508 lines
23 KiB
ReStructuredText
508 lines
23 KiB
ReStructuredText
Functions
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#########
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Before proceeding with this section, make sure that you are already familiar
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with the basics of binding functions and classes, as explained in :doc:`/basics`
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and :doc:`/classes`. The following guide is applicable to both free and member
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functions, i.e. *methods* in Python.
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.. _return_value_policies:
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Return value policies
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=====================
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Python and C++ use fundamentally different ways of managing the memory and
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lifetime of objects managed by them. This can lead to issues when creating
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bindings for functions that return a non-trivial type. Just by looking at the
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type information, it is not clear whether Python should take charge of the
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returned value and eventually free its resources, or if this is handled on the
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C++ side. For this reason, pybind11 provides a several *return value policy*
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annotations that can be passed to the :func:`module::def` and
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:func:`class_::def` functions. The default policy is
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:enum:`return_value_policy::automatic`.
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Return value policies are tricky, and it's very important to get them right.
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Just to illustrate what can go wrong, consider the following simple example:
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.. code-block:: cpp
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/* Function declaration */
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Data *get_data() { return _data; /* (pointer to a static data structure) */ }
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...
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/* Binding code */
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m.def("get_data", &get_data); // <-- KABOOM, will cause crash when called from Python
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What's going on here? When ``get_data()`` is called from Python, the return
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value (a native C++ type) must be wrapped to turn it into a usable Python type.
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In this case, the default return value policy (:enum:`return_value_policy::automatic`)
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causes pybind11 to assume ownership of the static ``_data`` instance.
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When Python's garbage collector eventually deletes the Python
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wrapper, pybind11 will also attempt to delete the C++ instance (via ``operator
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delete()``) due to the implied ownership. At this point, the entire application
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will come crashing down, though errors could also be more subtle and involve
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silent data corruption.
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In the above example, the policy :enum:`return_value_policy::reference` should have
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been specified so that the global data instance is only *referenced* without any
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implied transfer of ownership, i.e.:
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.. code-block:: cpp
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m.def("get_data", &get_data, return_value_policy::reference);
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On the other hand, this is not the right policy for many other situations,
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where ignoring ownership could lead to resource leaks.
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As a developer using pybind11, it's important to be familiar with the different
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return value policies, including which situation calls for which one of them.
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The following table provides an overview of available policies:
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.. tabularcolumns:: |p{0.5\textwidth}|p{0.45\textwidth}|
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+--------------------------------------------------+----------------------------------------------------------------------------+
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| Return value policy | Description |
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+==================================================+============================================================================+
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| :enum:`return_value_policy::take_ownership` | Reference an existing object (i.e. do not create a new copy) and take |
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| | ownership. Python will call the destructor and delete operator when the |
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| | object's reference count reaches zero. Undefined behavior ensues when the |
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| | C++ side does the same, or when the data was not dynamically allocated. |
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+--------------------------------------------------+----------------------------------------------------------------------------+
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| :enum:`return_value_policy::copy` | Create a new copy of the returned object, which will be owned by Python. |
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| | This policy is comparably safe because the lifetimes of the two instances |
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| | are decoupled. |
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+--------------------------------------------------+----------------------------------------------------------------------------+
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| :enum:`return_value_policy::move` | Use ``std::move`` to move the return value contents into a new instance |
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| | that will be owned by Python. This policy is comparably safe because the |
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| | lifetimes of the two instances (move source and destination) are decoupled.|
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+--------------------------------------------------+----------------------------------------------------------------------------+
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| :enum:`return_value_policy::reference` | Reference an existing object, but do not take ownership. The C++ side is |
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| | responsible for managing the object's lifetime and deallocating it when |
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| | it is no longer used. Warning: undefined behavior will ensue when the C++ |
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| | side deletes an object that is still referenced and used by Python. |
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+--------------------------------------------------+----------------------------------------------------------------------------+
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| :enum:`return_value_policy::reference_internal` | Indicates that the lifetime of the return value is tied to the lifetime |
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| | of a parent object, namely the implicit ``this``, or ``self`` argument of |
