.. highlight:: cython .. _wrapping-cplusplus: ******************************** Using C++ in Cython ******************************** Overview ========= Cython has native support for most of the C++ language. Specifically: * C++ objects can be dynamically allocated with ``new`` and ``del`` keywords. * C++ objects can be stack-allocated. * C++ classes can be declared with the new keyword ``cppclass``. * Templated classes and functions are supported. * Overloaded functions are supported. * Overloading of C++ operators (such as operator+, operator[],...) is supported. Procedure Overview ------------------- The general procedure for wrapping a C++ file can now be described as follows: * Specify C++ language in a :file:`setup.py` script or locally in a source file. * Create one or more ``.pxd`` files with ``cdef extern from`` blocks and (if existing) the C++ namespace name. In these blocks: * declare classes as ``cdef cppclass`` blocks * declare public names (variables, methods and constructors) * ``cimport`` them in one or more extension modules (``.pyx`` files). A simple Tutorial ================== An example C++ API ------------------- Here is a tiny C++ API which we will use as an example throughout this document. Let's assume it will be in a header file called :file:`Rectangle.h`: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/Rectangle.h :language: c++ :tab-width: 4 and the implementation in the file called :file:`Rectangle.cpp`: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/Rectangle.cpp :language: c++ :tab-width: 4 This is pretty dumb, but should suffice to demonstrate the steps involved. Declaring a C++ class interface -------------------------------- The procedure for wrapping a C++ class is quite similar to that for wrapping normal C structs, with a couple of additions. Let's start here by creating the basic ``cdef extern from`` block:: cdef extern from "Rectangle.h" namespace "shapes": This will make the C++ class def for Rectangle available. Note the namespace declaration. Namespaces are simply used to make the fully qualified name of the object, and can be nested (e.g. ``"outer::inner"``) or even refer to classes (e.g. ``"namespace::MyClass`` to declare static members on MyClass). Declare class with cdef cppclass ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Now, let's add the Rectangle class to this extern from block - just copy the class name from Rectangle.h and adjust for Cython syntax, so now it becomes:: cdef extern from "Rectangle.h" namespace "shapes": cdef cppclass Rectangle: Add public attributes ^^^^^^^^^^^^^^^^^^^^^^ We now need to declare the attributes and methods for use on Cython. We put those declarations in a file called :file:`Rectangle.pxd`. You can see it as a header file which is readable by Cython: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/Rectangle.pxd Note that the constructor is declared as "except +". If the C++ code or the initial memory allocation raises an exception due to a failure, this will let Cython safely raise an appropriate Python exception instead (see below). Without this declaration, C++ exceptions originating from the constructor will not be handled by Cython. We use the lines:: cdef extern from "Rectangle.cpp": pass to include the C++ code from :file:`Rectangle.cpp`. It is also possible to specify to distutils that :file:`Rectangle.cpp` is a source. To do that, you can add this directive at the top of the ``.pyx`` (not ``.pxd``) file:: # distutils: sources = Rectangle.cpp Note that when you use ``cdef extern from``, the path that you specify is relative to the current file, but if you use the distutils directive, the path is relative to the :file:`setup.py`. If you want to discover the path of the sources when running the :file:`setup.py`, you can use the ``aliases`` argument of the :func:`cythonize` function. Declare a var with the wrapped C++ class ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ We'll create a ``.pyx`` file named ``rect.pyx`` to build our wrapper. We're using a name other than ``Rectangle``, but if you prefer giving the same name to the wrapper as the C++ class, see the section on :ref:`resolving naming conflicts `. Within, we use cdef to declare a var of the class with the C++ ``new`` statement: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/cython_usage.pyx The line:: # distutils: language = c++ is to indicate to Cython that this ``.pyx`` file has to be compiled to C++. It's also possible to declare a stack allocated object, as long as it has a "default" constructor:: cdef extern from "Foo.h": cdef cppclass Foo: Foo() def func(): cdef Foo foo ... Note that, like C++, if the class has only one constructor and it is a nullary one, it's not necessary to declare it. Create Cython wrapper class ---------------------------- At this point, we have exposed into our pyx file's namespace the interface of the C++ Rectangle type. Now, we need to make this accessible from external Python code (which is our whole point). Common programming practice is to create a Cython extension type which holds a C++ instance as an attribute and create a bunch of forwarding methods. So we can implement the Python extension type as: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/rect.pyx And there we have it. From a Python perspective, this extension type will look and feel just like a natively defined Rectangle class. It should be noted that if you want to give attribute access, you could just implement some properties: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/rect_with_attributes.pyx Cython initializes C++ class attributes of a cdef class using the nullary constructor. If the class you're wrapping does not have a nullary constructor, you must store a pointer to the wrapped class and manually allocate and deallocate it. A convenient and safe place to do so is in the `__cinit__` and `__dealloc__` methods which are guaranteed to be called exactly once upon creation and deletion of the Python instance. .