Annotations =========== In this section we describe each of the annotations that can be used in specification files. Annotations can either be :ref:`argument annotations `, :ref:`class annotations `, :ref:`mapped type annotations `, :ref:`enum annotations `, :ref:`exception annotations `, :ref:`function annotations `, :ref:`license annotations `, :ref:`typedef annotations ` or :ref:`variable annotations ` depending on the context in which they can be used. Annotations are placed between forward slashes (``/``). Multiple annotations are comma separated within the slashes. Annotations have a type and, possibly, a value. The type determines the format of the value. The name of an annotation and its value are separated by ``=``. Annotations can have one of the following types: *boolean* This type of annotation has no value and is implicitly true. *name* The value is a name that is compatible with a C/C++ identifier. In some cases the value is optional. *dotted name* The value is a name that is compatible with an identifier preceded by a Python scope. *string* The value is a double quoted string. *API range* The value is the name of an API (defined using the :directive:`%API` directive) separated by a range of version numbers with a colon. The range of version numbers is a pair of numbers separated by a hyphen specifying the lower and upper bounds of the range. A version number is within the range if it is greater or equal to the lower bound and less than the upper bound. Each bound can be omitted meaning that the range is unbounded in that direction. For example:: # This is part of the PyQt4 API up to but excluding v2. void hex() /API=PyQt4:-2/ # This is part of the PyQt4 API starting from v2. void hex() /PyName=hex_, API=PyQt4:2-/ The following example shows argument and function annotations:: void exec(QWidget * /Transfer/) /ReleaseGIL, PyName=call_exec/; Note that the current version of SIP does not complain about unknown annotations, or annotations used out of their correct context. .. _ref-arg-annos: Argument Annotations -------------------- .. argument-annotation:: AllowNone This boolean annotation specifies that the value of the corresponding argument (which should be either :stype:`SIP_PYCALLABLE`, :stype:`SIP_PYDICT`, :stype:`SIP_PYLIST`, :stype:`SIP_PYSLICE`, :stype:`SIP_PYTUPLE` or :stype:`SIP_PYTYPE`) may be ``None``. .. argument-annotation:: Array This boolean annotation specifies that the corresponding argument refers to an array. The argument should be either a pointer to a wrapped type, a ``char *`` or a ``unsigned char *``. If the argument is a character array then the annotation also implies the :aanno:`Encoding` annotation with an encoding of ``"None"``. There must be a corresponding argument with the :aanno:`ArraySize` annotation specified. The annotation may only be specified once in a list of arguments. .. argument-annotation:: ArraySize This boolean annotation specifies that the corresponding argument (which should be either ``short``, ``unsigned short``, ``int``, ``unsigned``, ``long`` or ``unsigned long``) refers to the size of an array. There must be a corresponding argument with the :aanno:`Array` annotation specified. The annotation may only be specified once in a list of arguments. .. argument-annotation:: Constrained Python will automatically convert between certain compatible types. For example, if a floating pointer number is expected and an integer supplied, then the integer will be converted appropriately. This can cause problems when wrapping C or C++ functions with similar signatures. For example:: // The wrapper for this function will also accept an integer argument // which Python will automatically convert to a floating point number. void foo(double); // The wrapper for this function will never get used. void foo(int); This boolean annotation specifies that the corresponding argument (which should be either ``bool``, ``int``, ``float``, ``double``, ``enum`` or a wrapped class) must match the type without any automatic conversions. In the context of a wrapped class the invocation of any :directive:`%ConvertToTypeCode` is suppressed. The following example gets around the above problem:: // The wrapper for this function will only accept floating point // numbers. void foo(double /Constrained/); // The wrapper for this function will be used for anything that Python // can convert to an integer, except for floating point numbers. void foo(int); .. argument-annotation:: DocType .. versionadded:: 4.10 This string annotation specifies the type of the argument as it will appear in any generated docstrings. It is usually used with arguments of type :stype:`SIP_PYOBJECT` to provide a more specific type. .. argument-annotation:: DocValue .. versionadded:: 4.10 This string annotation specifies the default value of the argument as it will appear in any generated docstrings. .. argument-annotation:: Encoding This string annotation specifies that the corresponding argument (which should be either ``char``, ``const char``, ``char *`` or ``const char *``) refers to an encoded character or ``'\0'`` terminated encoded string with the specified encoding. The encoding can be either ``"ASCII"``, ``"Latin-1"``, ``"UTF-8"`` or ``"None"``. An encoding of ``"None"`` means that the corresponding argument refers to an unencoded character or string. The default encoding is specified by the :directive:`%DefaultEncoding` directive. If the directive