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| | the called method or property. Internally, this policy works just like |
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| | :enum:`return_value_policy::reference` but additionally applies a |
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| | ``keep_alive<0, 1>`` *call policy* (described in the next section) that |
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| | prevents the parent object from being garbage collected as long as the |
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| | return value is referenced by Python. This is the default policy for |
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| | property getters created via ``def_property``, ``def_readwrite``, etc. |
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+--------------------------------------------------+----------------------------------------------------------------------------+
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| :enum:`return_value_policy::automatic` | **Default policy.** This policy falls back to the policy |
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| | :enum:`return_value_policy::take_ownership` when the return value is a |
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| | pointer. Otherwise, it uses :enum:`return_value_policy::move` or |
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| | :enum:`return_value_policy::copy` for rvalue and lvalue references, |
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| | respectively. See above for a description of what all of these different |
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| | policies do. |
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+--------------------------------------------------+----------------------------------------------------------------------------+
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| :enum:`return_value_policy::automatic_reference` | As above, but use policy :enum:`return_value_policy::reference` when the |
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| | return value is a pointer. This is the default conversion policy for |
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| | function arguments when calling Python functions manually from C++ code |
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| | (i.e. via handle::operator()). You probably won't need to use this. |
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+--------------------------------------------------+----------------------------------------------------------------------------+
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Return value policies can also be applied to properties:
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.. code-block:: cpp
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class_<MyClass>(m, "MyClass")
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.def_property("data", &MyClass::getData, &MyClass::setData,
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py::return_value_policy::copy);
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Technically, the code above applies the policy to both the getter and the
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setter function, however, the setter doesn't really care about *return*
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value policies which makes this a convenient terse syntax. Alternatively,
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targeted arguments can be passed through the :class:`cpp_function` constructor:
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.. code-block:: cpp
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class_<MyClass>(m, "MyClass")
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.def_property("data"
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py::cpp_function(&MyClass::getData, py::return_value_policy::copy),
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py::cpp_function(&MyClass::setData)
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);
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.. warning::
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Code with invalid return value policies might access uninitialized memory or
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free data structures multiple times, which can lead to hard-to-debug
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non-determinism and segmentation faults, hence it is worth spending the
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time to understand all the different options in the table above.
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.. note::
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One important aspect of the above policies is that they only apply to
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instances which pybind11 has *not* seen before, in which case the policy
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clarifies essential questions about the return value's lifetime and
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ownership. When pybind11 knows the instance already (as identified by its
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type and address in memory), it will return the existing Python object
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wrapper rather than creating a new copy.
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.. note::
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The next section on :ref:`call_policies` discusses *call policies* that can be
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specified *in addition* to a return value policy from the list above. Call
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policies indicate reference relationships that can involve both return values
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and parameters of functions.
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.. note::
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As an alternative to elaborate call policies and lifetime management logic,
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consider using smart pointers (see the section on :ref:`smart_pointers` for
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details). Smart pointers can tell whether an object is still referenced from
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C++ or Python, which generally eliminates the kinds of inconsistencies that
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can lead to crashes or undefined behavior. For functions returning smart
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pointers, it is not necessary to specify a return value policy.
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.. _call_policies:
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Additional call policies
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========================
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In addition to the above return value policies, further *call policies* can be
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specified to indicate dependencies between parameters or ensure a certain state
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for the function call.
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Keep alive
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----------
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In general, this policy is required when the C++ object is any kind of container
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and another object is being added to the container. ``keep_alive<Nurse, Patient>``
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indicates that the argument with index ``Patient`` should be kept alive at least
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until the argument with index ``Nurse`` is freed by the garbage collector. Argument
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indices start at one, while zero refers to the return value. For methods, index
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``1`` refers to the implicit ``this`` pointer, while regular arguments begin at
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index ``2``. Arbitrarily many call policies can be specified. When a ``Nurse``
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with value ``None`` is detected at runtime, the call policy does nothing.
