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pysidesignal.cpp
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pysidesignal.cpp
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// Copyright (C) 2020 The Qt Company Ltd.
// SPDX-License-Identifier: LicenseRef-Qt-Commercial OR LGPL-3.0-only OR GPL-2.0-only OR GPL-3.0-only
#include <sbkpython.h>
#include "pysidesignal.h"
#include "pysidesignal_p.h"
#include "pysideutils.h"
#include "pysidestaticstrings.h"
#include "pysideweakref.h"
#include "signalmanager.h"
#include <shiboken.h>
#include <QtCore/QByteArray>
#include <QtCore/QDebug>
#include <QtCore/QHash>
#include <QtCore/QObject>
#include <QtCore/QMetaMethod>
#include <QtCore/QMetaObject>
#include <signature.h>
#include <algorithm>
#include <utility>
#include <cstring>
#define QT_SIGNAL_SENTINEL '2'
QDebug operator<<(QDebug debug, const PySideSignalData::Signature &s)
{
QDebugStateSaver saver(debug);
debug.noquote();
debug.nospace();
debug << "Signature(\"" << s.signature << '"';
if (s.attributes)
debug << ", attributes=" << s.attributes;
debug << ')';
return debug;
}
QDebug operator<<(QDebug debug, const PySideSignalData &d)
{
QDebugStateSaver saver(debug);
debug.noquote();
debug.nospace();
debug << "PySideSignalData(\"" << d.signalName << "\", "
<< d.signatures;
if (d.signalArguments)
debug << ", signalArguments=\"" << *d.signalArguments << '"';
debug << ')';
return debug;
}
QDebug operator<<(QDebug debug, const PySideSignalInstancePrivate &d)
{
QDebugStateSaver saver(debug);
debug.noquote();
debug.nospace();
debug << "PySideSignalInstancePrivate(\"" << d.signalName
<< "\", \"" << d.signature << '"';
if (d.attributes)
debug << ", attributes=" << d.attributes;
if (d.homonymousMethod)
debug << ", homonymousMethod=" << d.homonymousMethod;
debug << ')';
return debug;
}
static bool connection_Check(PyObject *o)
{
if (o == nullptr || o == Py_None)
return false;
static QByteArray typeName = QByteArrayLiteral("PySide")
+ QByteArray::number(QT_VERSION_MAJOR)
+ QByteArrayLiteral(".QtCore.QMetaObject.Connection");
return std::strcmp(o->ob_type->tp_name, typeName.constData()) == 0;
}
namespace PySide {
namespace Signal {
//aux
class SignalSignature {
public:
SignalSignature() = default;
explicit SignalSignature(QByteArray parameterTypes) :
m_parameterTypes(std::move(parameterTypes)) {}
explicit SignalSignature(QByteArray parameterTypes, QMetaMethod::Attributes attributes) :
m_parameterTypes(std::move(parameterTypes)),
m_attributes(attributes) {}
QByteArray m_parameterTypes;
QMetaMethod::Attributes m_attributes = QMetaMethod::Compatibility;
};
static QByteArray buildSignature(const QByteArray &, const QByteArray &);
static void appendSignature(PySideSignal *, const SignalSignature &);
static void instanceInitialize(PySideSignalInstance *, PyObject *, PySideSignal *, PyObject *, int);
static QByteArray parseSignature(PyObject *);
static PyObject *buildQtCompatible(const QByteArray &);
}
}
extern "C"
{
// Signal methods
static int signalTpInit(PyObject *, PyObject *, PyObject *);
static void signalFree(void *);
static void signalInstanceFree(void *);
static PyObject *signalGetItem(PyObject *self, PyObject *key);
static PyObject *signalGetAttr(PyObject *self, PyObject *name);
static PyObject *signalToString(PyObject *self);
static PyObject *signalDescrGet(PyObject *self, PyObject *obj, PyObject *type);
// Signal Instance methods
static PyObject *signalInstanceConnect(PyObject *, PyObject *, PyObject *);
static PyObject *signalInstanceDisconnect(PyObject *, PyObject *);
static PyObject *signalInstanceEmit(PyObject *, PyObject *);
static PyObject *signalInstanceGetItem(PyObject *, PyObject *);
static PyObject *signalInstanceCall(PyObject *self, PyObject *args, PyObject *kw);
static PyObject *signalCall(PyObject *, PyObject *, PyObject *);
static PyObject *metaSignalCheck(PyObject *, PyObject *);
static PyMethodDef MetaSignal_tp_methods[] = {
{"__instancecheck__", reinterpret_cast<PyCFunction>(metaSignalCheck),
METH_O|METH_STATIC, nullptr},
{nullptr, nullptr, 0, nullptr}
};
static PyType_Slot PySideMetaSignalType_slots[] = {
{Py_tp_methods, reinterpret_cast<void *>(MetaSignal_tp_methods)},
{Py_tp_base, reinterpret_cast<void *>(&PyType_Type)},
{Py_tp_free, reinterpret_cast<void *>(PyObject_GC_Del)},
{Py_tp_dealloc, reinterpret_cast<void *>(Sbk_object_dealloc)},
{0, nullptr}
};
static PyType_Spec PySideMetaSignalType_spec = {
"2:PySide6.QtCore.MetaSignal",
0,
// sizeof(PyHeapTypeObject) is filled in by SbkType_FromSpec
// which calls PyType_Ready which calls inherit_special.
