ext/pybind11/docs/advanced/pycpp/object.rst - public/gem5 - Git at Google

 Python types
 ############

 .. _wrappers:

 Available wrappers
 ==================

 All major Python types are available as thin C++ wrapper classes. These
 can also be used as function parameters -- see :ref:`python_objects_as_args`.

 Available types include :class:`handle`, :class:`object`, :class:`bool_`,
 :class:`int_`, :class:`float_`, :class:`str`, :class:`bytes`, :class:`tuple`,
 :class:`list`, :class:`dict`, :class:`slice`, :class:`none`, :class:`capsule`,
 :class:`iterable`, :class:`iterator`, :class:`function`, :class:`buffer`,
 :class:`array`, and :class:`array_t`.

 .. warning::

     Be sure to review the :ref:`pytypes_gotchas` before using this heavily in
     your C++ API.

 .. _instantiating_compound_types:

 Instantiating compound Python types from C++
 ============================================

 Dictionaries can be initialized in the :class:`dict` constructor:

 .. code-block:: cpp

     using namespace pybind11::literals; // to bring in the `_a` literal
     py::dict d("spam"_a=py::none(), "eggs"_a=42);

 A tuple of python objects can be instantiated using :func:`py::make_tuple`:

 .. code-block:: cpp

     py::tuple tup = py::make_tuple(42, py::none(), "spam");

 Each element is converted to a supported Python type.

 A `simple namespace`_ can be instantiated using

 .. code-block:: cpp

     using namespace pybind11::literals;  // to bring in the `_a` literal
     py::object SimpleNamespace = py::module_::import("types").attr("SimpleNamespace");
     py::object ns = SimpleNamespace("spam"_a=py::none(), "eggs"_a=42);

 Attributes on a namespace can be modified with the :func:`py::delattr`,
 :func:`py::getattr`, and :func:`py::setattr` functions. Simple namespaces can
 be useful as lightweight stand-ins for class instances.

 .. _simple namespace: https://docs.python.org/3/library/types.html#types.SimpleNamespace

 .. _casting_back_and_forth:

 Casting back and forth
 ======================

 In this kind of mixed code, it is often necessary to convert arbitrary C++
 types to Python, which can be done using :func:`py::cast`:

 .. code-block:: cpp

     MyClass *cls = ...;
     py::object obj = py::cast(cls);

 The reverse direction uses the following syntax:

 .. code-block:: cpp

     py::object obj = ...;
     MyClass *cls = obj.cast<MyClass *>();

 When conversion fails, both directions throw the exception :class:`cast_error`.

 .. _python_libs:

 Accessing Python libraries from C++
 ===================================

 It is also possible to import objects defined in the Python standard
 library or available in the current Python environment (``sys.path``) and work
 with these in C++.

 This example obtains a reference to the Python ``Decimal`` class.

 .. code-block:: cpp

     // Equivalent to "from decimal import Decimal"
     py::object Decimal = py::module_::import("decimal").attr("Decimal");

 .. code-block:: cpp

     // Try to import scipy
     py::object scipy = py::module_::import("scipy");
     return scipy.attr("__version__");


 .. _calling_python_functions:

 Calling Python functions
 ========================

 It is also possible to call Python classes, functions and methods
 via ``operator()``.

 .. code-block:: cpp

     // Construct a Python object of class Decimal
     py::object pi = Decimal("3.14159");

 .. code-block:: cpp

     // Use Python to make our directories
     py::object os = py::module_::import("os");
     py::object makedirs = os.attr("makedirs");
     makedirs("/tmp/path/to/somewhere");

 One can convert the result obtained from Python to a pure C++ version
 if a ``py::class_`` or type conversion is defined.

 .. code-block:: cpp

     py::function f = <...>;
     py::object result_py = f(1234, "hello", some_instance);
     MyClass &result = result_py.cast<MyClass>();

 .. _calling_python_methods:

 Calling Python methods
 ========================

 To call an object's method, one can again use ``.attr`` to obtain access to the
 Python method.

 .. code-block:: cpp

     // Calculate e^π in decimal
     py::object exp_pi = pi.attr("exp")();
     py::print(py::str(exp_pi));

 In the example above ``pi.attr("exp")`` is a *bound method*: it will always call
 the method for that same instance of the class. Alternately one can create an
 *unbound method* via the Python class (instead of instance) and pass the ``self``
 object explicitly, followed by other arguments.

