Specifying Types#
Including Snippets#
There might be repetitive XML code, for example function modifications that need to be done on classes that are not related by type inheritance. It is possible to split out such snippets and include them via an entity reference.
<typesystem>
<object-type name="A">
&common_function_modifications;
</object-type>
<object-type name="B">
&common_function_modifications;
</object-type>
</typesystem>
The entity name is interpreted as file name (with suffix xml) appended and resolved in the type system paths passed as command line argument.
Note that this is not a standard externally parsed entity due to the limitations of the underlying parser.
typesystem#
This is the root node containing all the type system information. It may contain add-function, container-type, custom-type, enum-type, extra-includes, function, load-typesystem, namespace-type, object-type, opaque-container, primitive-type, rejection, smart-pointer-type, suppress-warning, template, system-include, typedef-type or value-type child nodes.
It can have a number of attributes, described below.
<typesystem package="..." default-superclass="..." allow-thread="..."
exception-handling="..." snake-case="yes | no | both" >
</typesystem>
The package attribute is a string describing the package to be used, e.g. “QtCore”. The optional default-superclass attribute is the canonical C++ base class name of all objects, e.g., “object”.
The optional attributes allow-thread and exception-handling specify the default handling for the corresponding function modification (see modify-function).
The optional snake-case attribute specifies whether function
and field names will be automatically changed to the snake case
style that is common in Python (for example, snakeCase
will be
changed to snake_case
).
The value both
means that the function or field will be exposed
under both its original name and the snake case version. There are
limitations to this though:
When overriding a virtual function of a C++ class in Python, the snake case name must be used.
When static and non-static overloads of a class member function exist (as is the case for example for
QFileInfo::exists()
), the snake case name must be used.
load-typesystem#
The load-typesystem
node specifies which type systems to load when mapping
multiple libraries to another language or basing one library on another, and
it is a child of the typesystem node.
<typesystem>
<load-typesystem name="..." generate="yes | no" />
</typesystem>
The name attribute is the filename of the typesystem to load, the generate attribute specifies whether code should be generated or not. The later must be specified when basing one library on another, making the generator able to understand inheritance hierarchies, primitive mapping, parameter types in functions, etc.
Most libraries will be based on both the QtCore and QtGui modules, in which case code generation for these libraries will be disabled.
rejection#
The rejection
node rejects the given class, or the specified function
or field, and it is a child of the typesystem node.
<typesystem>
<rejection class="..."
function-name="..."
argument-type="..."
field-name="..." />
</typesystem>
The class attribute is the C++ class name of the class to reject. Use the optional function-name, argument-type, or field-name attributes to reject a particular function, function with arguments of a particular type, or a field. Note that the field-name and function-name/argument-type cannot be specified at the same time. To remove all occurrences of a given field or function, set the class attribute to *.
primitive-type#
The primitive-type
node describes how a primitive type is mapped from C++ to
the target language, and is a child of the typesystem node. It may
contain conversion-rule child nodes. Note that most primitives are
already specified in the QtCore typesystem (see Primitive C++ Types).
<typesystem>
<primitive-type name="..."
since="..."
until="..."
target-lang-api-name="..."
default-constructor="..."
preferred-conversion="yes | no" />
view-on="..."
</typesystem>
The name attribute is the name of the primitive in C++.
The optional target-lang-api-name attribute is the name of the primitive type in the target language, defaulting to the name attribute.
The optional since value is used to specify the API version in which the type was introduced.
Similarly, the optional until value can be used to specify the API version in which the type will be obsoleted.
If the optional preferred-conversion attribute is set to no, it indicates that this version of the primitive type is not the preferred C++ equivalent of the target language type. For example, in Python both “qint64” and “long long” become “long” but we should prefer the “qint64” version. For this reason we mark “long long” with preferred-conversion=”no”.
The optional default-constructor specifies the minimal constructor call to build one value of the primitive-type. This is not needed when the primitive-type may be built with a default constructor (the one without arguments).
The optional preferred-conversion attribute tells how to build a default instance of the primitive type. It should be a constructor call capable of creating a instance of the primitive type. Example: a class “Foo” could have a preferred-conversion value set to “Foo()”. Usually this attribute is used only for classes declared as primitive types and not for primitive C++ types, but that depends on the application using ApiExtractor.
The optional view-on attribute specifies that the type is a view class like std::string_view or QStringView which has a constructor accepting another type like std::string or QString. Since typically no values can be assigned to view classes, no target-to-native conversion can be generated for them. Instead, an instance of the viewed class should be instantiated and passed to functions using the view class for argument types.
