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635 lines
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635 lines
22 KiB
ReStructuredText
Classes
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#######
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This section presents advanced binding code for classes and it is assumed
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that you are already familiar with the basics from :doc:`/classes`.
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.. _overriding_virtuals:
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Overriding virtual functions in Python
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======================================
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Suppose that a C++ class or interface has a virtual function that we'd like to
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to override from within Python (we'll focus on the class ``Animal``; ``Dog`` is
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given as a specific example of how one would do this with traditional C++
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code).
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.. code-block:: cpp
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class Animal {
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public:
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virtual ~Animal() { }
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virtual std::string go(int n_times) = 0;
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};
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class Dog : public Animal {
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public:
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std::string go(int n_times) override {
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std::string result;
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for (int i=0; i<n_times; ++i)
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result += "woof! ";
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return result;
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}
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};
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Let's also suppose that we are given a plain function which calls the
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function ``go()`` on an arbitrary ``Animal`` instance.
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.. code-block:: cpp
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std::string call_go(Animal *animal) {
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return animal->go(3);
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}
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Normally, the binding code for these classes would look as follows:
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.. code-block:: cpp
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PYBIND11_PLUGIN(example) {
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py::module m("example", "pybind11 example plugin");
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py::class_<Animal> animal(m, "Animal");
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animal
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.def("go", &Animal::go);
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py::class_<Dog>(m, "Dog", animal)
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.def(py::init<>());
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m.def("call_go", &call_go);
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return m.ptr();
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}
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However, these bindings are impossible to extend: ``Animal`` is not
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constructible, and we clearly require some kind of "trampoline" that
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redirects virtual calls back to Python.
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Defining a new type of ``Animal`` from within Python is possible but requires a
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helper class that is defined as follows:
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.. code-block:: cpp
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class PyAnimal : public Animal {
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public:
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/* Inherit the constructors */
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using Animal::Animal;
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/* Trampoline (need one for each virtual function) */
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std::string go(int n_times) override {
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PYBIND11_OVERLOAD_PURE(
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std::string, /* Return type */
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Animal, /* Parent class */
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go, /* Name of function */
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n_times /* Argument(s) */
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);
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}
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};
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The macro :func:`PYBIND11_OVERLOAD_PURE` should be used for pure virtual
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functions, and :func:`PYBIND11_OVERLOAD` should be used for functions which have
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a default implementation. There are also two alternate macros
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:func:`PYBIND11_OVERLOAD_PURE_NAME` and :func:`PYBIND11_OVERLOAD_NAME` which
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take a string-valued name argument between the *Parent class* and *Name of the
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function* slots. This is useful when the C++ and Python versions of the
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function have different names, e.g. ``operator()`` vs ``__call__``.
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The binding code also needs a few minor adaptations (highlighted):
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.. code-block:: cpp
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:emphasize-lines: 4,6,7
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PYBIND11_PLUGIN(example) {
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py::module m("example", "pybind11 example plugin");
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py::class_<Animal, PyAnimal /* <--- trampoline*/> animal(m, "Animal");
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animal
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.def(py::init<>())
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.def("go", &Animal::go);
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py::class_<Dog>(m, "Dog", animal)
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.def(py::init<>());
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m.def("call_go", &call_go);
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return m.ptr();
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}
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Importantly, pybind11 is made aware of the trampoline helper class by
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specifying it as an extra template argument to :class:`class_`. (This can also
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be combined with other template arguments such as a custom holder type; the
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order of template types does not matter). Following this, we are able to
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define a constructor as usual.
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Note, however, that the above is sufficient for allowing python classes to
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extend ``Animal``, but not ``Dog``: see ref:`virtual_and_inheritance` for the
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necessary steps required to providing proper overload support for inherited
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classes.
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The Python session below shows how to override ``Animal::go`` and invoke it via
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a virtual method call.
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.. code-block:: pycon
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>>> from example import *
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>>> d = Dog()
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>>> call_go(d)
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u'woof! woof! woof! '
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>>> class Cat(Animal):
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... def go(self, n_times):
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... return "meow! " * n_times
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...
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>>> c = Cat()
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>>> call_go(c)
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u'meow! meow! meow! '
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Please take a look at the :ref:`macro_notes` before using this feature.