 .. code-block:: cpp

     py::object decimal_exp = Decimal.attr("exp");

     // Compute the e^n for n=0..4
     for (int n = 0; n < 5; n++) {
         py::print(decimal_exp(Decimal(n));
     }

 Keyword arguments
 =================

 Keyword arguments are also supported. In Python, there is the usual call syntax:

 .. code-block:: python

     def f(number, say, to):
         ...  # function code


     f(1234, say="hello", to=some_instance)  # keyword call in Python

 In C++, the same call can be made using:

 .. code-block:: cpp

     using namespace pybind11::literals; // to bring in the `_a` literal
     f(1234, "say"_a="hello", "to"_a=some_instance); // keyword call in C++

 Unpacking arguments
 ===================

 Unpacking of ``*args`` and ``**kwargs`` is also possible and can be mixed with
 other arguments:

 .. code-block:: cpp

     // * unpacking
     py::tuple args = py::make_tuple(1234, "hello", some_instance);
     f(*args);

     // ** unpacking
     py::dict kwargs = py::dict("number"_a=1234, "say"_a="hello", "to"_a=some_instance);
     f(**kwargs);

     // mixed keywords, * and ** unpacking
     py::tuple args = py::make_tuple(1234);
     py::dict kwargs = py::dict("to"_a=some_instance);
     f(*args, "say"_a="hello", **kwargs);

 Generalized unpacking according to PEP448_ is also supported:

 .. code-block:: cpp

     py::dict kwargs1 = py::dict("number"_a=1234);
     py::dict kwargs2 = py::dict("to"_a=some_instance);
     f(**kwargs1, "say"_a="hello", **kwargs2);

 .. seealso::

     The file :file:`tests/test_pytypes.cpp` contains a complete
     example that demonstrates passing native Python types in more detail. The
     file :file:`tests/test_callbacks.cpp` presents a few examples of calling
     Python functions from C++, including keywords arguments and unpacking.

 .. _PEP448: https://www.python.org/dev/peps/pep-0448/

 .. _implicit_casting:

 Implicit casting
 ================

 When using the C++ interface for Python types, or calling Python functions,
 objects of type :class:`object` are returned. It is possible to invoke implicit
 conversions to subclasses like :class:`dict`. The same holds for the proxy objects
 returned by ``operator[]`` or ``obj.attr()``.
 Casting to subtypes improves code readability and allows values to be passed to
 C++ functions that require a specific subtype rather than a generic :class:`object`.

 .. code-block:: cpp

     #include <pybind11/numpy.h>
     using namespace pybind11::literals;

     py::module_ os = py::module_::import("os");
     py::module_ path = py::module_::import("os.path");  // like 'import os.path as path'
     py::module_ np = py::module_::import("numpy");  // like 'import numpy as np'

     py::str curdir_abs = path.attr("abspath")(path.attr("curdir"));
     py::print(py::str("Current directory: ") + curdir_abs);
     py::dict environ = os.attr("environ");
     py::print(environ["HOME"]);
     py::array_t<float> arr = np.attr("ones")(3, "dtype"_a="float32");
     py::print(py::repr(arr + py::int_(1)));

 These implicit conversions are available for subclasses of :class:`object`; there
 is no need to call ``obj.cast()`` explicitly as for custom classes, see
 :ref:`casting_back_and_forth`.

 .. note::
     If a trivial conversion via move constructor is not possible, both implicit and
     explicit casting (calling ``obj.cast()``) will attempt a "rich" conversion.
     For instance, ``py::list env = os.attr("environ");`` will succeed and is
     equivalent to the Python code ``env = list(os.environ)`` that produces a
     list of the dict keys.

 ..  TODO: Adapt text once PR #2349 has landed

 Handling exceptions
 ===================

 Python exceptions from wrapper classes will be thrown as a ``py::error_already_set``.
 See :ref:`Handling exceptions from Python in C++
 <handling_python_exceptions_cpp>` for more information on handling exceptions
 raised when calling C++ wrapper classes.

 .. _pytypes_gotchas:

 Gotchas
 =======

 Default-Constructed Wrappers
 ----------------------------

 When a wrapper type is default-constructed, it is **not** a valid Python object (i.e. it is not ``py::none()``). It is simply the same as
 ``PyObject*`` null pointer. To check for this, use
 ``static_cast<bool>(my_wrapper)``.

 Assigning py::none() to wrappers
 --------------------------------

 You may be tempted to use types like ``py::str`` and ``py::dict`` in C++
 signatures (either pure C++, or in bound signatures), and assign them default
 values of ``py::none()``. However, in a best case scenario, it will fail fast
 because ``None`` is not convertible to that type (e.g. ``py::dict``), or in a
 worse case scenario, it will silently work but corrupt the types you want to
 work with (e.g. ``py::str(py::none())`` will yield ``"None"`` in Python).
	Python types
	############

	.. _wrappers:

	Available wrappers
	==================

	All major Python types are available as thin C++ wrapper classes. These
	can also be used as function parameters -- see :ref:`python_objects_as_args`.