is not specified then ``None`` is used. Python v3 will use the ``bytes`` type to represent the argument if the encoding is ``"None"`` and the ``str`` type otherwise. Python v2 will use the ``str`` type to represent the argument if the encoding is ``"None"`` and the ``tqunicode`` type otherwise. .. argument-annotation:: GetWrapper This boolean annotation is only ever used in conjunction with handwritten code specified with the :directive:`%MethodCode` directive. It causes an extra variable to be generated for the corresponding argument which is a pointer to the Python object that wraps the argument. See the :directive:`%MethodCode` directive for more detail. .. argument-annotation:: In This boolean annotation is used to specify that the corresponding argument (which should be a pointer type) is used to pass a value to the function. For pointers to wrapped C structures or C++ class instances, ``char *`` and ``unsigned char *`` then this annotation is assumed unless the :aanno:`Out` annotation is specified. For pointers to other types then this annotation must be explicitly specified if required. The argument will be dereferenced to obtain the actual value. Both :aanno:`In` and :aanno:`Out` may be specified for the same argument. .. argument-annotation:: KeepReference This boolean annotation is used to specify that a reference to the corresponding argument should be kept to ensure that the object is not garbage collected. If the method is called again with a new argument then the reference to the previous argument is discarded. Note that ownership of the argument is not changed. .. argument-annotation:: NoCopy .. versionadded:: 4.10.1 This boolean annotation is used with arguments of virtual methods that are a ``const`` reference to a class. Normally, if the class defines a copy constructor then a copy of the returned reference is automatically created and wrapped before being passed to a Python reimplementation of the method. The copy will be owned by Python. This means that the reimplementation may take a reference to the argument without having to make an explicit copy. If the annotation is specified then the copy is not made and the original reference is wrapped instead and will be owned by C++. .. argument-annotation:: Out This boolean annotation is used to specify that the corresponding argument (which should be a pointer type) is used by the function to return a value as an element of a tuple. For pointers to wrapped C structures or C++ class instances, ``char *`` and ``unsigned char *`` then this annotation must be explicitly specified if required. For pointers to other types then this annotation is assumed unless the :aanno:`In` annotation is specified. Both :aanno:`In` and :aanno:`Out` may be specified for the same argument. .. argument-annotation:: ResultSize This boolean annotation is used with functions or methods that return a ``void *`` or ``const void *``. It identifies an argument that defines the size of the block of memory whose address is being returned. This allows the ``sip.voidptr`` object that wraps the address to support the Python buffer protocol and allows the memory to be read and updated when wrapped by the Python ``buffer()`` builtin. .. argument-annotation:: SingleShot This boolean annotation is used only with arguments of type :stype:`SIP_RXOBJ_CON` to specify that the signal connected to the slot will only ever be emitted once. This prevents a certain class of memory leaks. .. argument-annotation:: Transfer This boolean annotation is used to specify that ownership of the corresponding argument (which should be a wrapped C structure or C++ class instance) is transferred from Python to C++. In addition, if the argument is of a class method, then it is associated with the class instance with regard to the cyclic garbage collector. See :ref:`ref-object-ownership` for more detail. .. argument-annotation:: TransferBack This boolean annotation is used to specify that ownership of the corresponding argument (which should be a wrapped C structure or C++ class instance) is transferred back to Python from C++. In addition, any association of the argument with regard to the cyclic garbage collector with another instance is removed. See :ref:`ref-object-ownership` for more detail. .. argument-annotation:: TransferThis This boolean annotation is only used in C++ constructors or methods. In the context of a constructor or factory method it specifies that ownership of the instance being created is transferred from Python to C++ if the corresponding argument (which should be a wrapped C structure or C++ class instance) is not ``None``. In addition, the newly created instance is associated with the argument with regard to the cyclic garbage collector. In the context of a non-factory method it specifies that ownership of ``this`` is transferred from Python to C++ if the corresponding argument is not ``None``. If it is ``None`` then ownership is transferred to Python. The annotation may be used more that once, in which case ownership is transferred to last instance that is not ``None``. See :ref:`ref-object-ownership` for more detail. .. _ref-class-annos: Class Annotations ----------------- .. class-annotation:: Abstract This boolean annotation is used to specify that the class has additional pure virtual methods that have not been specified and so it cannot be instantiated or sub-classed from Python. .. class-annotation:: AllowNone .. versionadded:: 4.8.2 Normally when a Python object is converted to a C/C++ instance ``None`` is handled automatically before the class's :directive:`%ConvertToTypeCode` is called. This boolean annotation specifies that the handling of ``None`` will be left to the :directive:`%ConvertToTypeCode`. The annotation is ignored if the class does not have any :directive:`%ConvertToTypeCode`. .. class-annotation:: API .. versionadded:: 4.9 This API range annotation is used to specify an API and corresponding range of version numbers that the class is enabled for. If a class or mapped type has different implementations enabled for different ranges of version numbers then those ranges must not overlap. See :ref:`ref-incompat-apis` for more detail. .. class-annotation:: DelayDtor This boolean annotation is used to specify that the class's destructor should not be called until the Python interpreter exits. It would normally only be applied to singleton classes. When the Python interpreter exits the order in which any wrapped instances are garbage collected is unpredictable. However, the underlying C or C++ instances may need to be destroyed in a certain order. If this annotation is specified then when the wrapped instance is garbage collected the C or C++ instance is not destroyed but instead added to a list of delayed instances. When the interpreter exits then the function :cfunc:`sipDelayedDtors()` is called with the list of delayed instances. :cfunc:`sipDelayedDtors()` can then choose to call (or ignore) the destructors in any desired order. The :cfunc:`sipDelayedDtors()` function must be specified using the :directive:`%ModuleCode` directive. .. cfunction:: void sipDelayedDtors(const sipDelayedDtor *dd_list) :param dd_list: the linked list of delayed instances. .. ctype:: sipDelayedDtor This structure describes a particular delayed destructor. .. cmember:: const char *dd_name This is the name of the class excluding any package or module name. .. cmember:: void *dd_ptr This is the address of the C or C++ instance to be destroyed. It's exact type depends on the value of :cmember:`dd_isderived`. .. cmember:: int dd_isderived This is non-zero if the type of :cmember:`dd_ptr` is actually the generated derived class. This allows the correct destructor to be called. See :ref:`ref-derived-classes`. .. cmember:: sipDelayedDtor *dd_next This is the address of the next entry in the list or zero if this is the last one. Note that the above applies only to C and C++ instances that are owned by Python. .. class-annotation:: Deprecated This boolean annotation is used to specify that the class is deprecated. It is the equivalent of annotating all the class's constructors, function and methods as being deprecated. .. class-annotation:: External This boolean annotation is used to specify that the class is defined in another module. Declarations of external classes are private to the module in which they appear. .. class-annotation:: Metatype This dotted name annotation specifies the name of the Python type object (i.e. the value of the ``tp_name`` field) used as the meta-type used when creating the type object for this C structure or C++ type. See the section :ref:`ref-types-metatypes` for more details. .. class-annotation:: NoDefaultCtors This boolean annotation is used to suppress the automatic generation of default constructors for the class. .. class-annotation:: PyName This name annotation specifies an alternative name for the class being wrapped which is used when it is referred to from Python. It is required when a class name is the same as a Python keyword. It may also be used to avoid name clashes with other objects (e.g. enums, exceptions, functions) that have the same name in the same C++ scope. .. class-annotation:: Supertype This dotted name annotation specifies the name of the Python type object (i.e. the value of the ``tp_name`` field) used as the super-type used when creating the type object for this C structure or C++ type. See the section :ref:`ref-types-metatypes` for more details. .. _ref-mapped-type-annos: Mapped Type Annotations ----------------------- .. mapped-type-annotation:: AllowNone Normally when a Python object is converted to a C/C++ instance ``None`` is handled automatically before the mapped type's :directive:`%ConvertToTypeCode` is called. This boolean annotation specifies that the handling of ``None`` will be left to the :directive:`%ConvertToTypeCode`. .. mapped-type-annotation:: API .. versionadded:: 4.9 This API range annotation is used to specify an API and corresponding range of version numbers that the mapped type is enabled for. If a class or mapped type has different implementations enabled for different ranges of version numbers then those ranges must not overlap. See :ref:`ref-incompat-apis` for more detail. .. mapped-type-annotation:: DocType .. versionadded:: 4.10 This string annotation specifies the name of the type as it will appear in any generated docstrings. .. mapped-type-annotation:: NoRelease This boolean annotation is used to specify that the mapped type does not support the :cfunc:`sipReleaseType()` function. Any :directive:`%ConvertToTypeCode` should not create temporary instances of the mapped type, i.e. it should not return :cmacro:`SIP_TEMPORARY`. .. _ref-enum-annos: Enum Annotations ---------------- .. enum-annotation:: PyName This name annotation specifies an alternative name for the enum or enum member being