0,
Py_TPFLAGS_DEFAULT,
PySideMetaSignalType_slots,
};
static PyTypeObject *PySideMetaSignal_TypeF(void)
{
static auto *type = SbkType_FromSpec(&PySideMetaSignalType_spec);
return type;
}
static PyType_Slot PySideSignalType_slots[] = {
{Py_mp_subscript, reinterpret_cast<void *>(signalGetItem)},
{Py_tp_getattro, reinterpret_cast<void *>(signalGetAttr)},
{Py_tp_descr_get, reinterpret_cast<void *>(signalDescrGet)},
{Py_tp_call, reinterpret_cast<void *>(signalCall)},
{Py_tp_str, reinterpret_cast<void *>(signalToString)},
{Py_tp_init, reinterpret_cast<void *>(signalTpInit)},
{Py_tp_new, reinterpret_cast<void *>(PyType_GenericNew)},
{Py_tp_free, reinterpret_cast<void *>(signalFree)},
{Py_tp_dealloc, reinterpret_cast<void *>(Sbk_object_dealloc)},
{0, nullptr}
};
static PyType_Spec PySideSignalType_spec = {
"2:PySide6.QtCore.Signal",
sizeof(PySideSignal),
0,
Py_TPFLAGS_DEFAULT,
PySideSignalType_slots,
};
PyTypeObject *PySideSignal_TypeF(void)
{
static auto *type = SbkType_FromSpecWithMeta(&PySideSignalType_spec, PySideMetaSignal_TypeF());
return type;
}
static PyObject *signalInstanceRepr(PyObject *obSelf)
{
auto *self = reinterpret_cast<PySideSignalInstance *>(obSelf);
auto *typeName = Py_TYPE(obSelf)->tp_name;
return Shiboken::String::fromFormat("<%s %s at %p>", typeName,
self->d ? self->d->signature.constData()
: "(no signature)", obSelf);
}
static PyMethodDef SignalInstance_methods[] = {
{"connect", reinterpret_cast<PyCFunction>(signalInstanceConnect),
METH_VARARGS|METH_KEYWORDS, nullptr},
{"disconnect", signalInstanceDisconnect, METH_VARARGS, nullptr},
{"emit", signalInstanceEmit, METH_VARARGS, nullptr},
{nullptr, nullptr, 0, nullptr} /* Sentinel */
};
static PyType_Slot PySideSignalInstanceType_slots[] = {
{Py_mp_subscript, reinterpret_cast<void *>(signalInstanceGetItem)},
{Py_tp_call, reinterpret_cast<void *>(signalInstanceCall)},
{Py_tp_methods, reinterpret_cast<void *>(SignalInstance_methods)},
{Py_tp_repr, reinterpret_cast<void *>(signalInstanceRepr)},
{Py_tp_new, reinterpret_cast<void *>(PyType_GenericNew)},
{Py_tp_free, reinterpret_cast<void *>(signalInstanceFree)},
{Py_tp_dealloc, reinterpret_cast<void *>(Sbk_object_dealloc)},
{0, nullptr}
};
static PyType_Spec PySideSignalInstanceType_spec = {
"2:PySide6.QtCore.SignalInstance",
sizeof(PySideSignalInstance),
0,
Py_TPFLAGS_DEFAULT,
PySideSignalInstanceType_slots,
};
PyTypeObject *PySideSignalInstance_TypeF(void)
{
static auto *type = SbkType_FromSpec(&PySideSignalInstanceType_spec);
return type;
}
static int signalTpInit(PyObject *obSelf, PyObject *args, PyObject *kwds)
{
static PyObject * const emptyTuple = PyTuple_New(0);
static const char *kwlist[] = {"name", "arguments", nullptr};
char *argName = nullptr;
PyObject *argArguments = nullptr;
if (!PyArg_ParseTupleAndKeywords(emptyTuple, kwds,
"|sO:QtCore.Signal{name, arguments}",
const_cast<char **>(kwlist), &argName, &argArguments))
return -1;
bool tupledArgs = false;
PySideSignal *self = reinterpret_cast<PySideSignal *>(obSelf);
if (!self->data)
self->data = new PySideSignalData;
if (argName)
self->data->signalName = argName;
const Py_ssize_t argument_size =
argArguments != nullptr && PySequence_Check(argArguments)
? PySequence_Size(argArguments) : 0;
if (argument_size > 0) {
self->data->signalArguments = new QByteArrayList();
self->data->signalArguments->reserve(argument_size);
for (Py_ssize_t i = 0; i < argument_size; ++i) {
Shiboken::AutoDecRef item(PySequence_GetItem(argArguments, i));
Shiboken::AutoDecRef strObj(PyUnicode_AsUTF8String(item));
if (char *s = PyBytes_AsString(strObj))
self->data->signalArguments->append(QByteArray(s));
}