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When the nurse is not a pybind11-registered type, the implementation internally
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relies on the ability to create a *weak reference* to the nurse object. When
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the nurse object is not a pybind11-registered type and does not support weak
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references, an exception will be thrown.
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Consider the following example: here, the binding code for a list append
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operation ties the lifetime of the newly added element to the underlying
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container:
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.. code-block:: cpp
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py::class_<List>(m, "List")
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.def("append", &List::append, py::keep_alive<1, 2>());
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For consistency, the argument indexing is identical for constructors. Index
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``1`` still refers to the implicit ``this`` pointer, i.e. the object which is
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being constructed. Index ``0`` refers to the return type which is presumed to
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be ``void`` when a constructor is viewed like a function. The following example
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ties the lifetime of the constructor element to the constructed object:
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.. code-block:: cpp
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py::class_<Nurse>(m, "Nurse")
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.def(py::init<Patient &>(), py::keep_alive<1, 2>());
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.. note::
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``keep_alive`` is analogous to the ``with_custodian_and_ward`` (if Nurse,
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Patient != 0) and ``with_custodian_and_ward_postcall`` (if Nurse/Patient ==
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0) policies from Boost.Python.
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Call guard
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----------
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The ``call_guard<T>`` policy allows any scope guard type ``T`` to be placed
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around the function call. For example, this definition:
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.. code-block:: cpp
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m.def("foo", foo, py::call_guard<T>());
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is equivalent to the following pseudocode:
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.. code-block:: cpp
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m.def("foo", [](args...) {
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T scope_guard;
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return foo(args...); // forwarded arguments
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});
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The only requirement is that ``T`` is default-constructible, but otherwise any
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scope guard will work. This is very useful in combination with `gil_scoped_release`.
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See :ref:`gil`.
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Multiple guards can also be specified as ``py::call_guard<T1, T2, T3...>``. The
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constructor order is left to right and destruction happens in reverse.
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.. seealso::
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The file :file:`tests/test_call_policies.cpp` contains a complete example
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that demonstrates using `keep_alive` and `call_guard` in more detail.
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.. _python_objects_as_args:
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Python objects as arguments
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===========================
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pybind11 exposes all major Python types using thin C++ wrapper classes. These
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wrapper classes can also be used as parameters of functions in bindings, which
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makes it possible to directly work with native Python types on the C++ side.
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For instance, the following statement iterates over a Python ``dict``:
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.. code-block:: cpp
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void print_dict(py::dict dict) {
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/* Easily interact with Python types */
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for (auto item : dict)
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std::cout << "key=" << std::string(py::str(item.first)) << ", "
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<< "value=" << std::string(py::str(item.second)) << std::endl;
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}
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It can be exported:
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.. code-block:: cpp
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m.def("print_dict", &print_dict);
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And used in Python as usual:
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.. code-block:: pycon
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>>> print_dict({'foo': 123, 'bar': 'hello'})
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key=foo, value=123
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key=bar, value=hello
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For more information on using Python objects in C++, see :doc:`/advanced/pycpp/index`.
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Accepting \*args and \*\*kwargs
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===============================
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Python provides a useful mechanism to define functions that accept arbitrary
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numbers of arguments and keyword arguments:
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.. code-block:: python
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def generic(*args, **kwargs):
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... # do something with args and kwargs
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Such functions can also be created using pybind11:
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.. code-block:: cpp
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void generic(py::args args, py::kwargs kwargs) {
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/// .. do something with args
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if (kwargs)
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/// .. do something with kwargs
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}
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/// Binding code
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m.def("generic", &generic);
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The class ``py::args`` derives from ``py::tuple`` and ``py::kwargs`` derives
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from ``py::dict``.
