(v)
    [5, 6]

 As you can see, when passing STL data structures by reference, modifications
 are not propagated back the Python side. A similar situation arises when
 exposing STL data structures using the ``def_readwrite`` or ``def_readonly``
 functions:

 .. code-block:: cpp

     /* ... definition ... */

     class MyClass {
         std::vector<int> contents;
     };

     /* ... binding code ... */

     py::class_<MyClass>(m, "MyClass")
         .def(py::init<>())
         .def_readwrite("contents", &MyClass::contents);

 In this case, properties can be read and written in their entirety. However, an
 ``append`` operation involving such a list type has no effect:

 .. code-block:: pycon

    >>> m = MyClass()
    >>> m.contents = [5, 6]
    >>> print(m.contents)
    [5, 6]
    >>> m.contents.append(7)
    >>> print(m.contents)
    [5, 6]

 Finally, the involved copy operations can be costly when dealing with very
 large lists. To deal with all of the above situations, pybind11 provides a
 macro named ``PYBIND11_MAKE_OPAQUE(T)`` that disables the template-based
 conversion machinery of types, thus rendering them *opaque*. The contents of
 opaque objects are never inspected or extracted, hence they *can* be passed by
 reference. For instance, to turn ``std::vector<int>`` into an opaque type, add
 the declaration

 .. code-block:: cpp

     PYBIND11_MAKE_OPAQUE(std::vector<int>);

 before any binding code (e.g. invocations to ``class_::def()``, etc.). This
 macro must be specified at the top level (and outside of any namespaces), since
 it instantiates a partial template overload. If your binding code consists of
 multiple compilation units, it must be present in every file (typically via a
 common header) preceding any usage of ``std::vector<int>``. Opaque types must
 also have a corresponding ``class_`` declaration to associate them with a name
 in Python, and to define a set of available operations, e.g.:

 .. code-block:: cpp

     py::class_<std::vector<int>>(m, "IntVector")
         .def(py::init<>())
         .def("clear", &std::vector<int>::clear)
         .def("pop_back", &std::vector<int>::pop_back)
         .def("__len__", [](const std::vector<int> &v) { return v.size(); })
         .def("__iter__", [](std::vector<int> &v) {
            return py::make_iterator(v.begin(), v.end());
         }, py::keep_alive<0, 1>()) /* Keep vector alive while iterator is used */
         // ....

 Please take a look at the :ref:`macro_notes` before using the
 ``PYBIND11_MAKE_OPAQUE`` macro.

 .. seealso::

     The file :file:`tests/test_opaque_types.cpp` contains a complete
     example that demonstrates how to create and expose opaque types using
     pybind11 in more detail.

 .. _stl_bind:

 Binding STL containers
 ======================

 The ability to expose STL containers as native Python objects is a fairly
 common request, hence pybind11 also provides an optional header file named
 :file:`pybind11/stl_bind.h` that does exactly this. The mapped containers try
 to match the behavior of their native Python counterparts as much as possible.

 The following example showcases usage of :file:`pybind11/stl_bind.h`:

 .. code-block:: cpp

     // Don't forget this
     #include <pybind11/stl_bind.h>

     PYBIND11_MAKE_OPAQUE(std::vector<int>);
     PYBIND11_MAKE_OPAQUE(std::map<std::string, double>);

     // ...

     // later in binding code:
     py::bind_vector<std::vector<int>>(m, "VectorInt");
     py::bind_map<std::map<std::string, double>>(m, "MapStringDouble");

 When binding STL containers pybind11 considers the types of the container's
 elements to decide whether the container should be confined to the local module
 (via the :ref:`module_local` feature).  If the container element types are
 anything other than already-bound custom types bound without
 ``py::module_local()`` the container binding will have ``py::module_local()``
 applied.  This includes converting types such as numeric types, strings, Eigen
 types; and types that have not yet been bound at the time of the stl container
 binding.  This module-local binding is designed to avoid potential conflicts
 between module bindings (for example, from two separate modules each attempting
 to bind ``std::vector<int>`` as a python type).

 It is possible to override this behavior to force a definition to be either
 module-local or global.  To do so, you can pass the attributes
 ``py::module_local()`` (to make the binding module-local) or
 ``py::module_local(false)`` (to make the binding global) into the
 ``py::bind_vector`` or ``py::bind_map`` arguments:

 .. code-block:: cpp

     py::bind_vector<std::vector<int>>(m, "VectorInt", py::module_local(false));

 Note, however, that such a global binding would make it impossible to load this
 module at the same time as any other pybind module that also attempts to bind
 the same container type (``std::vector<int>`` in the above example).