wrapped which is used when it is referred to from Python. It is required when an enum or enum member name is the same as a Python keyword. It may also be used to avoid name clashes with other objects (e.g. classes, exceptions, functions) that have the same name in the same C++ scope. .. _ref-exception-annos: Exception Annotations --------------------- .. exception-annotation:: Default This boolean annotation specifies that the exception being defined will be used as the default exception to be caught if a function or constructor does not have a ``throw`` clause. .. exception-annotation:: PyName This name annotation specifies an alternative name for the exception being defined which is used when it is referred to from Python. It is required when an exception name is the same as a Python keyword. It may also be used to avoid name clashes with other objects (e.g. classes, enums, functions) that have the same name. .. _ref-function-annos: Function Annotations -------------------- .. function-annotation:: API .. versionadded:: 4.9 This API range annotation is used to specify an API and corresponding range of version numbers that the function is enabled for. See :ref:`ref-incompat-apis` for more detail. .. function-annotation:: AutoGen This optional name annotation is used with class methods to specify that the method be automatically included in all sub-classes. The value is the name of a feature (specified using the :directive:`%Feature` directive) which must be enabled for the method to be generated. .. function-annotation:: Default This boolean annotation is only used with C++ constructors. Sometimes SIP needs to create a class instance. By default it uses a constructor with no compulsory arguments if one is specified. (SIP will automatically generate a constructor with no arguments if no constructors are specified.) This annotation is used to explicitly specify which constructor to use. Zero is passed as the value of any arguments to the constructor. .. function-annotation:: Deprecated This boolean annotation is used to specify that the constructor or function is deprecated. A deprecation warning is issued whenever the constructor or function is called. .. function-annotation:: DocType .. versionadded:: 4.10 This string annotation specifies the name of the type of the returned value as it will appear in any generated docstrings. It is usually used with values of type :stype:`SIP_PYOBJECT` to provide a more specific type. .. function-annotation:: Factory This boolean annotation specifies that the value returned by the function (which should be a wrapped C structure or C++ class instance) is a newly created instance and is owned by Python. See :ref:`ref-object-ownership` for more detail. .. function-annotation:: HoldGIL This boolean annotation specifies that the Python Global Interpreter Lock (GIL) is not released before the call to the underlying C or C++ function. See :ref:`ref-gil` and the :fanno:`ReleaseGIL` annotation. .. function-annotation:: KeywordArgs .. versionadded:: 4.10 This boolean annotation specifies that the argument parser generated for this function will support passing the parameters using Python's keyword argument syntax. Keyword arguments cannot be used for functions that have unnamed arguments or use an ellipsis to designate that the function has a variable number of arguments. .. function-annotation:: __len__ .. versionadded:: 4.10.3 This boolean annotation specifies that a ``__len__()`` method should be automatically generated that will use the method being annotated to compute the value that the ``__len__()`` method will return. .. function-annotation:: NewThread This boolean annotation specifies that the function will create a new thread. .. function-annotation:: NoArgParser This boolean annotation is used with methods and global functions to specify that the supplied :directive:`%MethodCode` will handle the parsing of the arguments. .. function-annotation:: NoCopy .. versionadded:: 4.10.1 This boolean annotation is used with methods and global functions that return a ``const`` reference to a class. Normally, if the class defines a copy constructor then a copy of the returned reference is automatically created and wrapped. The copy will be owned by Python. If the annotation is specified then the copy is not made and the original reference is wrapped instead and will be owned by C++. .. function-annotation:: NoDerived This boolean annotation is only used with C++ constructors. In many cases SIP generates a derived class for each class being wrapped (see :ref:`ref-derived-classes`). This derived class contains constructors with the same C++ signatures as the class being wrapped. Sometimes you may want to define a Python constructor that has no corresponding C++ constructor. This annotation is used to suppress the generation of the constructor in the derived class. .. function-annotation:: NoKeywordArgs .. versionadded:: 4.10 This boolean annotation specifies that the argument parser generated for this function will not support passing the parameters using Python's keyword argument syntax. In other words, the argument parser will only support only normal positional arguments. This annotation is useful when the default setting of allowing keyword arguments has been changed via the command line, but you would still like certain functions to only support positional arguments. .. function-annotation:: Numeric This boolean annotation