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/rect_ptr.pyx Compilation and Importing ========================= To compile a Cython module, it is necessary to have a :file:`setup.py` file: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/setup.py Run ``$ python setup.py build_ext --inplace`` To test it, open the Python interpreter:: >>> import rect >>> x0, y0, x1, y1 = 1, 2, 3, 4 >>> rect_obj = rect.PyRectangle(x0, y0, x1, y1) >>> print(dir(rect_obj)) ['__class__', '__delattr__', '__dir__', '__doc__', '__eq__', '__format__', '__ge__', '__getattribute__', '__gt__', '__hash__', '__init__', '__init_subclass__', '__le__', '__lt__', '__ne__', '__new__', '__reduce__', '__reduce_ex__', '__repr__', '__setattr__', '__setstate__', '__sizeof__', '__str__', '__subclasshook__', 'get_area', 'get_size', 'move'] Advanced C++ features ====================== We describe here all the C++ features that were not discussed in the above tutorial. Overloading ------------ Overloading is very simple. Just declare the method with different parameters and use any of them:: cdef extern from "Foo.h": cdef cppclass Foo: Foo(int) Foo(bool) Foo(int, bool) Foo(int, int) Overloading operators ---------------------- Cython uses C++ naming for overloading operators:: cdef extern from "foo.h": cdef cppclass Foo: Foo() Foo operator+(Foo) Foo operator-(Foo) int operator*(Foo) int operator/(int) int operator*(int, Foo) # allows 1*Foo() # nonmember operators can also be specified outside the class double operator/(double, Foo) cdef Foo foo = new Foo() foo2 = foo + foo foo2 = foo - foo x = foo * foo2 x = foo / 1 x = foo[0] * foo2 x = foo[0] / 1 x = 1*foo[0] cdef double y y = 2.0/foo[0] Note that if one has *pointers* to C++ objects, dereferencing must be done to avoid doing pointer arithmetic rather than arithmetic on the objects themselves:: cdef Foo* foo_ptr = new Foo() foo = foo_ptr[0] + foo_ptr[0] x = foo_ptr[0] / 2 del foo_ptr Nested class declarations -------------------------- C++ allows nested class declaration. Class declarations can also be nested in Cython: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/nested_class.pyx Note that the nested class is declared with a ``cppclass`` but without a ``cdef``, as it is already part of a ``cdef`` declaration section. C++ operators not compatible with Python syntax ------------------------------------------------ Cython tries to keep its syntax as close as possible to standard Python. Because of this, certain C++ operators, like the preincrement ``++foo`` or the dereferencing operator ``*foo`` cannot be used with the same syntax as C++. Cython provides functions replacing these operators in a special module ``cython.operator``. The functions provided are: * ``cython.operator.dereference`` for dereferencing. ``dereference(foo)`` will produce the C++ code ``*(foo)`` * ``cython.operator.preincrement`` for pre-incrementation. ``preincrement(foo)`` will produce the C++ code ``++(foo)``. Similarly for ``predecrement``, ``postincrement`` and ``postdecrement``. * ``cython.operator.comma`` for the comma operator. ``comma(a, b)`` will produce the C++ code ``((a), (b))``. These functions need to be cimported. Of course, one can use a ``from ... cimport ... as`` to have shorter and more readable functions. For example: ``from cython.operator cimport dereference as deref``. For completeness, it's also worth mentioning ``cython.operator.address`` which can also be written ``&foo``. Templates ---------- Cython uses a bracket syntax for templating. A simple example for wrapping C++ vector: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/templates.pyx Multiple template parameters can be defined as a list, such as ``[T, U, V]`` or ``[int, bool, char]``. Optional template parameters can be indicated by writing ``[T, U, V=*]``. In the event that Cython needs to explicitly reference the type of a default template parameter for an incomplete template instantiation, it will write ``MyClass::V``, so if the class provides a typedef for its template parameters it is preferable to use that name here. Template functions are defined similarly to class templates, with the template parameter list following the function name: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/function_templates.pyx Standard library ----------------- Most of the containers of the C++ Standard Library have been declared in pxd files located in `/Cython/Includes/libcpp `_. These containers are: deque, list, map, pair, queue, set, stack, vector. For example: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/vector_demo.pyx