static PyObject *
meth_get__doc__(PythonQtSlotFunctionObject * m, void * /*closure*/)
{
QByteArray doc;
PythonQtSlotInfo* info = m->m_ml;
const QByteArray& returnType = info->parameters().at(0).name;
int returnTypeId = info->parameters().at(0).typeId;
PythonQtSlotInfo* longestInfo = info;
PythonQtSlotInfo* infoSearch = info->nextInfo();
while (infoSearch) {
if (longestInfo->parameterCount() < infoSearch->parameterCount()) {
longestInfo = infoSearch;
}
infoSearch = infoSearch->nextInfo();
}
doc = "X." + info->slotName(true) + "(";
for (int i = 1;i<longestInfo->parameterCount(); i++) {
if (i!=1) {
doc += ", ";
}
doc += QString('a' + i-1);
}
doc += ")";
QByteArray pyReturnType;
if (returnType == "QString" || returnType == "SbName" || returnType == "SbString") {
pyReturnType = "str";
} else if (returnType.startsWith("QVector<") || returnType.startsWith("QList<") ||
returnType == "QStringList" || returnType == "QObjectList" || returnType == "QVariantList") {
pyReturnType = "tuple";
} else if (returnType.startsWith("QHash<") || returnType.startsWith("QMap<") ||
returnType == "QVariantMap" || returnType == "QVariantHash") {
pyReturnType = "dict";
} else if (returnTypeId == QVariant::Bool) {
pyReturnType = "bool";
} else if (returnTypeId == PythonQtMethodInfo::Variant) {
pyReturnType = "object";
} else if (returnTypeId == QMetaType::Char || returnTypeId == QMetaType::UChar ||
returnTypeId == QMetaType::Short || returnTypeId == QMetaType::UShort ||
returnTypeId == QMetaType::Int || returnTypeId == QMetaType::UInt ||
returnTypeId == QMetaType::Long || returnTypeId == QMetaType::ULong ||
returnTypeId == QMetaType::LongLong || returnTypeId == QMetaType::ULongLong) {
pyReturnType = "int";
} else if (returnTypeId == QMetaType::Float || returnTypeId == QMetaType::Double) {
pyReturnType = "float";
} else {
PythonQtClassInfo* returnTypeClassInfo = PythonQt::priv()->getClassInfo(returnType);
if (returnTypeClassInfo) {
PyObject* s = PyObject_GetAttrString(returnTypeClassInfo->pythonQtClassWrapper(), "__module__");
if (s) {
pyReturnType = QByteArray(PyString_AsString(s)) + "." + returnType;
Py_DECREF(s);
}
}
}
if (!pyReturnType.isEmpty()) {
doc += " -> " + pyReturnType;
}
return PyString_FromString(doc.constData());
}
bool PythonQtCallSlot(PythonQtClassInfo* classInfo, QObject* objectToCall, PyObject* args, bool strict, PythonQtSlotInfo* info, void* firstArgument, PyObject** pythonReturnValue, void** directReturnValuePointer)
{
static unsigned int recursiveEntry = 0;
if (directReturnValuePointer) {
*directReturnValuePointer = NULL;
}
// store the current storage position, so that we can get back to this state after a slot is called
// (do this locally, so that we have all positions on the stack
PythonQtValueStoragePosition globalValueStoragePos;
PythonQtValueStoragePosition globalPtrStoragePos;
PythonQtValueStoragePosition globalVariantStoragePos;
PythonQtConv::global_valueStorage.getPos(globalValueStoragePos);
PythonQtConv::global_ptrStorage.getPos(globalPtrStoragePos);
PythonQtConv::global_variantStorage.getPos(globalVariantStoragePos);
recursiveEntry++;
// the arguments that are passed to qt_metacall
void* argList[PYTHONQT_MAX_ARGS];
PyObject* result = NULL;
int argc = info->parameterCount();
const QList<PythonQtSlotInfo::ParameterInfo>& params = info->parameters();
const PythonQtSlotInfo::ParameterInfo& returnValueParam = params.at(0);
// set return argument to NULL
argList[0] = NULL;
bool ok = true;
bool skipFirst = false;
if (info->isInstanceDecorator()) {
skipFirst = true;
// for decorators on CPP objects, we take the cpp ptr, for QObjects we take the QObject pointer
void* arg1 = firstArgument;
if (!arg1) {
arg1 = objectToCall;
}
if (arg1) {
// upcast to correct parent class
arg1 = ((char*)arg1)+info->upcastingOffset();
}
argList[1] = &arg1;
if (ok) {
for (int i = 2; i<argc && ok; i++) {
const PythonQtSlotInfo::ParameterInfo& param = params.at(i);
argList[i] = PythonQtConv::ConvertPythonToQt(param, PyTuple_GET_ITEM(args, i-2), strict, classInfo);
if (argList[i]==NULL) {
ok = false;
break;
}
}
}