}
for (Py_ssize_t i = 0, i_max = PyTuple_Size(args); i < i_max; i++) {
PyObject *arg = PyTuple_GET_ITEM(args, i);
if (PySequence_Check(arg) && !Shiboken::String::check(arg) && !PyEnumMeta_Check(arg)) {
tupledArgs = true;
const auto sig = PySide::Signal::parseSignature(arg);
PySide::Signal::appendSignature(
self,
PySide::Signal::SignalSignature(sig));
}
}
if (!tupledArgs) {
const auto sig = PySide::Signal::parseSignature(args);
PySide::Signal::appendSignature(
self,
PySide::Signal::SignalSignature(sig));
}
return 0;
}
static void signalFree(void *vself)
{
auto pySelf = reinterpret_cast<PyObject *>(vself);
auto self = reinterpret_cast<PySideSignal *>(vself);
if (self->data) {
delete self->data->signalArguments;
delete self->data;
self->data = nullptr;
}
Py_XDECREF(self->homonymousMethod);
self->homonymousMethod = nullptr;
Py_TYPE(pySelf)->tp_base->tp_free(self);
}
static PyObject *signalGetItem(PyObject *obSelf, PyObject *key)
{
auto self = reinterpret_cast<PySideSignal *>(obSelf);
QByteArray sigKey;
if (key) {
sigKey = PySide::Signal::parseSignature(key);
} else {
sigKey = self->data == nullptr || self->data->signatures.isEmpty()
? PySide::Signal::voidType() : self->data->signatures.constFirst().signature;
}
auto sig = PySide::Signal::buildSignature(self->data->signalName, sigKey);
return Shiboken::String::fromCString(sig.constData());
}
static PyObject *signalToString(PyObject *self)
{
return signalGetItem(self, nullptr);
}
static PyObject *signalGetAttr(PyObject *obSelf, PyObject *name)
{
auto self = reinterpret_cast<PySideSignal *>(obSelf);
if (PyUnicode_CompareWithASCIIString(name, "signatures") != 0)
return PyObject_GenericGetAttr(obSelf, name);
auto nelems = self->data->signatures.count();
PyObject *tuple = PyTuple_New(nelems);
for (Py_ssize_t idx = 0; idx < nelems; ++idx) {
QByteArray sigKey = self->data->signatures.at(idx).signature;
auto sig = PySide::Signal::buildSignature(self->data->signalName, sigKey);
PyObject *entry = Shiboken::String::fromCString(sig.constData());
PyTuple_SetItem(tuple, idx, entry);
}
return tuple;
}
static void signalInstanceFree(void *vself)
{
auto pySelf = reinterpret_cast<PyObject *>(vself);
auto self = reinterpret_cast<PySideSignalInstance *>(vself);
PySideSignalInstancePrivate *dataPvt = self->d;
if (dataPvt) {
Py_XDECREF(dataPvt->homonymousMethod);
if (dataPvt->next) {
Py_DECREF(dataPvt->next);
dataPvt->next = nullptr;
}
delete dataPvt;
self->d = nullptr;
}
self->deleted = true;
Py_TYPE(pySelf)->tp_base->tp_free(self);
}
// PYSIDE-1523: PyFunction_Check is not accepting compiled functions and
// PyMethod_Check is not allowing compiled methods, therefore also lookup
// "im_func" and "__code__" attributes, we allow for that with a dedicated
// function handling both.
static void extractFunctionArgumentsFromSlot(PyObject *slot,
PyObject *& function,
PepCodeObject *& objCode,
bool &isMethod,
QByteArray *functionName)
{
isMethod = PyMethod_Check(slot);
bool isFunction = PyFunction_Check(slot);
function = nullptr;
objCode = nullptr;
if (isMethod || isFunction) {
function = isMethod ? PyMethod_GET_FUNCTION(slot) : slot;
objCode = reinterpret_cast<PepCodeObject *>(PyFunction_GET_CODE(function));
if (functionName != nullptr) {
*functionName = Shiboken::String::toCString(PepFunction_GetName(function));
}
} else if (PySide::isCompiledMethod(slot)) {
// PYSIDE-1523: PyFunction_Check and PyMethod_Check are not accepting compiled forms, we
// just go by attributes.
isMethod = true;
function = PyObject_GetAttr(slot, PySide::PySideName::im_func());
// Not retaining a reference inline with what PyMethod_GET_FUNCTION does.