 See :ref:`module_local` for more details on module-local bindings.

 .. seealso::

     The file :file:`tests/test_stl_binders.cpp` shows how to use the
     convenience STL container wrappers.
	STL containers
	##############

	Automatic conversion
	====================

	When including the additional header file :file:`pybind11/stl.h`, conversions
	between ``std::vector<>``/``std::list<>``/``std::array<>``,
	``std::set<>``/``std::unordered_set<>``, and
	``std::map<>``/``std::unordered_map<>`` and the Python ``list``, ``set`` and
	``dict`` data structures are automatically enabled. The types ``std::pair<>``
	and ``std::tuple<>`` are already supported out of the box with just the core
	:file:`pybind11/pybind11.h` header.

	The major downside of these implicit conversions is that containers must be
	converted (i.e. copied) on every Python->C++ and C++->Python transition, which
	can have implications on the program semantics and performance. Please read the
	next sections for more details and alternative approaches that avoid this.

	.. note::

	Arbitrary nesting of any of these types is possible.

	.. seealso::

	The file :file:`tests/test_stl.cpp` contains a complete
	example that demonstrates how to pass STL data types in more detail.

	.. _cpp17_container_casters:

	C++17 library containers
	========================

	The :file:`pybind11/stl.h` header also includes support for ``std::optional<>``
	and ``std::variant<>``. These require a C++17 compiler and standard library.
	In C++14 mode, ``std::experimental::optional<>`` is supported if available.

	Various versions of these containers also exist for C++11 (e.g. in Boost).
	pybind11 provides an easy way to specialize the ``type_caster`` for such
	types:

	.. code-block:: cpp

	// `boost::optional` as an example -- can be any `std::optional`-like container
	namespace pybind11 { namespace detail {
	template <typename T>
	struct type_caster<boost::optional<T>> : optional_caster<boost::optional<T>> {};
	}}

	The above should be placed in a header file and included in all translation units
	where automatic conversion is needed. Similarly, a specialization can be provided
	for custom variant types:

	.. code-block:: cpp

	// `boost::variant` as an example -- can be any `std::variant`-like container
	namespace pybind11 { namespace detail {
	template <typename... Ts>
	struct type_caster<boost::variant<Ts...>> : variant_caster<boost::variant<Ts...>> {};

	// Specifies the function used to visit the variant -- `apply_visitor` instead of `visit`
	template <>
	struct visit_helper<boost::variant> {
	template <typename... Args>
	static auto call(Args &&...args) -> decltype(boost::apply_visitor(args...)) {
	return boost::apply_visitor(args...);
	}
	};
	}} // namespace pybind11::detail

	The ``visit_helper`` specialization is not required if your ``name::variant`` provides
	a ``name::visit()`` function. For any other function name, the specialization must be
	included to tell pybind11 how to visit the variant.

	.. note::

	pybind11 only supports the modern implementation of ``boost::variant``
	which makes use of variadic templates. This requires Boost 1.56 or newer.
	Additionally, on Windows, MSVC 2017 is required because ``boost::variant``
	falls back to the old non-variadic implementation on MSVC 2015.

	.. _opaque:

	Making opaque types
	===================

	pybind11 heavily relies on a template matching mechanism to convert parameters
	and return values that are constructed from STL data types such as vectors,
	linked lists, hash tables, etc. This even works in a recursive manner, for
	instance to deal with lists of hash maps of pairs of elementary and custom
	types, etc.

	However, a fundamental limitation of this approach is that internal conversions
	between Python and C++ types involve a copy operation that prevents
	pass-by-reference semantics. What does this mean?