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.. note::
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When the overridden type returns a reference or pointer to a type that
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pybind11 converts from Python (for example, numeric values, std::string,
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and other built-in value-converting types), there are some limitations to
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be aware of:
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- because in these cases there is no C++ variable to reference (the value
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is stored in the referenced Python variable), pybind11 provides one in
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the PYBIND11_OVERLOAD macros (when needed) with static storage duration.
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Note that this means that invoking the overloaded method on *any*
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instance will change the referenced value stored in *all* instances of
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that type.
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- Attempts to modify a non-const reference will not have the desired
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effect: it will change only the static cache variable, but this change
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will not propagate to underlying Python instance, and the change will be
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replaced the next time the overload is invoked.
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.. seealso::
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The file :file:`tests/test_virtual_functions.cpp` contains a complete
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example that demonstrates how to override virtual functions using pybind11
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in more detail.
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.. _virtual_and_inheritance:
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Combining virtual functions and inheritance
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===========================================
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When combining virtual methods with inheritance, you need to be sure to provide
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an override for each method for which you want to allow overrides from derived
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python classes. For example, suppose we extend the above ``Animal``/``Dog``
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example as follows:
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.. code-block:: cpp
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class Animal {
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public:
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virtual std::string go(int n_times) = 0;
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virtual std::string name() { return "unknown"; }
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};
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class Dog : public class Animal {
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public:
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std::string go(int n_times) override {
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std::string result;
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for (int i=0; i<n_times; ++i)
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result += bark() + " ";
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return result;
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}
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virtual std::string bark() { return "woof!"; }
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};
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then the trampoline class for ``Animal`` must, as described in the previous
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section, override ``go()`` and ``name()``, but in order to allow python code to
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inherit properly from ``Dog``, we also need a trampoline class for ``Dog`` that
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overrides both the added ``bark()`` method *and* the ``go()`` and ``name()``
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methods inherited from ``Animal`` (even though ``Dog`` doesn't directly
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override the ``name()`` method):
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.. code-block:: cpp
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class PyAnimal : public Animal {
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public:
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using Animal::Animal; // Inherit constructors
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std::string go(int n_times) override { PYBIND11_OVERLOAD_PURE(std::string, Animal, go, n_times); }
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std::string name() override { PYBIND11_OVERLOAD(std::string, Animal, name, ); }
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};
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class PyDog : public Dog {
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public:
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using Dog::Dog; // Inherit constructors
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std::string go(int n_times) override { PYBIND11_OVERLOAD_PURE(std::string, Dog, go, n_times); }
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std::string name() override { PYBIND11_OVERLOAD(std::string, Dog, name, ); }
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std::string bark() override { PYBIND11_OVERLOAD(std::string, Dog, bark, ); }
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};
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A registered class derived from a pybind11-registered class with virtual
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methods requires a similar trampoline class, *even if* it doesn't explicitly
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declare or override any virtual methods itself:
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.. code-block:: cpp
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class Husky : public Dog {};
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class PyHusky : public Husky {
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using Dog::Dog; // Inherit constructors
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std::string go(int n_times) override { PYBIND11_OVERLOAD_PURE(std::string, Husky, go, n_times); }
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std::string name() override { PYBIND11_OVERLOAD(std::string, Husky, name, ); }
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std::string bark() override { PYBIND11_OVERLOAD(std::string, Husky, bark, ); }
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};
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There is, however, a technique that can be used to avoid this duplication
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(which can be especially helpful for a base class with several virtual
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methods). The technique involves using template trampoline classes, as
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follows:
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.. code-block:: cpp
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template <class AnimalBase = Animal> class PyAnimal : public AnimalBase {
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using AnimalBase::AnimalBase; // Inherit constructors
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std::string go(int n_times) override { PYBIND11_OVERLOAD_PURE(std::string, AnimalBase, go, n_times); }
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std::string name() override { PYBIND11_OVERLOAD(std::string, AnimalBase, name, ); }
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};
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template <class DogBase = Dog> class PyDog : public PyAnimal<DogBase> {
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using PyAnimal<DogBase>::PyAnimal; // Inherit constructors
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// Override PyAnimal's pure virtual go() with a non-pure one:
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std::string go(int n_times) override { PYBIND11_OVERLOAD(std::string, DogBase, go, n_times); }
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std::string bark() override { PYBIND11_OVERLOAD(std::string, DogBase, bark, ); }
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};
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This technique has the advantage of requiring just one trampoline method to be
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declared per virtual method and pure virtual method override. It does,
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however, require the compiler to generate at least as many methods (and
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possibly more, if both pure virtual and overridden pure virtual methods are
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exposed, as above).