	Available types include :class:`handle`, :class:`object`, :class:`bool_`,
	:class:`int_`, :class:`float_`, :class:`str`, :class:`bytes`, :class:`tuple`,
	:class:`list`, :class:`dict`, :class:`slice`, :class:`none`, :class:`capsule`,
	:class:`iterable`, :class:`iterator`, :class:`function`, :class:`buffer`,
	:class:`array`, and :class:`array_t`.

	.. warning::

	Be sure to review the :ref:`pytypes_gotchas` before using this heavily in
	your C++ API.

	.. _instantiating_compound_types:

	Instantiating compound Python types from C++
	============================================

	Dictionaries can be initialized in the :class:`dict` constructor:

	.. code-block:: cpp

	using namespace pybind11::literals; // to bring in the `_a` literal
	py::dict d("spam"_a=py::none(), "eggs"_a=42);

	A tuple of python objects can be instantiated using :func:`py::make_tuple`:

	.. code-block:: cpp

	py::tuple tup = py::make_tuple(42, py::none(), "spam");

	Each element is converted to a supported Python type.

	A `simple namespace`_ can be instantiated using

	.. code-block:: cpp

	using namespace pybind11::literals; // to bring in the `_a` literal
	py::object SimpleNamespace = py::module_::import("types").attr("SimpleNamespace");
	py::object ns = SimpleNamespace("spam"_a=py::none(), "eggs"_a=42);

	Attributes on a namespace can be modified with the :func:`py::delattr`,
	:func:`py::getattr`, and :func:`py::setattr` functions. Simple namespaces can
	be useful as lightweight stand-ins for class instances.

	.. _simple namespace: https://docs.python.org/3/library/types.html#types.SimpleNamespace

	.. _casting_back_and_forth:

	Casting back and forth
	======================

	In this kind of mixed code, it is often necessary to convert arbitrary C++
	types to Python, which can be done using :func:`py::cast`:

	.. code-block:: cpp

	MyClass *cls = ...;
	py::object obj = py::cast(cls);

	The reverse direction uses the following syntax:

	.. code-block:: cpp

	py::object obj = ...;
	MyClass cls = obj.cast<MyClass >();

	When conversion fails, both directions throw the exception :class:`cast_error`.

	.. _python_libs:

	Accessing Python libraries from C++
	===================================

	It is also possible to import objects defined in the Python standard
	library or available in the current Python environment (``sys.path``) and work
	with these in C++.

	This example obtains a reference to the Python ``Decimal`` class.

	.. code-block:: cpp

	// Equivalent to "from decimal import Decimal"
	py::object Decimal = py::module_::import("decimal").attr("Decimal");

	.. code-block:: cpp

	// Try to import scipy
	py::object scipy = py::module_::import("scipy");
	return scipy.attr("__version__");


	.. _calling_python_functions:

	Calling Python functions
	========================

	It is also possible to call Python classes, functions and methods
	via ``operator()``.

	.. code-block:: cpp

	// Construct a Python object of class Decimal
	py::object pi = Decimal("3.14159");

	.. code-block:: cpp

	// Use Python to make our directories
	py::object os = py::module_::import("os");
	py::object makedirs = os.attr("makedirs");
	makedirs("/tmp/path/to/somewhere");

	One can convert the result obtained from Python to a pure C++ version
	if a ``py::class_`` or type conversion is defined.

	.. code-block:: cpp

	py::function f = <...>;
	py::object result_py = f(1234, "hello", some_instance);
	MyClass &result = result_py.cast<MyClass>();

	.. _calling_python_methods:

	Calling Python methods
	========================

	To call an object's method, one can again use ``.attr`` to obtain access to the
	Python method.

	.. code-block:: cpp

	// Calculate e^π in decimal
	py::object exp_pi = pi.attr("exp")();
	py::print(py::str(exp_pi));

	In the example above ``pi.attr("exp")`` is a bound method: it will always call
	the method for that same instance of the class. Alternately one can create an
	unbound method via the Python class (instead of instance) and pass the ``self``
	object explicitly, followed by other arguments.

