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PySide Shiboken Code Injection Semantics
API Extractor provides the inject-code tag allowing the user to put custom written code to on specific locations of the generated code. Yet this is only part of what is needed to generate proper binding code, where the custom code should be written to depends upon the technology used on the generated binding code.
This is the inject-code tag options that matters to Shiboken.
<inject-code class="native | target" position="beginning | end">
// custom code
</inject-code>
Conventions
C++ Wrapper
This term refers to a generated C++ class that extends a class from the wrapped library. It is used only when a wrapped C++ class is polymorphic, i.e. it has or inherits any virtual methods.
Python Wrapper
The code that exports the C++ wrapped class to Python. Python wrapper refers to all the code needed to export a C++ class to Python, and Python method/function wrapper means the specific function that calls the C++ method/function on behalf of Python.
Native
This is a possible value for the class attribute of the inject-code tag, it means things more akin to the C++ side.
Target
Another class attribute value, it indicates things more close to the Python side.
inject-code tag
The following table describes the semantics of inject-code tag as used on Shiboken.
Parent Tag | Class | Position | Meaning |
---|---|---|---|
value-type, object-type | native | beginning | Write to the beginning of a class wrapper .cpp file, right after the #include clauses. A common use would be to write prototypes for custom functions whose definitions are put on a native/end code injection. |
| | end | Write to the end of a class wrapper .cpp file. Could be used to write custom/helper functions definitions for prototypes declared on native/beginning. |
| target | beginning | Meaning. |
| | end | Meaning. |
modify-function | native | beginning | Code here is put on the virtual method override of a C++ wrapper class (the one responsible for passing C++ calls to a Python override, if there is any), right after the C++ arguments have been converted but before the Python call. |
| | end | This code injection is put in a virtual method override on the C++ wrapper class, after the call to Python and before dereferencing the Python method and tuple of arguments. |
| target | beginning | This code is injected on the Python method wrapper (PyCLASS_METHOD(…)), right after the decisor have found which signature to call and also after the conversion of the arguments to be used, but before the actual call. |
| | end | This code is injected on the Python method wrapper (PyCLASS_METHOD(…)), right after the C++ method call, but still inside the scope created by the overload for each signature. |
| shell | beginning | Used only for virtual functions. The code is injected when the function does not has a pyhton implementation, then the code is inserted before c++ call. |
| | end | Same as above, but the code is inserted after c++ call. |
typesystem | native | beginning | Write code to the beginning of the module .cpp file, right after the #include clauses. This position has a similar purpose as the native/beginning position on a wrapper class .cpp file, namely write function prototypes, but not restricted to this use. |
| | end | Write code to the end of the module .cpp file. Usually implementations for function prototypes inserted at the beginning of the file with a native/beginning code injection. |
| target | beginning | Insert code at the start of the module initialization function (initMODULENAME()), before the calling Py_InitModule. |
| | end | Insert code at the end of the module initialization function (initMODULENAME()), but before the checking that emits a fatal error in case of problems importing the module. |
Anatomy of Code Injection
To make things clear let’s use a simplified example of generated wrapper code and the places where each kind of code injection goes.
Below is the example C++ class for whom wrapper code will be generated.
class InjectCode {
public:
InjectCode();
double overloadedMethod(int arg);
double overloadedMethod(double arg);
virtual int virtualMethod(int arg);
};
From the C++ class, Shiboken will generate a injectcode_wrapper.cpp file with the binding code. The next section will use a simplified version of the generated wrapper code with the injection spots marked with comments.
Noteworthy Cases
The type system description system gives the binding developer a lot of flexibility, which is power, which comes with responsibility. Some modifications to the wrapped API will not be complete without some code injection.
Removing arguments and setting a default values for them
A simple case is when a function have one argument removed, as when the C++ method METHOD (ARG) is modified to be used from Python as METHOD(); of course the binding developer must provide some guidelines to the generator on what to do to call it. The most common solution is to remove the argument and set a default value for it at the same time, so the original C++ method could be called without problems.
Removing arguments and calling the method with your own hands
If the argument is removed and no default value is provided, the generator will not write any call to the method and expect the modify-function - target/beginning code injection to call the original C++ method on its own terms. If even this custom code is not provided the generator will put an #error clause to prevent compilation of erroneus binding code.
Calling the method with your own hands always!
If your custom code to be injected contains a call to the wrapped C++ method, it surely means that you don’t want the generator to write another call to the same method. As expected Shiboken will detect the user written call on the code injection and will not write its own call, but for this to work properly the binding developer must use the template variable %FUNCTION_NAME instead of writing the actual name of the wrapped method/function.