See Predefined Templates for built-in templates for standard type conversion rules.
namespace-type#
The namespace-type
node maps the given C++ namespace to the target
language, and it is a child of the typesystem node or other
namespace-type
nodes. It may contain add-function,
declare-function, enum-type, extra-includes,
include, modify-function, namespace-type
,
object-type, smart-pointer-type, typedef-type or value-type
child nodes.
<typesystem>
<namespace-type name="..."
visible="true | auto | false"
generate="yes | no"
generate-using="yes | no"
package="..."
since="..."
extends = "..."
files = "..."
revision="..." />
</typesystem>
The name attribute is the name of the namespace, e.g., “Qt”.
The optional visible attribute is used specify whether the namespace is visible in the target language name. Its default value is auto. It means that normal namespaces are visible, but inline namespaces (as introduced in C++ 11) will not be visible.
The detection of inline namespaces requires shiboken to be built using LLVM 9.0.
The optional generate is a legacy attribute. Specifying no is equivalent to visible=”false”.
The optional generate-using attribute specifies whether
using namespace
is generated into the wrapper code for classes within
the namespace (default: yes). This ensures for example that not fully
qualified enumeration values of default argument values compile.
However, in rare cases, it might cause ambiguities and can then be turned
off.
The package attribute can be used to override the package of the type system.
The optional since value is used to specify the API version of this type.
The revision attribute can be used to specify a revision for each type, easing the production of ABI compatible bindings.
The optional extends attribute specifies the module name where the given
namespace first occurs in case of a namespace spanning several modules. For
example, in Qt, the namespace Qt
first occurs in the QtCore
module and
is further populated in the QtGui
module. QtGui.Qt
will then be
generated extending QtCore.Qt
if extends is specified.
The optional file attribute specifies a regular expression matching the include files whose contents are to be associated with the current module in case of a namespace spanning several modules.
enum-type#
The enum-type
node maps the given enum from C++ to the target language,
and it is a child of the typesystem node. Use
reject-enum-value child nodes to reject values.
<typesystem>
<enum-type name="..."
identified-by-value="..."
class="yes | no"
since="..."
flags="yes | no"
flags-revision="..."
cpp-type = "..."
python-type = "IntEnum | IntFlag"
lower-bound="..."
upper-bound="..."
force-integer="yes | no"
extensible="yes | no"
revision="..." />
</typesystem>
The name attribute is the fully qualified C++ name of the enum (e.g.,”Qt::FillRule”). If the optional flags attribute is set to yes (the default is no), the generator will expect an existing QFlags<T> for the given enum type. The lower-bound and upper-bound attributes are used to specify runtime bounds checking for the enum value. The value must be a compilable target language statement, such as “QGradient.Spread.PadSpread” (taking again Python as an example). If the force-integer attribute is set to yes (the default is no), the generated target language code will use the target language integers instead of enums. And finally, the extensible attribute specifies whether the given enum can be extended with user values (the default is no).
The optional since value is used to specify the API version of this type.
The attribute identified-by-value helps to specify anonymous enums using the name of one of their values, which is unique for the anonymous enum scope. Notice that the enum-type tag can either have name or identified-by-value but not both.
The optional python-type attribute specifies the underlying Python type.
The optional cpp-type attribute specifies a C++ to be used for casting values. This can be useful for large values triggering MSVC signedness issues.
The revision attribute can be used to specify a revision for each type, easing the production of ABI compatible bindings.
The flags-revision attribute has the same purposes of revision attribute but is used for the QFlag related to this enum.
reject-enum-value#
The reject-enum-value
node rejects the enum value specified by the
name attribute, and it is a child of the enum-type node.
<enum-type>
<reject-enum-value name="..."/>
</enum-type>
This node is used when a C++ enum implementation has several identical numeric values, some of which are typically obsolete.
value-type#
The value-type
node indicates that the given C++ type is mapped onto the target
language as a value type. This means that it is an object passed by value on C++,
i.e. it is stored in the function call stack. It is a child of the typesystem
node or other type nodes and may contain add-function, add-pymethoddef,
configuration, declare-function, conversion-rule,
enum-type, extra-includes, include, modify-function,
object-type, smart-pointer-type, typedef-type or further
value-type
child nodes.