	.. code-block:: cpp

	py::object decimal_exp = Decimal.attr("exp");

	// Compute the e^n for n=0..4
	for (int n = 0; n < 5; n++) {
	py::print(decimal_exp(Decimal(n));
	}

	Keyword arguments
	=================

	Keyword arguments are also supported. In Python, there is the usual call syntax:

	.. code-block:: python

	def f(number, say, to):
	... # function code


	f(1234, say="hello", to=some_instance) # keyword call in Python

	In C++, the same call can be made using:

	.. code-block:: cpp

	using namespace pybind11::literals; // to bring in the `_a` literal
	f(1234, "say"_a="hello", "to"_a=some_instance); // keyword call in C++

	Unpacking arguments
	===================

	Unpacking of ``args`` and ``*kwargs`` is also possible and can be mixed with
	other arguments:

	.. code-block:: cpp

	// * unpacking
	py::tuple args = py::make_tuple(1234, "hello", some_instance);
	f(*args);

	// ** unpacking
	py::dict kwargs = py::dict("number"_a=1234, "say"_a="hello", "to"_a=some_instance);
	f(**kwargs);

	// mixed keywords, * and ** unpacking
	py::tuple args = py::make_tuple(1234);
	py::dict kwargs = py::dict("to"_a=some_instance);
	f(args, "say"_a="hello", *kwargs);

	Generalized unpacking according to PEP448_ is also supported:

	.. code-block:: cpp

	py::dict kwargs1 = py::dict("number"_a=1234);
	py::dict kwargs2 = py::dict("to"_a=some_instance);
	f(kwargs1, "say"_a="hello", kwargs2);

	.. seealso::

	The file :file:`tests/test_pytypes.cpp` contains a complete
	example that demonstrates passing native Python types in more detail. The
	file :file:`tests/test_callbacks.cpp` presents a few examples of calling
	Python functions from C++, including keywords arguments and unpacking.

	.. _PEP448: https://www.python.org/dev/peps/pep-0448/

	.. _implicit_casting:

	Implicit casting
	================

	When using the C++ interface for Python types, or calling Python functions,
	objects of type :class:`object` are returned. It is possible to invoke implicit
	conversions to subclasses like :class:`dict`. The same holds for the proxy objects
	returned by ``operator[]`` or ``obj.attr()``.
	Casting to subtypes improves code readability and allows values to be passed to
	C++ functions that require a specific subtype rather than a generic :class:`object`.

	.. code-block:: cpp

	#include <pybind11/numpy.h>
	using namespace pybind11::literals;

	py::module_ os = py::module_::import("os");
	py::module_ path = py::module_::import("os.path"); // like 'import os.path as path'
	py::module_ np = py::module_::import("numpy"); // like 'import numpy as np'

	py::str curdir_abs = path.attr("abspath")(path.attr("curdir"));
	py::print(py::str("Current directory: ") + curdir_abs);
	py::dict environ = os.attr("environ");
	py::print(environ["HOME"]);
	py::array_t<float> arr = np.attr("ones")(3, "dtype"_a="float32");
	py::print(py::repr(arr + py::int_(1)));

	These implicit conversions are available for subclasses of :class:`object`; there
	is no need to call ``obj.cast()`` explicitly as for custom classes, see
	:ref:`casting_back_and_forth`.

	.. note::
	If a trivial conversion via move constructor is not possible, both implicit and
	explicit casting (calling ``obj.cast()``) will attempt a "rich" conversion.
	For instance, ``py::list env = os.attr("environ");`` will succeed and is
	equivalent to the Python code ``env = list(os.environ)`` that produces a
	list of the dict keys.

	.. TODO: Adapt text once PR #2349 has landed

	Handling exceptions
	===================

	Python exceptions from wrapper classes will be thrown as a ``py::error_already_set``.
	See :ref:`Handling exceptions from Python in C++
	<handling_python_exceptions_cpp>` for more information on handling exceptions
	raised when calling C++ wrapper classes.

	.. _pytypes_gotchas:

	Gotchas
	=======

	Default-Constructed Wrappers
	----------------------------

	When a wrapper type is default-constructed, it is not a valid Python object (i.e. it is not ``py::none()``). It is simply the same as
	``PyObject*`` null pointer. To check for this, use
	``static_cast<bool>(my_wrapper)``.

	Assigning py::none() to wrappers
	--------------------------------

	You may be tempted to use types like ``py::str`` and ``py::dict`` in C++
	signatures (either pure C++, or in bound signatures), and assign them default
	values of ``py::none()``. However, in a best case scenario, it will fail fast
	because ``None`` is not convertible to that type (e.g. ``py::dict``), or in a
	worse case scenario, it will silently work but corrupt the types you want to
	work with (e.g. ``py::str(py::none())`` will yield ``"None"`` in Python).