Py_DECREF(function);
if (functionName != nullptr) {
PyObject *name = PyObject_GetAttr(function, PySide::PySideMagicName::name());
*functionName = Shiboken::String::toCString(name);
// Not retaining a reference inline with what PepFunction_GetName does.
Py_DECREF(name);
}
objCode = reinterpret_cast<PepCodeObject *>(
PyObject_GetAttr(function, PySide::PySideMagicName::code()));
// Not retaining a reference inline with what PyFunction_GET_CODE does.
Py_XDECREF(objCode);
if (objCode == nullptr) {
// Should not happen, but lets handle it gracefully, maybe Nuitka one day
// makes these optional, or somebody defined a type named like it without
// it being actually being that.
function = nullptr;
}
} else if (strcmp(Py_TYPE(slot)->tp_name, "compiled_function") == 0) {
isMethod = false;
function = slot;
if (functionName != nullptr) {
PyObject *name = PyObject_GetAttr(function, PySide::PySideMagicName::name());
*functionName = Shiboken::String::toCString(name);
// Not retaining a reference inline with what PepFunction_GetName does.
Py_DECREF(name);
}
objCode = reinterpret_cast<PepCodeObject *>(
PyObject_GetAttr(function, PySide::PySideMagicName::code()));
// Not retaining a reference inline with what PyFunction_GET_CODE does.
Py_XDECREF(objCode);
if (objCode == nullptr) {
// Should not happen, but lets handle it gracefully, maybe Nuitka one day
// makes these optional, or somebody defined a type named like it without
// it being actually being that.
function = nullptr;
}
}
// any other callback
}
static PyObject *signalInstanceConnect(PyObject *self, PyObject *args, PyObject *kwds)
{
PyObject *slot = nullptr;
PyObject *type = nullptr;
static const char *kwlist[] = {"slot", "type", nullptr};
if (!PyArg_ParseTupleAndKeywords(args, kwds,
"O|O:SignalInstance", const_cast<char **>(kwlist), &slot, &type))
return nullptr;
PySideSignalInstance *source = reinterpret_cast<PySideSignalInstance *>(self);
if (!source->d) {
PyErr_Format(PyExc_RuntimeError, "cannot connect uninitialized SignalInstance");
return nullptr;
}
if (source->deleted) {
PyErr_Format(PyExc_RuntimeError, "Signal source has been deleted");
return nullptr;
}
Shiboken::AutoDecRef pyArgs(PyList_New(0));
bool match = false;
if (Py_TYPE(slot) == PySideSignalInstance_TypeF()) {
PySideSignalInstance *sourceWalk = source;
//find best match
while (sourceWalk && !match) {
auto targetWalk = reinterpret_cast<PySideSignalInstance *>(slot);
while (targetWalk && !match) {
if (QMetaObject::checkConnectArgs(sourceWalk->d->signature,
targetWalk->d->signature)) {
PyList_Append(pyArgs, sourceWalk->d->source);
Shiboken::AutoDecRef sourceSignature(PySide::Signal::buildQtCompatible(sourceWalk->d->signature));
PyList_Append(pyArgs, sourceSignature);
PyList_Append(pyArgs, targetWalk->d->source);
Shiboken::AutoDecRef targetSignature(PySide::Signal::buildQtCompatible(targetWalk->d->signature));
PyList_Append(pyArgs, targetSignature);
match = true;
}
targetWalk = reinterpret_cast<PySideSignalInstance *>(targetWalk->d->next);
}
sourceWalk = reinterpret_cast<PySideSignalInstance *>(sourceWalk->d->next);
}
} else {
// Check signature of the slot (method or function) to match signal
int slotArgs = -1;
bool matchedSlot = false;
PySideSignalInstance *it = source;
PyObject *function = nullptr;
PepCodeObject *objCode = nullptr;
bool useSelf = false;
extractFunctionArgumentsFromSlot(slot, function, objCode, useSelf, nullptr);
if (function != nullptr) {
slotArgs = PepCode_GET_FLAGS(objCode) & CO_VARARGS ? -1 : PepCode_GET_ARGCOUNT(objCode);
if (useSelf)
slotArgs -= 1;
// Get signature args
bool isShortCircuit = false;
int signatureArgs = 0;
QStringList argsSignature;
argsSignature = PySide::Signal::getArgsFromSignature(it->d->signature,
&isShortCircuit);
signatureArgs = argsSignature.length();
// Iterate the possible types of connection for this signal and compare
// it with slot arguments
if (signatureArgs != slotArgs) {
while (it->d->next != nullptr) {
it = it->d->next;
argsSignature = PySide::Signal::getArgsFromSignature(it->d->signature,
&isShortCircuit);
signatureArgs = argsSignature.length();
if (signatureArgs == slotArgs) {
matchedSlot = true;
break;
}
}
}
}
// Adding references to pyArgs
PyList_Append(pyArgs, source->d->source);
if (matchedSlot) {
// If a slot matching the same number of arguments was found,
// include signature to the pyArgs
Shiboken::AutoDecRef signature(PySide::Signal::buildQtCompatible(it->d->signature));
PyList_Append(pyArgs, signature);
} else {
// Try the first by default if the slot was not found
Shiboken::AutoDecRef signature(PySide::Signal::buildQtCompatible(source->d->signature));
PyList_Append(pyArgs, signature);
}
PyList_Append(pyArgs, slot);
match = true;
}
if (type)
PyList_Append(pyArgs, type);
if (match) {
Shiboken::AutoDecRef tupleArgs(PyList_AsTuple(pyArgs));
Shiboken::AutoDecRef pyMethod(PyObject_GetAttr(source->d->source,
PySide::PySideName::qtConnect()));
if (pyMethod.isNull()) { // PYSIDE-79: check if pyMethod exists.