The pxd files in `/Cython/Includes/libcpp `_ also work as good examples on how to declare C++ classes. The STL containers coerce from and to the corresponding Python builtin types. The conversion is triggered either by an assignment to a typed variable (including typed function arguments) or by an explicit cast, e.g.: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/python_to_cpp.pyx The following coercions are available: +------------------+----------------+-----------------+ | Python type => | *C++ type* | => Python type | +==================+================+=================+ | bytes | std::string | bytes | +------------------+----------------+-----------------+ | iterable | std::vector | list | +------------------+----------------+-----------------+ | iterable | std::list | list | +------------------+----------------+-----------------+ | iterable | std::set | set | +------------------+----------------+-----------------+ | iterable (len 2) | std::pair | tuple (len 2) | +------------------+----------------+-----------------+ All conversions create a new container and copy the data into it. The items in the containers are converted to a corresponding type automatically, which includes recursively converting containers inside of containers, e.g. a C++ vector of maps of strings. Iteration over stl containers (or indeed any class with ``begin()`` and ``end()`` methods returning an object supporting incrementing, dereferencing, and comparison) is supported via the ``for .. in`` syntax (including in list comprehensions). For example, one can write: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/iterate.pyx If the loop target variable is unspecified, an assignment from type ``*container.begin()`` is used for :ref:`type inference `. .. note:: Slicing stl containers is supported, you can do ``for x in my_vector[:5]: ...`` but unlike pointers slices, it will create a temporary Python object and iterate over it. Thus making the iteration very slow. You might want to avoid slicing C++ containers for performance reasons. Simplified wrapping with default constructor -------------------------------------------- If your extension type instantiates a wrapped C++ class using the default constructor (not passing any arguments), you may be able to simplify the lifecycle handling by tying it directly to the lifetime of the Python wrapper object. Instead of a pointer attribute, you can declare an instance: .. literalinclude:: ../../examples/userguide/wrapping_CPlusPlus/wrapper_vector.pyx Cython will automatically generate code that instantiates the C++ object instance when the Python object is created and deletes it when the Python object is garbage collected. Exceptions ----------- Cython cannot throw C++ exceptions, or catch them with a try-except statement, but it is possible to declare a function as potentially raising an C++ exception and converting it into a Python exception. For example, :: cdef extern from "some_file.h": cdef int foo() except + This will translate try and the C++ error into an appropriate Python exception. The translation is performed according to the following table (the ``std::`` prefix is omitted from the C++ identifiers): +-----------------------+---------------------+ | C++ | Python | +=======================+=====================+ | ``bad_alloc`` | ``MemoryError`` | +-----------------------+---------------------+ | ``bad_cast`` | ``TypeError`` | +-----------------------+---------------------+ | ``bad_typeid`` | ``TypeError`` | +-----------------------+---------------------+ | ``domain_error`` | ``ValueError`` | +-----------------------+---------------------+ | ``invalid_argument`` | ``ValueError`` | +-----------------------+---------------------+ | ``ios_base::failure`` | ``IOError`` | +-----------------------+---------------------+ | ``out_of_range`` | ``IndexError`` | +-----------------------+---------------------+ | ``overflow_error`` | ``OverflowError`` | +-----------------------+---------------------+ | ``range_error`` | ``ArithmeticError`` | +-----------------------+---------------------+ | ``underflow_error`` | ``ArithmeticError`` | +-----------------------+---------------------+ | (all others) | ``RuntimeError`` | +-----------------------+---------------------+ The ``what()`` message, if any, is preserved. Note that a C++ ``ios_base_failure`` can denote EOF, but does not carry enough information for Cython to discern that, so watch out with exception masks on IO streams. :: cdef int bar() except +MemoryError This will catch any C++ error and raise a Python MemoryError in its place. (Any Python exception is valid here.) :: cdef int raise_py_error() cdef int something_dangerous() except +raise_py_error If something_dangerous raises a C++ exception then raise_py_error will be called, which allows one to do custom C++ to Python error "translations." If raise_py_error does not actually raise an exception a RuntimeError will be raised. There is also the special form:: cdef int raise_py_or_cpp() except +* for those functions that may raise either a Python or a C++ exception. Static member method -------------------- If the Rectangle class has a static member: .. sourcecode:: c++ namespace shapes { class Rectangle { ... public: static void do_something(); }; } you can declare it using the Python @staticmethod decorator, i.e.:: cdef extern from "Rectangle.h" namespace "shapes": cdef cppclass Rectangle: ... @staticmethod void do_something() Declaring/Using References --------------------------- Cython supports declaring lvalue references using the standard ``Type&`` syntax. Note, however, that it is unnecessary to declare the arguments of extern functions as references (const or otherwise) as it has no impact on the caller's syntax. ``auto`` Keyword ---------------- Though Cython does not have an ``auto`` keyword, Cython local variables not explicitly typed with ``cdef`` are deduced from the types of the right hand side of *all* their assignments (see the ``infer_types`` :ref:`compiler directive `). This is particularly handy when dealing with functions that return complicated, nested, templated types, e.g.:: cdef vector[int] v = ... it = v.begin() (Though of course the ``for .. in`` syntax is preferred for objects supporting the iteration protocol.) RTTI and typeid() ================= Cython has support for the ``typeid(...)`` operator. from cython.operator cimport typeid The ``typeid(...)`` operator returns an object of the type ``const type_info &``. If you want to store a type_info value in a C variable, you will need to store it as a pointer rather than a reference:: from libcpp.typeinfo cimport type_info cdef const type_info* info = &typeid(MyClass) If an invalid type is passed to ``typeid``, it will throw an ``std::bad_typeid`` exception which is converted into a ``TypeError`` exception in Python. An additional C++11-only RTTI-related class, ``std::type_index``, is available in ``libcpp.typeindex``. Specify C++ language in setup.py ================================ Instead of specifying the language and the sources in the source files, it is possible to declare them in the :file:`setup.py` file:: from distutils.core import setup from Cython.Build import cythonize setup(ext_modules = cythonize( "rect.pyx", # our Cython source sources=["Rectangle.cpp"], # additional source file(s) language="c++", # generate C++ code )) Cython will generate and compile the :file:`rect.cpp` file (from :file:`rect.pyx`), then it will compile :file:`Rectangle.cpp` (implementation of the ``Rectangle`` class) and link both object files together into :file:`rect.so` on Linux, or :file:`rect.pyd` on windows, which you can then import in Python using ``import rect`` (if you forget to link the :file:`Rectangle.o`, you will get missing symbols while importing the library in Python). Note that the ``language`` option has no effect on user provided Extension objects that are passed into ``cythonize()``. It is only used for modules found by file name (as in the example above). The ``cythonize()`` function in Cython versions up to 0.21 does not recognize the ``language`` option and it needs to be specified as an option to an :class:`Extension` that describes your extension and that is then handled by ``cythonize()`` as follows:: from distutils.core import setup, Extension from Cython.Build import cythonize setup(ext_modules = cythonize(Extension( "rect", # the extension name sources=["rect.pyx", "Rectangle.cpp"], # the Cython source and # additional C++ source files language="c++", # generate and compile C++ code ))) The options can also be passed directly from the source file, which is often preferable (and overrides any global option). Starting with version 0.17, Cython also allows passing external source files into the ``cythonize()`` command this way. Here is a simplified setup.py file:: from distutils.core import setup from Cython.Build import cythonize setup( name = "rectangleapp", ext_modules = cythonize('*.pyx'), ) And in the .pyx source file, write this into the first comment block, before any source code, to compile it in C++ mode and link it statically against the :file:`Rectangle.cpp` code file:: # distutils: language = c++ # distutils: sources = Rectangle.cpp .. note:: When using distutils directives, the paths are relative to the working directory of the distutils run (which is usually the project root where the :file:`setup.py` resides). To compile manually (e.g. using ``make``), the ``cython`` command-line utility can be used to generate a C++ ``.cpp`` file, and then compile it into a python extension. C++ mode for the ``cython`` command is turned on with the ``--cplus`` option. Caveats and Limitations ======================== Access to C-only functions --------------------------- Whenever generating C++ code, Cython generates declarations of and calls to functions assuming these functions are C++ (ie, not declared as ``extern "C" {...}``. This is ok if the C functions have C++ entry points, but if they're C only, you will hit a roadblock. If you have a C++ Cython module needing to make calls to pure-C functions, you will need to write a small C++ shim module which: * includes the needed C headers in an extern "C" block * contains minimal forwarding functions in C++, each of which calls the respective pure-C function C++ left-values ---------------- C++ allows functions returning a reference to be left-values. This is currently not supported in Cython. ``cython.operator.dereference(foo)`` is also not considered a left-value.