<typesystem>
<value-type name="..." since="..."
copyable="yes | no"
allow-thread="..."
disable-wrapper="yes | no"
exception-handling="..."
generate-functions="..."
isNull ="yes | no"
operator-bool="yes | no"
hash-function="..."
private="yes | no"
qt-register-metatype = "yes | no | base"
stream="yes | no"
default-constructor="..."
revision="..."
snake-case="yes | no | both" />
</typesystem>
The name attribute is the fully qualified C++ class name, such as “QMatrix” or “QPainterPath::Element”. The copyable attribute is used to force or not specify if this type is copyable. The optional hash-function attribute informs the function name of a hash function for the type.
The optional attribute stream specifies whether this type will be able to use externally defined operators, like QDataStream << and >>. If equals to yes, these operators will be called as normal methods within the current class.
The optional since value is used to specify the API version of this type.
The optional default-constructor specifies the minimal constructor call to build one instance of the value-type. This is not needed when the value-type may be built with a default constructor (the one without arguments). Usually a code generator may guess a minimal constructor for a value-type based on its constructor signatures, thus default-constructor is used only in very odd cases.
For the optional disable-wrapper and generate-functions attributes, see object-type.
For the optional private attribute, see Defining Entities.
The optional qt-register-metatype attribute determines whether
a Qt meta type registration is generated for name
. By
default, this is generated for non-abstract, default-constructible
types for usage in signals and slots.
The value base
means that the registration will be generated for the
class in question but not for inheriting classes. This allows for
restricting the registration to base classes of type hierarchies.
The revision attribute can be used to specify a revision for each type, easing the production of ABI compatible bindings.
The optional attributes allow-thread and exception-handling specify the default handling for the corresponding function modification (see modify-function).
The optional snake-case attribute allows for overriding the value specified on the typesystem element.
The optional isNull and operator-bool attributes can be used to override the command line setting for generating bool casts (see Bool Cast).
object-type#
The object-type node indicates that the given C++ type is mapped onto the target
language as an object type. This means that it is an object passed by pointer on
C++ and it is stored on the heap. It is a child of the typesystem node
or other type nodes and may contain add-function, add-pymethoddef,
configuration, declare-function, enum-type,
extra-includes, include, modify-function,
object-type
, smart-pointer-type, typedef-type or
value-type child nodes.
<typesystem>
<object-type name="..."
since="..."
copyable="yes | no"
allow-thread="..."
disable-wrapper="yes | no"
exception-handling="..."
generate-functions="..."
force-abstract="yes | no"
hash-function="..."
isNull ="yes | no"
operator-bool="yes | no"
parent-management="yes | no"
polymorphic-id-expression="..."
polymorphic-name-function="..."
private="yes | no"
qt-register-metatype = "yes | no | base"
stream="yes | no"
revision="..."
snake-case="yes | no | both" />
</typesystem>
The name attribute is the fully qualified C++ class name. If there is no C++ base class, the default-superclass attribute can be used to specify a superclass for the given type, in the generated target language API. The copyable and hash-function attributes are the same as described for value-type.
The optional force-abstract attribute forces the class to be abstract, disabling its instantiation. The generator will normally detect this automatically unless the class inherits from an abstract base class that is not in the type system.
The optional disable-wrapper attribute disables the generation of a C++ Wrapper (see Code Generation Terminology). This will effectively disable overriding virtuals methods in Python for the class. It can be used when the class cannot be instantiated from Python and its virtual methods pose some problem for the code generator (by returning references, or using a default value that cannot be generated for a parameter, or similar).
For the optional private attribute, see Defining Entities.
The optional qt-register-metatype attribute determines whether
a Qt meta type registration is generated for name *
. By
default, this is only generated for non-QObject types for usage
in signals and slots.
The value base
means that the registration will be generated for the
class in question but not for inheriting classes. This allows for
restricting the registration to base classes of type hierarchies.
The optional attribute stream specifies whether this type will be able to use externally defined operators, like QDataStream << and >>. If equals to yes, these operators will be called as normal methods within the current class.
The optional since value is used to specify the API version of this type.
The revision attribute can be used to specify a revision for each type, easing the production of ABI compatible bindings.
The optional attributes allow-thread and exception-handling specify the default handling for the corresponding function modification (see modify-function).
The optional generate-functions specifies a semicolon-separated list of function names or minimal signatures to be generated. This allows for restricting the functions for which bindings are generated. This also applies to virtual functions; so, all abstract functions need to be listed to prevent non-compiling code to be generated. If nothing is specified, bindings for all suitable functions are generated. Note that special functions (constructors, etc), cannot be specified.