PyErr_SetString(PyExc_RuntimeError, "method 'connect' vanished!");
return nullptr;
}
PyObject *result = PyObject_CallObject(pyMethod, tupleArgs);
if (connection_Check(result))
return result;
Py_XDECREF(result);
}
if (!PyErr_Occurred()) // PYSIDE-79: inverse the logic. A Null return needs an error.
PyErr_Format(PyExc_RuntimeError, "Failed to connect signal %s.",
source->d->signature.constData());
return nullptr;
}
static int argCountInSignature(const char *signature)
{
return QByteArray(signature).count(",") + 1;
}
static PyObject *signalInstanceEmit(PyObject *self, PyObject *args)
{
PySideSignalInstance *source = reinterpret_cast<PySideSignalInstance *>(self);
if (!source->d) {
PyErr_Format(PyExc_RuntimeError, "cannot emit uninitialized SignalInstance");
return nullptr;
}
// PYSIDE-2201: Check if the object has vanished meanwhile.
// Tried to revive it without exception, but this gives problems.
if (source->deleted) {
PyErr_Format(PyExc_RuntimeError, "The SignalInstance object was already deleted");
return nullptr;
}
Shiboken::AutoDecRef pyArgs(PyList_New(0));
int numArgsGiven = PySequence_Fast_GET_SIZE(args);
int numArgsInSignature = argCountInSignature(source->d->signature);
// If number of arguments given to emit is smaller than the first source signature expects,
// it is possible it's a case of emitting a signal with default parameters.
// Search through all the overloaded signals with the same name, and try to find a signature
// with the same number of arguments as given to emit, and is also marked as a cloned method
// (which in metaobject parlance means a signal with default parameters).
// @TODO: This should be improved to take into account argument types as well. The current
// assumption is there are no signals which are both overloaded on argument types and happen to
// have signatures with default parameters.
if (numArgsGiven < numArgsInSignature) {
PySideSignalInstance *possibleDefaultInstance = source;
while ((possibleDefaultInstance = possibleDefaultInstance->d->next)) {
if (possibleDefaultInstance->d->attributes & QMetaMethod::Cloned
&& argCountInSignature(possibleDefaultInstance->d->signature) == numArgsGiven) {
source = possibleDefaultInstance;
break;
}
}
}
Shiboken::AutoDecRef sourceSignature(PySide::Signal::buildQtCompatible(source->d->signature));
PyList_Append(pyArgs, sourceSignature);
for (Py_ssize_t i = 0, max = PyTuple_Size(args); i < max; i++)
PyList_Append(pyArgs, PyTuple_GetItem(args, i));
Shiboken::AutoDecRef pyMethod(PyObject_GetAttr(source->d->source,
PySide::PySideName::qtEmit()));
Shiboken::AutoDecRef tupleArgs(PyList_AsTuple(pyArgs));
return PyObject_CallObject(pyMethod.object(), tupleArgs);
}
static PyObject *signalInstanceGetItem(PyObject *self, PyObject *key)
{
auto *firstSignal = reinterpret_cast<PySideSignalInstance *>(self);
const auto &sigName = firstSignal->d->signalName;
const auto sigKey = PySide::Signal::parseSignature(key);
const auto sig = PySide::Signal::buildSignature(sigName, sigKey);
for (auto *data = firstSignal; data != nullptr; data = data->d->next) {
if (data->d->signature == sig) {
PyObject *result = reinterpret_cast<PyObject *>(data);
Py_INCREF(result);
return result;
}
}
// Build error message with candidates
QByteArray message = "Signature \"" + sig + "\" not found for signal: \""
+ sigName + "\". Available candidates: ";
for (auto *data = firstSignal; data != nullptr; data = data->d->next) {
if (data != firstSignal)
message += ", ";
message += '"' + data->d->signature + '"';
}
PyErr_SetString(PyExc_IndexError, message.constData());
return nullptr;
}
static PyObject *signalInstanceDisconnect(PyObject *self, PyObject *args)
{
auto source = reinterpret_cast<PySideSignalInstance *>(self);
if (!source->d) {
PyErr_Format(PyExc_RuntimeError, "cannot disconnect uninitialized SignalInstance");
return nullptr;
}
Shiboken::AutoDecRef pyArgs(PyList_New(0));
PyObject *slot = Py_None;
if (PyTuple_Check(args) && PyTuple_GET_SIZE(args))