} else {
for (int i = 1; i<argc && ok; i++) {
const PythonQtSlotInfo::ParameterInfo& param = params.at(i);
argList[i] = PythonQtConv::ConvertPythonToQt(param, PyTuple_GET_ITEM(args, i-1), strict, classInfo);
if (argList[i]==NULL) {
ok = false;
break;
}
}
}
if (ok) {
// parameters are ok, now create the qt return value which is assigned to by metacall
if (returnValueParam.typeId != QMetaType::Void) {
// create empty default value for the return value
if (!directReturnValuePointer) {
// create empty default value for the return value
argList[0] = PythonQtConv::CreateQtReturnValue(returnValueParam);
if (argList[0]==NULL) {
// return value could not be created, maybe we have a registered class with a default constructor, so that we can construct the pythonqt wrapper object and
// pass its internal pointer
PythonQtClassInfo* info = PythonQt::priv()->getClassInfo(returnValueParam.name);
if (info && info->pythonQtClassWrapper()) {
PyObject* emptyTuple = PyTuple_New(0);
// 1) default construct an empty object as python object (owned by PythonQt), by calling the meta class with empty arguments
result = PyObject_Call((PyObject*)info->pythonQtClassWrapper(), emptyTuple, NULL);
if (result) {
argList[0] = ((PythonQtInstanceWrapper*)result)->_wrappedPtr;
}
Py_DECREF(emptyTuple);
}
}
} else {
// we can use our pointer directly!
argList[0] = directReturnValuePointer;
}
}
PythonQt::ProfilingCB* profilingCB = PythonQt::priv()->profilingCB();
if (profilingCB) {
const char* className = NULL;
if (info->decorator()) {
className = info->decorator()->metaObject()->className();
} else {
className = objectToCall->metaObject()->className();
}
profilingCB(PythonQt::Enter, className, info->metaMethod()->signature());
}
// invoke the slot via metacall
bool hadException = false;
QObject* obj = info->decorator()?info->decorator():objectToCall;
if (!obj) {
hadException = true;
PyErr_SetString(PyExc_RuntimeError, "Trying to call a slot on a deleted QObject!");
} else {
try {
obj->qt_metacall(QMetaObject::InvokeMetaMethod, info->slotIndex(), argList);
} catch (std::bad_alloc & e) {
hadException = true;
QByteArray what("std::bad_alloc: ");
what += e.what();
PyErr_SetString(PyExc_MemoryError, what.constData());
} catch (std::runtime_error & e) {
hadException = true;
QByteArray what("std::runtime_error: ");
what += e.what();
PyErr_SetString(PyExc_RuntimeError, what.constData());
} catch (std::logic_error & e) {
hadException = true;
QByteArray what("std::logic_error: ");
what += e.what();
PyErr_SetString(PyExc_RuntimeError, what.constData());
} catch (std::exception& e) {
hadException = true;
QByteArray what("std::exception: ");
what += e.what();
PyErr_SetString(PyExc_StandardError, what.constData());
}
}
if (profilingCB) {
profilingCB(PythonQt::Leave, NULL, NULL);
}
// handle the return value (which in most cases still needs to be converted to a Python object)
if (!hadException) {
if (argList[0] || returnValueParam.typeId == QMetaType::Void) {
if (directReturnValuePointer) {
result = NULL;
} else {
// the resulting object maybe present already, because we created it above at 1)...
if (!result) {
result = PythonQtConv::ConvertQtValueToPython(returnValueParam, argList[0]);
}
}
} else {
QString e = QString("Called ") + info->fullSignature() + ", return type '" + returnValueParam.name + "' is ignored because it is unknown to PythonQt. Probably you should register it using qRegisterMetaType() or add a default constructor decorator to the class.";
PyErr_SetString(PyExc_ValueError, e.toLatin1().data());
result = NULL;
}
} else {
result = NULL;
}
}
recursiveEntry--;
// reset the parameter storage position to the stored pos to "pop" the parameter stack
PythonQtConv::global_valueStorage.setPos(globalValueStoragePos);
PythonQtConv::global_ptrStorage.setPos(globalPtrStoragePos);
PythonQtConv::global_variantStorage.setPos(globalVariantStoragePos);
*pythonReturnValue = result;
// NOTE: it is important to only return here, otherwise the stack will not be popped!!!
return result || (directReturnValuePointer && *directReturnValuePointer);
}