In other words, use
<inject-code class="target" position="beginning | end">
%CPPSELF.originalMethodName();
</inject-code>
instead of
<inject-code class="target" position="beginning | end">
%CPPSELF.%FUNCTION_NAME();
</inject-code>
Code Injection for Functions/Methods
On The Native Side
Notice that this is only used when there is a C++ wrapper, i.e. the wrapped class is polymorphic.
int InjectCodeWrapper::virtualMethod(int arg)
{
PyObject* method = BindingManager::instance().getOverride(this, "virtualMethod");
if (!py_override)
return this->InjectCode::virtualMethod(arg);
(… here C++ arguments are converted to Python …)
// INJECT-CODE: <modify-function><inject-code class="native" position="beginning">
// Uses: pre method call custom code, modify the argument before the
// Python call.
(… Python method call goes in here …)
// INJECT-CODE: <modify-function><inject-code class="native" position="end">
// Uses: post method call custom code, modify the result before delivering
// it to C++ caller.
(… Python method and argument tuple are dereferenced here …)
return Shiboken::Converter<int>::toCpp(method_result);
}
On The Target Side
All the overloads of a method from C++ are gathered together on a single Python method that uses an overload decisor to call the correct C++ method based on the arguments passed by the Python call. Each overloaded method signature has its own beginning and end code injections.
static PyObject*
PyInjectCode_overloadedMethod(PyObject* self, PyObject* arg)
{
PyObject* py_result = 0;
if (PyFloat_Check(arg)) {
double cpp_arg0 = Shiboken::Converter<double >::toCpp(arg);
// INJECT-CODE: <modify-function><inject-code class="target" position="beginning">
// Uses: pre method call custom code.
py_result = Shiboken::Converter<double >::toPython(
PyInjectCode_cptr(self)->InjectCode::overloadedMethod(cpp_arg0)
);
// INJECT-CODE: <modify-function><inject-code class="target" position="end">
// Uses: post method call custom code.
} else if (PyNumber_Check(arg)) {
(… other overload calling code …)
} else goto PyInjectCode_overloadedMethod_TypeError;
if (PyErr_Occurred() || !py_result)
return 0;
return py_result;
PyInjectCode_overloadedMethod_TypeError:
PyErr_SetString(PyExc_TypeError, "'overloadedMethod()' called with wrong parameters.");
return 0;
}
Code Injection for Wrapped Classes
On The Native Side
Those injections go in the body of the CLASSNAME_wrapper.cpp file for the wrapped class.
// Start of ``CLASSNAME_wrapper.cpp``
#define protected public
// default includes
#include <shiboken.h>
(…)
#include "injectcode_wrapper.h"
using namespace Shiboken;
// INJECT-CODE: <value/object-type><inject-code class="native" position="beginning">
// Uses: prototype declarations
(… C++ wrapper virtual methods, if any …)
(… Python wrapper code …)
PyAPI_FUNC(void)
init_injectcode(PyObject *module)
{
(…)
}
(…)
// INJECT-CODE: <value/object-type><inject-code class="native" position="end">
// Uses: definition of functions prototyped at ``native/beginning``.
// End of ``CLASSNAME_wrapper.cpp``
On The Target Side
Code injections to the class Python initialization function.
// Start of ``CLASSNAME_wrapper.cpp``
(…)
PyAPI_FUNC(void)
init_injectcode(PyObject '''module)
{
// INJECT-CODE: <value/object-type><inject-code class="target" position="beginning">
// Uses: Alter something in the PyInjectCode_Type (tp_flags value for example)
// before registering it.
if (PyType_Ready(&PyInjectCode_Type) < 0)
return;
Py_INCREF(&PyInjectCode_Type);
PyModule_AddObject(module, "InjectCode",
((PyObject''')&PyInjectCode_Type));
// INJECT-CODE: <value/object-type><inject-code class="target" position="end">
// Uses: do something right after the class is registered, like set some static
// variable injected on this same file elsewhere.
}
(…)
// End of ``CLASSNAME_wrapper.cpp``
Code Injection for Modules
The C++ libraries are wapped as Python modules, a collection of classes, functions, enums and namespaces. Shiboken creates wrapper files for all of them and also one extra MODULENAME_module_wrapper.cpp to register the whole module. Code injection xml tags who have the typesystem tag as parent will be put on this file.
On The Native Side
This works exactly as the class wrapper code injections On The Native Side.
On The Target Side
This is very similar to class wrapper code injections On The Target Side. Notice that the inject code at target/end is inserted before the check for errors to prevent bad custom code to pass unnoticed.
// Start of ``MODULENAME_module_wrapper.cpp``
(…)
initMODULENAME()
{
// INJECT-CODE: <typesystem><inject-code class="target" position="beginning">
// Uses: do something before the module is created.
PyObject* module = Py_InitModule("MODULENAME", MODULENAME_methods);
(… initialization of wrapped classes, namespaces, functions and enums …)
// INJECT-CODE: <typesystem><inject-code class="target" position="end">
// Uses: do something after the module is registered and initialized.
if (PyErr_Occurred())
Py_FatalError("can't initialize module sample");
}
(…)
// Start of ``MODULENAME_module_wrapper.cpp``