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You may also use just one or the other, and may combine these with other
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arguments as long as the ``py::args`` and ``py::kwargs`` arguments are the last
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arguments accepted by the function.
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Please refer to the other examples for details on how to iterate over these,
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and on how to cast their entries into C++ objects. A demonstration is also
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available in ``tests/test_kwargs_and_defaults.cpp``.
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.. note::
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When combining \*args or \*\*kwargs with :ref:`keyword_args` you should
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*not* include ``py::arg`` tags for the ``py::args`` and ``py::kwargs``
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arguments.
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Default arguments revisited
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===========================
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The section on :ref:`default_args` previously discussed basic usage of default
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arguments using pybind11. One noteworthy aspect of their implementation is that
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default arguments are converted to Python objects right at declaration time.
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Consider the following example:
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.. code-block:: cpp
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py::class_<MyClass>("MyClass")
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.def("myFunction", py::arg("arg") = SomeType(123));
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In this case, pybind11 must already be set up to deal with values of the type
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``SomeType`` (via a prior instantiation of ``py::class_<SomeType>``), or an
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exception will be thrown.
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Another aspect worth highlighting is that the "preview" of the default argument
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in the function signature is generated using the object's ``__repr__`` method.
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If not available, the signature may not be very helpful, e.g.:
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.. code-block:: pycon
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FUNCTIONS
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...
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| myFunction(...)
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| Signature : (MyClass, arg : SomeType = <SomeType object at 0x101b7b080>) -> NoneType
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...
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The first way of addressing this is by defining ``SomeType.__repr__``.
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Alternatively, it is possible to specify the human-readable preview of the
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default argument manually using the ``arg_v`` notation:
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.. code-block:: cpp
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py::class_<MyClass>("MyClass")
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.def("myFunction", py::arg_v("arg", SomeType(123), "SomeType(123)"));
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Sometimes it may be necessary to pass a null pointer value as a default
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argument. In this case, remember to cast it to the underlying type in question,
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like so:
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.. code-block:: cpp
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py::class_<MyClass>("MyClass")
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.def("myFunction", py::arg("arg") = (SomeType *) nullptr);
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.. _nonconverting_arguments:
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Non-converting arguments
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========================
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Certain argument types may support conversion from one type to another. Some
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examples of conversions are:
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* :ref:`implicit_conversions` declared using ``py::implicitly_convertible<A,B>()``
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* Calling a method accepting a double with an integer argument
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* Calling a ``std::complex<float>`` argument with a non-complex python type
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(for example, with a float). (Requires the optional ``pybind11/complex.h``
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header).
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* Calling a function taking an Eigen matrix reference with a numpy array of the
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wrong type or of an incompatible data layout. (Requires the optional
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``pybind11/eigen.h`` header).
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This behaviour is sometimes undesirable: the binding code may prefer to raise
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an error rather than convert the argument. This behaviour can be obtained
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through ``py::arg`` by calling the ``.noconvert()`` method of the ``py::arg``
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object, such as:
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.. code-block:: cpp
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m.def("floats_only", [](double f) { return 0.5 * f; }, py::arg("f").noconvert());
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m.def("floats_preferred", [](double f) { return 0.5 * f; }, py::arg("f"));
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Attempting the call the second function (the one without ``.noconvert()``) with
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an integer will succeed, but attempting to call the ``.noconvert()`` version
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will fail with a ``TypeError``:
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.. code-block:: pycon
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>>> floats_preferred(4)
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2.0
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>>> floats_only(4)
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Traceback (most recent call last):
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File "<stdin>", line 1, in <module>
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TypeError: floats_only(): incompatible function arguments. The following argument types are supported:
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1. (f: float) -> float
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Invoked with: 4
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You may, of course, combine this with the :var:`_a` shorthand notation (see
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:ref:`keyword_args`) and/or :ref:`default_args`. It is also permitted to omit
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the argument name by using the ``py::arg()`` constructor without an argument
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name, i.e. by specifying ``py::arg().noconvert()``.