	Suppose we bind the following function

	.. code-block:: cpp

	void append_1(std::vector<int> &v) {
	v.push_back(1);
	}

	and call it from Python, the following happens:

	.. code-block:: pycon

	>>> v = [5, 6]
	>>> append_1(v)
	>>> print(v)
	[5, 6]

	As you can see, when passing STL data structures by reference, modifications
	are not propagated back the Python side. A similar situation arises when
	exposing STL data structures using the ``def_readwrite`` or ``def_readonly``
	functions:

	.. code-block:: cpp

	/* ... definition ... */

	class MyClass {
	std::vector<int> contents;
	};

	/* ... binding code ... */

	py::class_<MyClass>(m, "MyClass")
	.def(py::init<>())
	.def_readwrite("contents", &MyClass::contents);

	In this case, properties can be read and written in their entirety. However, an
	``append`` operation involving such a list type has no effect:

	.. code-block:: pycon

	>>> m = MyClass()
	>>> m.contents = [5, 6]
	>>> print(m.contents)
	[5, 6]
	>>> m.contents.append(7)
	>>> print(m.contents)
	[5, 6]

	Finally, the involved copy operations can be costly when dealing with very
	large lists. To deal with all of the above situations, pybind11 provides a
	macro named ``PYBIND11_MAKE_OPAQUE(T)`` that disables the template-based
	conversion machinery of types, thus rendering them opaque. The contents of
	opaque objects are never inspected or extracted, hence they can be passed by
	reference. For instance, to turn ``std::vector<int>`` into an opaque type, add
	the declaration

	.. code-block:: cpp

	PYBIND11_MAKE_OPAQUE(std::vector<int>);

	before any binding code (e.g. invocations to ``class_::def()``, etc.). This
	macro must be specified at the top level (and outside of any namespaces), since
	it instantiates a partial template overload. If your binding code consists of
	multiple compilation units, it must be present in every file (typically via a
	common header) preceding any usage of ``std::vector<int>``. Opaque types must
	also have a corresponding ``class_`` declaration to associate them with a name
	in Python, and to define a set of available operations, e.g.:

	.. code-block:: cpp

	py::class_<std::vector<int>>(m, "IntVector")
	.def(py::init<>())
	.def("clear", &std::vector<int>::clear)
	.def("pop_back", &std::vector<int>::pop_back)
	.def("__len__", [](const std::vector<int> &v) { return v.size(); })
	.def("__iter__", [](std::vector<int> &v) {
	return py::make_iterator(v.begin(), v.end());
	}, py::keep_alive<0, 1>()) /* Keep vector alive while iterator is used */
	// ....

	Please take a look at the :ref:`macro_notes` before using the
	``PYBIND11_MAKE_OPAQUE`` macro.

	.. seealso::

	The file :file:`tests/test_opaque_types.cpp` contains a complete
	example that demonstrates how to create and expose opaque types using
	pybind11 in more detail.

	.. _stl_bind:

	Binding STL containers
	======================

	The ability to expose STL containers as native Python objects is a fairly
	common request, hence pybind11 also provides an optional header file named
	:file:`pybind11/stl_bind.h` that does exactly this. The mapped containers try
	to match the behavior of their native Python counterparts as much as possible.

	The following example showcases usage of :file:`pybind11/stl_bind.h`:

	.. code-block:: cpp

	// Don't forget this
	#include <pybind11/stl_bind.h>

	PYBIND11_MAKE_OPAQUE(std::vector<int>);
	PYBIND11_MAKE_OPAQUE(std::map<std::string, double>);

	// ...

	// later in binding code:
	py::bind_vector<std::vector<int>>(m, "VectorInt");
	py::bind_map<std::map<std::string, double>>(m, "MapStringDouble");

	When binding STL containers pybind11 considers the types of the container's
	elements to decide whether the container should be confined to the local module
	(via the :ref:`module_local` feature). If the container element types are
	anything other than already-bound custom types bound without
	``py::module_local()`` the container binding will have ``py::module_local()``
	applied. This includes converting types such as numeric types, strings, Eigen
	types; and types that have not yet been bound at the time of the stl container
	binding. This module-local binding is designed to avoid potential conflicts
	between module bindings (for example, from two separate modules each attempting
	to bind ``std::vector<int>`` as a python type).

	It is possible to override this behavior to force a definition to be either
	module-local or global. To do so, you can pass the attributes
	``py::module_local()`` (to make the binding module-local) or
	``py::module_local(false)`` (to make the binding global) into the
	``py::bind_vector`` or ``py::bind_map`` arguments:

	.. code-block:: cpp

	py::bind_vector<std::vector<int>>(m, "VectorInt", py::module_local(false));

	Note, however, that such a global binding would make it impossible to load this
	module at the same time as any other pybind module that also attempts to bind
	the same container type (``std::vector<int>`` in the above example).

	See :ref:`module_local` for more details on module-local bindings.

	.. seealso::

	The file :file:`tests/test_stl_binders.cpp` shows how to use the
	convenience STL container wrappers.