slot = PyTuple_GET_ITEM(args, 0);
bool match = false;
if (Py_TYPE(slot) == PySideSignalInstance_TypeF()) {
PySideSignalInstance *target = reinterpret_cast<PySideSignalInstance *>(slot);
if (QMetaObject::checkConnectArgs(source->d->signature, target->d->signature)) {
PyList_Append(pyArgs, source->d->source);
Shiboken::AutoDecRef source_signature(PySide::Signal::buildQtCompatible(source->d->signature));
PyList_Append(pyArgs, source_signature);
PyList_Append(pyArgs, target->d->source);
Shiboken::AutoDecRef target_signature(PySide::Signal::buildQtCompatible(target->d->signature));
PyList_Append(pyArgs, target_signature);
match = true;
}
} else if (connection_Check(slot)) {
PyList_Append(pyArgs, slot);
match = true;
} else {
//try the first signature
PyList_Append(pyArgs, source->d->source);
Shiboken::AutoDecRef signature(PySide::Signal::buildQtCompatible(source->d->signature));
PyList_Append(pyArgs, signature);
// disconnect all, so we need to use the c++ signature disconnect(qobj, signal, 0, 0)
if (slot == Py_None)
PyList_Append(pyArgs, slot);
PyList_Append(pyArgs, slot);
match = true;
}
if (match) {
Shiboken::AutoDecRef tupleArgs(PyList_AsTuple(pyArgs));
Shiboken::AutoDecRef pyMethod(PyObject_GetAttr(source->d->source,
PySide::PySideName::qtDisconnect()));
PyObject *result = PyObject_CallObject(pyMethod, tupleArgs);
if (!result || result == Py_True)
return result;
Py_DECREF(result);
}
PyErr_Format(PyExc_RuntimeError, "Failed to disconnect signal %s.",
source->d->signature.constData());
return nullptr;
}
// PYSIDE-68: Supply the missing __get__ function
static PyObject *signalDescrGet(PyObject *self, PyObject *obj, PyObject * /*type*/)
{
auto signal = reinterpret_cast<PySideSignal *>(self);
// Return the unbound signal if there is nothing to bind it to.
if (obj == nullptr || obj == Py_None) {
Py_INCREF(self);
return self;
}
// PYSIDE-68-bis: It is important to respect the already cached instance.
Shiboken::AutoDecRef name(Py_BuildValue("s", signal->data->signalName.data()));
auto *dict = SbkObject_GetDict_NoRef(obj);
auto *inst = PyDict_GetItem(dict, name);
if (inst) {
Py_INCREF(inst);
return inst;
}
inst = reinterpret_cast<PyObject *>(PySide::Signal::initialize(signal, name, obj));
PyObject_SetAttr(obj, name, inst);
return inst;
}
static PyObject *signalCall(PyObject *self, PyObject *args, PyObject *kw)
{
auto signal = reinterpret_cast<PySideSignal *>(self);
// Native C++ signals can't be called like functions, thus we throw an exception.
// The only way calling a signal can succeed (the Python equivalent of C++'s operator() )
// is when a method with the same name as the signal is attached to an object.
// An example is QProcess::error() (don't check the docs, but the source code of qprocess.h).
if (!signal->homonymousMethod) {
PyErr_SetString(PyExc_TypeError, "native Qt signal is not callable");
return nullptr;
}
descrgetfunc getDescriptor = Py_TYPE(signal->homonymousMethod)->tp_descr_get;
// Check if there exists a method with the same name as the signal, which is also a static
// method in C++ land.
Shiboken::AutoDecRef homonymousMethod(getDescriptor(signal->homonymousMethod,
nullptr, nullptr));
if (PyCFunction_Check(homonymousMethod.object())
&& (PyCFunction_GET_FLAGS(homonymousMethod.object()) & METH_STATIC))
return PyObject_Call(homonymousMethod, args, kw);
// Assumes homonymousMethod is not a static method.
ternaryfunc callFunc = Py_TYPE(signal->homonymousMethod)->tp_call;
return callFunc(homonymousMethod, args, kw);
}
// This function returns a borrowed reference.
static inline PyObject *_getRealCallable(PyObject *func)
{
static const auto *SignalType = PySideSignal_TypeF();
static const auto *SignalInstanceType = PySideSignalInstance_TypeF();
// If it is a signal, use the (maybe empty) homonymous method.
if (Py_TYPE(func) == SignalType) {
auto *signal = reinterpret_cast<PySideSignal *>(func);
return signal->homonymousMethod;
}
// If it is a signal instance, use the (maybe empty) homonymous method.