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The classes are then registered with pybind11 using:
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.. code-block:: cpp
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py::class_<Animal, PyAnimal<>> animal(m, "Animal");
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py::class_<Dog, PyDog<>> dog(m, "Dog");
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py::class_<Husky, PyDog<Husky>> husky(m, "Husky");
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// ... add animal, dog, husky definitions
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Note that ``Husky`` did not require a dedicated trampoline template class at
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all, since it neither declares any new virtual methods nor provides any pure
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virtual method implementations.
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With either the repeated-virtuals or templated trampoline methods in place, you
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can now create a python class that inherits from ``Dog``:
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.. code-block:: python
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class ShihTzu(Dog):
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def bark(self):
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return "yip!"
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.. seealso::
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See the file :file:`tests/test_virtual_functions.cpp` for complete examples
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using both the duplication and templated trampoline approaches.
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Extended trampoline class functionality
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=======================================
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The trampoline classes described in the previous sections are, by default, only
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initialized when needed. More specifically, they are initialized when a python
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class actually inherits from a registered type (instead of merely creating an
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instance of the registered type), or when a registered constructor is only
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valid for the trampoline class but not the registered class. This is primarily
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for performance reasons: when the trampoline class is not needed for anything
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except virtual method dispatching, not initializing the trampoline class
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improves performance by avoiding needing to do a run-time check to see if the
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inheriting python instance has an overloaded method.
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Sometimes, however, it is useful to always initialize a trampoline class as an
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intermediate class that does more than just handle virtual method dispatching.
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For example, such a class might perform extra class initialization, extra
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destruction operations, and might define new members and methods to enable a
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more python-like interface to a class.
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In order to tell pybind11 that it should *always* initialize the trampoline
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class when creating new instances of a type, the class constructors should be
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declared using ``py::init_alias<Args, ...>()`` instead of the usual
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``py::init<Args, ...>()``. This forces construction via the trampoline class,
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ensuring member initialization and (eventual) destruction.
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.. seealso::
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See the file :file:`tests/test_alias_initialization.cpp` for complete examples
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showing both normal and forced trampoline instantiation.
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.. _custom_constructors:
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Custom constructors
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===================
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The syntax for binding constructors was previously introduced, but it only
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works when a constructor with the given parameters actually exists on the C++
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side. To extend this to more general cases, let's take a look at what actually
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happens under the hood: the following statement
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.. code-block:: cpp
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py::class_<Example>(m, "Example")
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.def(py::init<int>());
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is short hand notation for
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.. code-block:: cpp
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py::class_<Example>(m, "Example")
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.def("__init__",
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[](Example &instance, int arg) {
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new (&instance) Example(arg);
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}
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);
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In other words, :func:`init` creates an anonymous function that invokes an
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in-place constructor. Memory allocation etc. is already take care of beforehand
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within pybind11.
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.. _classes_with_non_public_destructors:
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Non-public destructors
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======================
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If a class has a private or protected destructor (as might e.g. be the case in
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a singleton pattern), a compile error will occur when creating bindings via
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pybind11. The underlying issue is that the ``std::unique_ptr`` holder type that
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is responsible for managing the lifetime of instances will reference the
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destructor even if no deallocations ever take place. In order to expose classes
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with private or protected destructors, it is possible to override the holder
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type via a holder type argument to ``class_``. Pybind11 provides a helper class
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``py::nodelete`` that disables any destructor invocations. In this case, it is
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crucial that instances are deallocated on the C++ side to avoid memory leaks.
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.. code-block:: cpp
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/* ... definition ... */
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class MyClass {
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private:
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~MyClass() { }
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};
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/* ... binding code ... */
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py::class_<MyClass, std::unique_ptr<MyClass, py::nodelete>>(m, "MyClass")
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.def(py::init<>)
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Implicit conversions
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====================
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Suppose that instances of two types ``A`` and ``B`` are used in a project, and
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that an ``A`` can easily be converted into an instance of type ``B`` (examples of this
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could be a fixed and an arbitrary precision number type).
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.. code-block:: cpp
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py::class_<A>(m, "A")
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/// ... members ...
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py::class_<B>(m, "B")
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.def(py::init<A>())
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/// ... members ...