The optional snake-case attribute allows for overriding the value specified on the typesystem element.
The optional isNull and operator-bool attributes can be used to override the command line setting for generating bool casts (see Bool Cast).
The optional parent-management attribute specifies that the class is
used for building object trees consisting of parents and children, for
example, user interfaces like the QWidget
classes. For those classes,
the heuristics enabled by Parentship heuristics and
Return value heuristics are applied to automatically set parent
relationships. Compatibility note: In shiboken 6, when no class of the
type system has this attribute set, the heuristics will be applied
to all classes. In shiboken 7, it will be mandatory to set the
attribute.
The optional polymorphic-id-expression attribute specifies an
expression checking whether a base class pointer is of the matching
type. For example, in a virtual eventHandler(BaseEvent *e)
function, this is used to construct a Python wrapper matching
the derived class (for example, a MouseEvent
or similar).
The optional polymorphic-name-function specifies the name of a
function returning the type name of a derived class on the base class
type entry. Normally, typeid(ptr).name()
is used for this.
However, this fails if the type hierarchy does not have virtual functions.
In this case, a function is required which typically decides depending
on some type enumeration.
interface-type#
This type is deprecated and no longer has any effect. Use object-type instead.
container-type#
The container-type
node indicates that the given class is a container and
must be handled using one of the conversion helpers provided by attribute type.
It is a child of the typesystem node and may contain
conversion-rule child nodes.
<typesystem>
<container-type name="..."
since="..."
type ="..."
opaque-containers ="..." />
</typesystem>
The name attribute is the fully qualified C++ class name. The type attribute is used to indicate what conversion rule will be applied to the container. It can be one of: list, set, map, multi-map or pair.
Some types were deprecated in 6.2: string-list, linked-list, vector, stack and queue are equivalent to list. hash and multi-hash are equivalent to map and multi-map, respectively.
The optional opaque-containers attribute specifies a semi-colon separated list of mappings from instantiations to a type name for Opaque Containers:
<typesystem>
<container-type name="std::array"
opaque-containers ="int,3:IntArray3;float,4:FloatArray4">
The optional since value is used to specify the API version of this container.
Some common standard containers are built-in, and there are also a number of useful predefined conversion templates.
opaque-container#
The opaque-container
element can be used to add further instantiations
of opaque containers to existing container types
(built-in or specified by container-type in included modules).
It is a child of the typesystem node.
<typesystem>
<oqaque-container name="..." opaque-containers ="..." />
</typesystem>
For the name and opaque-containers attributes, see container-type.
typedef-type#
The typedef-type
node allows for specifying typedefs in the typesystem. They
are mostly equivalent to spelling out the typedef in the included header, which
is often complicated when trying to wrap libraries whose source code cannot be
easily extended.
It is a child of the typesystem node or other type nodes.
<typesystem>
<typedef-type name="..."
source="..."
since="..." />
</typesystem>
The source attribute is the source. Example:
<namespace-type name='std'>
<value-type name='optional' generate='no'/>\n"
</namespace-type>
<typedef-type name="IntOptional" source="std::optional<int>"/>
is equivalent to
typedef std::optional<int> IntOptional;
The optional since value is used to specify the API version of this type.
custom-type#
The custom-type
node simply makes the parser aware of the existence of a target
language type, thus avoiding errors when trying to find a type used in function
signatures and other places. The proper handling of the custom type is meant to
be done by a generator using the APIExractor.
It is a child of the typesystem node.
<typesystem>
<custom-type name="..."
check-function="..." />
</typesystem>
The name attribute is the name of the custom type, e.g., “PyObject”.
The optional check-function attribute can be used to specify a
boolean check function that verifies if the PyObject is of the given type
in the function overload decisor. While shiboken knows common check
functions like PyLong_Check()
or PyType_Check()
, it might be useful
to provide one for function arguments modified to be custom types
handled by injected code (see replace-type).
See CPython Types for built-in types.
smart-pointer-type#
The smart pointer
type node indicates that the given class is a smart pointer
and requires inserting calls to getter to access the pointeee.
Currently, the usage is limited to function return values.
ref-count-method specifies the name of the method used to do reference counting.
It is a child of the typesystem node or other type nodes.
The optional attribute instantiations specifies for which instantiations of the smart pointer wrappers will be generated (comma-separated list). By default, this will happen for all instantiations found by code parsing. This might be a problem when linking different modules, since wrappers for the same instantiation might be generated into different modules, which then clash. Providing an instantiations list makes it possible to specify which wrappers will be generated into specific modules.