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.. note::
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When specifying ``py::arg`` options it is necessary to provide the same
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number of options as the bound function has arguments. Thus if you want to
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enable no-convert behaviour for just one of several arguments, you will
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need to specify a ``py::arg()`` annotation for each argument with the
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no-convert argument modified to ``py::arg().noconvert()``.
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.. _none_arguments:
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Allow/Prohibiting None arguments
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================================
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When a C++ type registered with :class:`py::class_` is passed as an argument to
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a function taking the instance as pointer or shared holder (e.g. ``shared_ptr``
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or a custom, copyable holder as described in :ref:`smart_pointers`), pybind
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allows ``None`` to be passed from Python which results in calling the C++
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function with ``nullptr`` (or an empty holder) for the argument.
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To explicitly enable or disable this behaviour, using the
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``.none`` method of the :class:`py::arg` object:
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.. code-block:: cpp
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py::class_<Dog>(m, "Dog").def(py::init<>());
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py::class_<Cat>(m, "Cat").def(py::init<>());
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m.def("bark", [](Dog *dog) -> std::string {
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if (dog) return "woof!"; /* Called with a Dog instance */
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else return "(no dog)"; /* Called with None, dog == nullptr */
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}, py::arg("dog").none(true));
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m.def("meow", [](Cat *cat) -> std::string {
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// Can't be called with None argument
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return "meow";
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}, py::arg("cat").none(false));
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With the above, the Python call ``bark(None)`` will return the string ``"(no
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dog)"``, while attempting to call ``meow(None)`` will raise a ``TypeError``:
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.. code-block:: pycon
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>>> from animals import Dog, Cat, bark, meow
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>>> bark(Dog())
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'woof!'
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>>> meow(Cat())
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'meow'
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>>> bark(None)
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'(no dog)'
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>>> meow(None)
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Traceback (most recent call last):
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File "<stdin>", line 1, in <module>
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TypeError: meow(): incompatible function arguments. The following argument types are supported:
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1. (cat: animals.Cat) -> str
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Invoked with: None
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The default behaviour when the tag is unspecified is to allow ``None``.
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.. note::
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Even when ``.none(true)`` is specified for an argument, ``None`` will be converted to a
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``nullptr`` *only* for custom and :ref:`opaque <opaque>` types. Pointers to built-in types
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(``double *``, ``int *``, ...) and STL types (``std::vector<T> *``, ...; if ``pybind11/stl.h``
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is included) are copied when converted to C++ (see :doc:`/advanced/cast/overview`) and will
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not allow ``None`` as argument. To pass optional argument of these copied types consider
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using ``std::optional<T>``
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Overload resolution order
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=========================
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When a function or method with multiple overloads is called from Python,
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pybind11 determines which overload to call in two passes. The first pass
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attempts to call each overload without allowing argument conversion (as if
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every argument had been specified as ``py::arg().noconvert()`` as described
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|
above).
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If no overload succeeds in the no-conversion first pass, a second pass is
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|
attempted in which argument conversion is allowed (except where prohibited via
|
|
an explicit ``py::arg().noconvert()`` attribute in the function definition).
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If the second pass also fails a ``TypeError`` is raised.
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Within each pass, overloads are tried in the order they were registered with
|
|
pybind11.
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What this means in practice is that pybind11 will prefer any overload that does
|
|
not require conversion of arguments to an overload that does, but otherwise prefers
|
|
earlier-defined overloads to later-defined ones.
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|
.. note::
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|
|
|
pybind11 does *not* further prioritize based on the number/pattern of
|
|
overloaded arguments. That is, pybind11 does not prioritize a function
|
|
requiring one conversion over one requiring three, but only prioritizes
|
|
overloads requiring no conversion at all to overloads that require
|
|
conversion of at least one argument.
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