if (Py_TYPE(func) == SignalInstanceType) {
auto *signalInstance = reinterpret_cast<PySideSignalInstance *>(func);
return signalInstance->d->homonymousMethod;
}
return func;
}
// This function returns a borrowed reference.
static PyObject *_getHomonymousMethod(PySideSignalInstance *inst)
{
if (inst->d->homonymousMethod)
return inst->d->homonymousMethod;
// PYSIDE-1730: We are searching methods with the same name not only at the same place,
// but walk through the whole mro to find a hidden method with the same name.
auto signalName = inst->d->signalName;
Shiboken::AutoDecRef name(Shiboken::String::fromCString(signalName));
auto *mro = Py_TYPE(inst->d->source)->tp_mro;
Py_ssize_t idx, n = PyTuple_GET_SIZE(mro);
for (idx = 0; idx < n; idx++) {
auto *sub_type = reinterpret_cast<PyTypeObject *>(PyTuple_GET_ITEM(mro, idx));
auto *hom = PyDict_GetItem(sub_type->tp_dict, name);
PyObject *realFunc{};
if (hom && PyCallable_Check(hom) && (realFunc = _getRealCallable(hom)))
return realFunc;
}
return nullptr;
}
static PyObject *signalInstanceCall(PyObject *self, PyObject *args, PyObject *kw)
{
auto *PySideSignal = reinterpret_cast<PySideSignalInstance *>(self);
auto *hom = _getHomonymousMethod(PySideSignal);
if (!hom) {
PyErr_Format(PyExc_TypeError, "native Qt signal instance '%s' is not callable",
PySideSignal->d->signalName.constData());
return nullptr;
}
descrgetfunc getDescriptor = Py_TYPE(hom)->tp_descr_get;
Shiboken::AutoDecRef homonymousMethod(getDescriptor(hom, PySideSignal->d->source, nullptr));
return PyObject_Call(homonymousMethod, args, kw);
}
static PyObject *metaSignalCheck(PyObject * /* klass */, PyObject *arg)
{
if (PyType_IsSubtype(Py_TYPE(arg), PySideSignalInstance_TypeF()))
Py_RETURN_TRUE;
Py_RETURN_FALSE;
}
} // extern "C"
namespace PySide {
namespace Signal {
static const char *MetaSignal_SignatureStrings[] = {
"PySide6.QtCore.MetaSignal.__instancecheck__(self,object:object)->bool",
nullptr}; // Sentinel
static const char *Signal_SignatureStrings[] = {
"PySide6.QtCore.Signal(self,*types:type,name:str=nullptr,arguments:str=nullptr)",
"1:PySide6.QtCore.Signal.__get__(self,instance:None,owner:Optional[typing.Any])->"
"PySide6.QtCore.Signal",
"0:PySide6.QtCore.Signal.__get__(self,instance:PySide6.QtCore.QObject,"
"owner:Optional[typing.Any])->PySide6.QtCore.SignalInstance",
nullptr}; // Sentinel
static const char *SignalInstance_SignatureStrings[] = {
"PySide6.QtCore.SignalInstance.connect(self,slot:object,type:type=nullptr)",
"PySide6.QtCore.SignalInstance.disconnect(self,slot:object=nullptr)",
"PySide6.QtCore.SignalInstance.emit(self,*args:typing.Any)",
nullptr}; // Sentinel
void init(PyObject *module)
{
if (InitSignatureStrings(PySideMetaSignal_TypeF(), MetaSignal_SignatureStrings) < 0)
return;
Py_INCREF(PySideMetaSignal_TypeF());
auto *obMetaSignal_Type = reinterpret_cast<PyObject *>(PySideMetaSignal_TypeF());
PyModule_AddObject(module, "MetaSignal", obMetaSignal_Type);
if (InitSignatureStrings(PySideSignal_TypeF(), Signal_SignatureStrings) < 0)
return;
Py_INCREF(PySideSignal_TypeF());
auto *obSignal_Type = reinterpret_cast<PyObject *>(PySideSignal_TypeF());
PyModule_AddObject(module, "Signal", obSignal_Type);
if (InitSignatureStrings(PySideSignalInstance_TypeF(), SignalInstance_SignatureStrings) < 0)
return;
Py_INCREF(PySideSignalInstance_TypeF());
auto *obSignalInstance_Type = reinterpret_cast<PyObject *>(PySideSignalInstance_TypeF());
PyModule_AddObject(module, "SignalInstance", obSignalInstance_Type);
}
bool checkType(PyObject *pyObj)
{
if (pyObj)
return PyType_IsSubtype(Py_TYPE(pyObj), PySideSignal_TypeF());
return false;
}
bool checkInstanceType(PyObject *pyObj)
{
return pyObj != nullptr
&& PyType_IsSubtype(Py_TYPE(pyObj), PySideSignalInstance_TypeF()) != 0;
}
void updateSourceObject(PyObject *source)
{
// TODO: Provide for actual upstream exception handling.