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m.def("func",
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[](const B &) { /* .... */ }
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);
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To invoke the function ``func`` using a variable ``a`` containing an ``A``
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instance, we'd have to write ``func(B(a))`` in Python. On the other hand, C++
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will automatically apply an implicit type conversion, which makes it possible
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to directly write ``func(a)``.
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In this situation (i.e. where ``B`` has a constructor that converts from
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``A``), the following statement enables similar implicit conversions on the
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Python side:
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.. code-block:: cpp
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py::implicitly_convertible<A, B>();
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.. note::
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Implicit conversions from ``A`` to ``B`` only work when ``B`` is a custom
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data type that is exposed to Python via pybind11.
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.. _static_properties:
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Static properties
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=================
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The section on :ref:`properties` discussed the creation of instance properties
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that are implemented in terms of C++ getters and setters.
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Static properties can also be created in a similar way to expose getters and
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setters of static class attributes. It is important to note that the implicit
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``self`` argument also exists in this case and is used to pass the Python
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``type`` subclass instance. This parameter will often not be needed by the C++
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side, and the following example illustrates how to instantiate a lambda getter
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function that ignores it:
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.. code-block:: cpp
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py::class_<Foo>(m, "Foo")
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.def_property_readonly_static("foo", [](py::object /* self */) { return Foo(); });
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Operator overloading
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====================
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Suppose that we're given the following ``Vector2`` class with a vector addition
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and scalar multiplication operation, all implemented using overloaded operators
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in C++.
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.. code-block:: cpp
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class Vector2 {
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public:
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Vector2(float x, float y) : x(x), y(y) { }
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Vector2 operator+(const Vector2 &v) const { return Vector2(x + v.x, y + v.y); }
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Vector2 operator*(float value) const { return Vector2(x * value, y * value); }
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Vector2& operator+=(const Vector2 &v) { x += v.x; y += v.y; return *this; }
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Vector2& operator*=(float v) { x *= v; y *= v; return *this; }
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friend Vector2 operator*(float f, const Vector2 &v) {
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return Vector2(f * v.x, f * v.y);
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}
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std::string toString() const {
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return "[" + std::to_string(x) + ", " + std::to_string(y) + "]";
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}
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private:
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float x, y;
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};
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The following snippet shows how the above operators can be conveniently exposed
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to Python.
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.. code-block:: cpp
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#include <pybind11/operators.h>
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PYBIND11_PLUGIN(example) {
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py::module m("example", "pybind11 example plugin");
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py::class_<Vector2>(m, "Vector2")
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.def(py::init<float, float>())
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.def(py::self + py::self)
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.def(py::self += py::self)
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.def(py::self *= float())
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.def(float() * py::self)
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.def("__repr__", &Vector2::toString);
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return m.ptr();
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}
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Note that a line like
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.. code-block:: cpp
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.def(py::self * float())
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is really just short hand notation for
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.. code-block:: cpp
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.def("__mul__", [](const Vector2 &a, float b) {
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return a * b;
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}, py::is_operator())
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This can be useful for exposing additional operators that don't exist on the
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C++ side, or to perform other types of customization. The ``py::is_operator``
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flag marker is needed to inform pybind11 that this is an operator, which
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returns ``NotImplemented`` when invoked with incompatible arguments rather than
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throwing a type error.
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.. note::
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To use the more convenient ``py::self`` notation, the additional
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header file :file:`pybind11/operators.h` must be included.
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.. seealso::
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The file :file:`tests/test_operator_overloading.cpp` contains a
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complete example that demonstrates how to work with overloaded operators in
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more detail.
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Pickling support
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================
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|
Python's ``pickle`` module provides a powerful facility to serialize and
|
|
de-serialize a Python object graph into a binary data stream. To pickle and
|
|
unpickle C++ classes using pybind11, two additional functions must be provided.