specifies that the operator should be interpreted as a numeric operator rather than a sequence operator. Python uses the ``+`` operator for adding numbers and concatanating sequences, and the ``*`` operator for multiplying numbers and repeating sequences. SIP tries to work out which is meant by looking at other operators that have been defined for the type. If it finds either ``-``, ``-=``, ``/``, ``/=``, ``%`` or ``%=`` defined then it assumes that ``+``, ``+=``, ``*`` and ``*=`` should be numeric operators. Otherwise, if it finds either ``[]``, :meth:`__getitem__`, :meth:`__setitem__` or :meth:`__delitem__` defined then it assumes that they should be sequence operators. This annotation is used to force SIP to treat the operator as numeric. .. function-annotation:: PostHook This name annotation is used to specify the name of a Python builtin that is called immediately after the call to the underlying C or C++ function or any handwritten code. The builtin is not called if an error occurred. It is primarily used to integrate with debuggers. .. function-annotation:: PreHook This name annotation is used to specify the name of a Python builtin that is called immediately after the function's arguments have been successfully parsed and before the call to the underlying C or C++ function or any handwritten code. It is primarily used to integrate with debuggers. .. function-annotation:: PyName This name annotation specifies an alternative name for the function being wrapped which is used when it is referred to from Python. It is required when a function or method name is the same as a Python keyword. It may also be used to avoid name clashes with other objects (e.g. classes, enums, exceptions) that have the same name in the same C++ scope. .. function-annotation:: ReleaseGIL This boolean annotation specifies that the Python Global Interpreter Lock (GIL) is released before the call to the underlying C or C++ function and reacquired afterwards. It should be used for functions that might block or take a significant amount of time to execute. See :ref:`ref-gil` and the :fanno:`HoldGIL` annotation. .. function-annotation:: Transfer This boolean annotation specifies that ownership of the value returned by the function (which should be a wrapped C structure or C++ class instance) is transferred to C++. It is only used in the context of a class constructor or a method. In the case of methods returned values (unless they are new references to already wrapped values) are normally owned by C++ anyway. However, in addition, an association between the returned value and the instance containing the method is created with regard to the cyclic garbage collector. See :ref:`ref-object-ownership` for more detail. .. function-annotation:: TransferBack This boolean annotation specifies that ownership of the value returned by the function (which should be a wrapped C structure or C++ class instance) is transferred back to Python from C++. Normally returned values (unless they are new references to already wrapped values) are owned by C++. In addition, any association of the returned value with regard to the cyclic garbage collector with another instance is removed. See :ref:`ref-object-ownership` for more detail. .. function-annotation:: TransferThis This boolean annotation specifies that ownership of ``this`` is transferred from Python to C++. See :ref:`ref-object-ownership` for more detail. .. _ref-license-annos: License Annotations ------------------- .. license-annotation:: Licensee This optional string annotation specifies the license's licensee. No restrictions are placed on the contents of the string. See the :directive:`%License` directive. .. license-annotation:: Signature This optional string annotation specifies the license's signature. No restrictions are placed on the contents of the string. See the :directive:`%License` directive. .. license-annotation:: Timestamp This optional string annotation specifies the license's timestamp. No restrictions are placed on the contents of the string. See the :directive:`%License` directive. .. license-annotation:: Type This string annotation specifies the license's type. No restrictions are placed on the contents of the string. See the :directive:`%License` directive. .. _ref-typedef-annos: Typedef Annotations ------------------- .. typedef-annotation:: NoTypeName This boolean annotation specifies that the definition of the type rather than the name of the type being defined should be used in the generated code. Normally a typedef would be defined as follows:: typedef bool MyBool; This would result in ``MyBool`` being used in the generated code. Specifying the annotation means that ``bool`` will be used in the generated code instead. .. _ref-variable-annos: Variable Annotations -------------------- .. variable-annotation:: DocType .. versionadded:: 4.10 This string annotation specifies the name of the type of the variable as it will appear in any generated docstrings. It is usually used with variables of type :stype:`SIP_PYOBJECT` to provide a more specific type. .. variable-annotation:: PyName This name annotation specifies an alternative name for the variable being wrapped which is used when it is referred to from Python. It is required when a variable name is the same as a Python keyword. It may also be used to avoid name clashes with other objects (e.g. classes, functions) that have the same name in the same C++ scope.