// For now we'll just return early to avoid further issues.
if (source == nullptr) // Bad input
return;
Shiboken::AutoDecRef mroIterator(PyObject_GetIter(source->ob_type->tp_mro));
if (mroIterator.isNull()) // Not iterable
return;
Shiboken::AutoDecRef mroItem{};
auto *dict = SbkObject_GetDict_NoRef(source);
// PYSIDE-1431: Walk the mro and update. But see PYSIDE-1751 below.
while ((mroItem.reset(PyIter_Next(mroIterator))), mroItem.object()) {
Py_ssize_t pos = 0;
PyObject *key, *value;
auto *type = reinterpret_cast<PyTypeObject *>(mroItem.object());
while (PyDict_Next(type->tp_dict, &pos, &key, &value)) {
if (PyObject_TypeCheck(value, PySideSignal_TypeF())) {
// PYSIDE-1751: We only insert an instance into the instance dict, if a signal
// of the same name is in the mro. This is the equivalent action
// as PyObject_SetAttr, but filtered by existing signal names.
if (!PyDict_GetItem(dict, key)) {
auto *inst = PyObject_New(PySideSignalInstance, PySideSignalInstance_TypeF());
Shiboken::AutoDecRef signalInstance(reinterpret_cast<PyObject *>(inst));
instanceInitialize(signalInstance.cast<PySideSignalInstance *>(),
key, reinterpret_cast<PySideSignal *>(value), source, 0);
if (PyDict_SetItem(dict, key, signalInstance) == -1)
return; // An error occurred while setting the attribute
}
}
}
}
if (PyErr_Occurred()) // An iteration error occurred
return;
}
QByteArray getTypeName(PyObject *obType)
{
if (PyType_Check(obType)) {
auto *type = reinterpret_cast<PyTypeObject *>(obType);
if (PyType_IsSubtype(type, SbkObject_TypeF()))
return Shiboken::ObjectType::getOriginalName(type);
// Translate Python types to Qt names
if (Shiboken::String::checkType(type))
return QByteArrayLiteral("QString");
if (type == &PyLong_Type)
return QByteArrayLiteral("int");
if (type == &PyFloat_Type)
return QByteArrayLiteral("double");
if (type == &PyBool_Type)
return QByteArrayLiteral("bool");
if (type == &PyList_Type)
return QByteArrayLiteral("QVariantList");
if (type == &PyDict_Type)
return QByteArrayLiteral("QVariantMap");
return QByteArrayLiteral("PyObject");
}
if (obType == Py_None) // Must be checked before as Shiboken::String::check accepts Py_None
return voidType();
if (Shiboken::String::check(obType)) {
QByteArray result = Shiboken::String::toCString(obType);
if (result == "qreal")
result = sizeof(qreal) == sizeof(double) ? "double" : "float";
return result;
}
return QByteArray();
}
static QByteArray buildSignature(const QByteArray &name, const QByteArray &signature)
{
return QMetaObject::normalizedSignature(name + '(' + signature + ')');
}
static QByteArray parseSignature(PyObject *args)
{
if (args && (Shiboken::String::check(args) || !PyTuple_Check(args)))
return getTypeName(args);
QByteArray signature;
for (Py_ssize_t i = 0, i_max = PySequence_Size(args); i < i_max; i++) {
Shiboken::AutoDecRef arg(PySequence_GetItem(args, i));
const auto typeName = getTypeName(arg);
if (!typeName.isEmpty()) {
if (!signature.isEmpty())
signature += ',';
signature += typeName;
}
}
return signature;
}
static void appendSignature(PySideSignal *self, const SignalSignature &signature)
{
self->data->signatures.append({signature.m_parameterTypes, signature.m_attributes});
}
static void sourceGone(void *data)
{
auto *self = reinterpret_cast<PySideSignalInstance *>(data);
self->deleted = true;
}
static void instanceInitialize(PySideSignalInstance *self, PyObject *name, PySideSignal *signal, PyObject *source, int index)
{
self->d = new PySideSignalInstancePrivate;
self->deleted = false;
PySideSignalInstancePrivate *selfPvt = self->d;
selfPvt->next = nullptr;
if (signal->data->signalName.isEmpty())
signal->data->signalName = Shiboken::String::toCString(name);
selfPvt->signalName = signal->data->signalName;
selfPvt->source = source;
const auto &signature = signal->data->signatures.at(index);
selfPvt->signature = buildSignature(self->d->signalName, signature.signature);
selfPvt->attributes = signature.attributes;
selfPvt->homonymousMethod = nullptr;
if (signal->homonymousMethod) {
selfPvt->homonymousMethod = signal->homonymousMethod;
Py_INCREF(selfPvt->homonymousMethod);
}
// PYSIDE-2201: We have no reference to source. Let's take a weakref to get
// notified when source gets deleted.
PySide::WeakRef::create(source, sourceGone, self);
index++;