|
|
Suppose the class in question has the following signature:
|
|
|
|
.. code-block:: cpp
|
|
|
|
class Pickleable {
|
|
public:
|
|
Pickleable(const std::string &value) : m_value(value) { }
|
|
const std::string &value() const { return m_value; }
|
|
|
|
void setExtra(int extra) { m_extra = extra; }
|
|
int extra() const { return m_extra; }
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|
private:
|
|
std::string m_value;
|
|
int m_extra = 0;
|
|
};
|
|
|
|
The binding code including the requisite ``__setstate__`` and ``__getstate__`` methods [#f3]_
|
|
looks as follows:
|
|
|
|
.. code-block:: cpp
|
|
|
|
py::class_<Pickleable>(m, "Pickleable")
|
|
.def(py::init<std::string>())
|
|
.def("value", &Pickleable::value)
|
|
.def("extra", &Pickleable::extra)
|
|
.def("setExtra", &Pickleable::setExtra)
|
|
.def("__getstate__", [](const Pickleable &p) {
|
|
/* Return a tuple that fully encodes the state of the object */
|
|
return py::make_tuple(p.value(), p.extra());
|
|
})
|
|
.def("__setstate__", [](Pickleable &p, py::tuple t) {
|
|
if (t.size() != 2)
|
|
throw std::runtime_error("Invalid state!");
|
|
|
|
/* Invoke the in-place constructor. Note that this is needed even
|
|
when the object just has a trivial default constructor */
|
|
new (&p) Pickleable(t[0].cast<std::string>());
|
|
|
|
/* Assign any additional state */
|
|
p.setExtra(t[1].cast<int>());
|
|
});
|
|
|
|
An instance can now be pickled as follows:
|
|
|
|
.. code-block:: python
|
|
|
|
try:
|
|
import cPickle as pickle # Use cPickle on Python 2.7
|
|
except ImportError:
|
|
import pickle
|
|
|
|
p = Pickleable("test_value")
|
|
p.setExtra(15)
|
|
data = pickle.dumps(p, 2)
|
|
|
|
Note that only the cPickle module is supported on Python 2.7. The second
|
|
argument to ``dumps`` is also crucial: it selects the pickle protocol version
|
|
2, since the older version 1 is not supported. Newer versions are also fine—for
|
|
instance, specify ``-1`` to always use the latest available version. Beware:
|
|
failure to follow these instructions will cause important pybind11 memory
|
|
allocation routines to be skipped during unpickling, which will likely lead to
|
|
memory corruption and/or segmentation faults.
|
|
|
|
.. seealso::
|
|
|
|
The file :file:`tests/test_pickling.cpp` contains a complete example
|
|
that demonstrates how to pickle and unpickle types using pybind11 in more
|
|
detail.
|
|
|
|
.. [#f3] http://docs.python.org/3/library/pickle.html#pickling-class-instances
|
|
|
|
Multiple Inheritance
|
|
====================
|
|
|
|
pybind11 can create bindings for types that derive from multiple base types
|
|
(aka. *multiple inheritance*). To do so, specify all bases in the template
|
|
arguments of the ``class_`` declaration:
|
|
|
|
.. code-block:: cpp
|
|
|
|
py::class_<MyType, BaseType1, BaseType2, BaseType3>(m, "MyType")
|
|
...
|
|
|
|
The base types can be specified in arbitrary order, and they can even be
|
|
interspersed with alias types and holder types (discussed earlier in this
|
|
document)---pybind11 will automatically find out which is which. The only
|
|
requirement is that the first template argument is the type to be declared.
|
|
|
|
There are two caveats regarding the implementation of this feature:
|
|
|
|
1. When only one base type is specified for a C++ type that actually has
|
|
multiple bases, pybind11 will assume that it does not participate in
|
|
multiple inheritance, which can lead to undefined behavior. In such cases,
|
|
add the tag ``multiple_inheritance``:
|
|
|
|
.. code-block:: cpp
|
|
|
|
py::class_<MyType, BaseType2>(m, "MyType", py::multiple_inheritance());
|
|
|
|
The tag is redundant and does not need to be specified when multiple base
|
|
types are listed.
|
|
|
|
2. As was previously discussed in the section on :ref:`overriding_virtuals`, it
|
|
is easy to create Python types that derive from C++ classes. It is even
|
|
possible to make use of multiple inheritance to declare a Python class which
|
|
has e.g. a C++ and a Python class as bases. However, any attempt to create a
|
|
type that has *two or more* C++ classes in its hierarchy of base types will
|
|
fail with a fatal error message: ``TypeError: multiple bases have instance
|
|
lay-out conflict``. Core Python types that are implemented in C (e.g.
|
|
``dict``, ``list``, ``Exception``, etc.) also fall under this combination
|
|
and cannot be combined with C++ types bound using pybind11 via multiple
|
|
inheritance.
|