<typesystem>
<smart-pointer-type name="..."
since="..."
type="shared | handle | value-handle | unique"
getter="..."
ref-count-method="..."
value-check-method="..."
null-check-method="..."
reset-method="..."
instantiations="..."/>
</typesystem>
The optional attribute value-check-method specifies a method that can be used to check whether the pointer has a value.
The optional attribute null-check-method specifies a method
that can be used to check for nullptr
.
The optional attribute reset-method specifies a method that can be used to clear the pointer.
The optional instantiations attribute specifies a comma-separated
list of instantiation types. When left empty, all instantiations
found in the code will be generated. The type name might optionally
be followed an equal sign and the Python type name, for example
instantiations="int=IntPtr,double=DoublePtr"
.
It is also possible to specify a namespace delimited by ::
.
The optional attribute type specifies the type:
- shared
A standard shared pointer.
- handle
A basic pointer handle which has a getter function and an
operator->
.- value-handle
A handle which has a getter function returning a value (
T
instead ofT *
as for the other types). It can be used forstd::optional
.- unique
A standard, unique pointer (
std::unique_ptr
) or a similar movable pointer. Specifying thereset-method
attribute is required for this work.
The example below shows an entry for a std::shared_ptr
:
<system-include file-name="memory"/>
<namespace-type name="std">
<include file-name="memory" location="global"/>
<modify-function signature="^.*$" remove="all"/>
<enum-type name="pointer_safety"/>
<smart-pointer-type name="shared_ptr" type="shared" getter="get"
ref-count-method="use_count"
instantiations="Integer">
<include file-name="memory" location="global"/>
</smart-pointer-type>
</namespace-type>
If the smart pointer is the only relevant class from namespace std
,
it can also be hidden:
<namespace-type name="std" visible="no">
<smart-pointer-type name="shared_ptr" type="shared" getter="get"
ref-count-method="use_count"
instantiations="Integer">
<include file-name="memory" location="global"/>
</smart-pointer-type>
</namespace-type>
First, shiboken is told to actually parse the system include files
containing the class definition using the system-include
element. For the namespace-type
and smart-pointer-type
, the
standard include files are given to override the internal implementation
header shared_ptr.h
.
This creates some wrapper sources which need to be added to the
CMakeLists.txt
of the module.
function#
The function
node indicates that the given C++ global function is mapped
onto the target language. It is a child of the typesystem node
and may contain a modify-function child node.
<typesystem>
<function signature="..." rename="..." since="..."
allow-thread="true | auto | false"
exception-handling="off | auto-off | auto-on | on"
overload-number="number"
snake-case="yes | no | both" />
</typesystem>
There is a limitation; you cannot add a function overload using the add-function tag to an existent function.
The optional since attribute is used to specify the API version in which the function was introduced.
The optional rename attribute is used to modify the function name.
For the optional attributes allow-thread, exception-handling, overload-number and snake-case, see modify-function.
system-include#
The optional system-include specifies the name of a system include file or a system include path (indicated by a trailing slash) to be parsed. Normally, include files considered to be system include files are skipped by the C++ code parser. Its primary use case is exposing classes from the STL library. It is a child of the typesystem node.
<typesystem>
<system-include file-name="memory"/>
<system-include file-name="/usr/include/Qt/"/>
</typesystem>
Conditional Processing#
Simple processing instructions are provided for including or excluding sections depending on the presence of keywords. The syntax is:
<?if keyword !excluded_keyword ?>
...
<?endif?>
There are predefined keywords indicating the operating system (windows
,
unix
and darwin
).
The language level passed to the language-level
command line option
is reflected as c++11
, c++14
, c++17
or c++20
.
The class names passed to the
–drop-type-entries command line option
are also predefined, prefixed by no_
. This allows for example
for enclosing added functions referring to those classes within
<?if !no_ClassName?>
, <?endif?>
.
Other keywords can be specified using the –keywords command line option.
Defining Entities#
It is possible to define entities using a simple processing instruction:
<?entity name value?>
<text>&name;</text>
This allows for defining function signatures depending on platform in conjunction with Conditional Processing.
Private Types#
Marking object-type or value-type entries as private causes a separate, private module header besides the public module header to be generated for them.
This can be used for classes that are not referenced in dependent modules and helps to prevent the propagation of for example private C++ headers required for them.