#include #include #include #include #include #include #include #include #include #include #include #include #include "gen_qiodevice.h" #include "_cgo_export.h" class MiqtVirtualQIODevice : public virtual QIODevice { public: MiqtVirtualQIODevice(): QIODevice() {}; MiqtVirtualQIODevice(QObject* parent): QIODevice(parent) {}; virtual ~MiqtVirtualQIODevice() = default; // cgo.Handle value for overwritten implementation intptr_t handle__IsSequential = 0; // Subclass to allow providing a Go implementation virtual bool isSequential() const override { if (handle__IsSequential == 0) { return QIODevice::isSequential(); } bool callback_return_value = miqt_exec_callback_QIODevice_IsSequential(const_cast(this), handle__IsSequential); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_IsSequential() const { return QIODevice::isSequential(); } // cgo.Handle value for overwritten implementation intptr_t handle__Open = 0; // Subclass to allow providing a Go implementation virtual bool open(QIODevice::OpenMode mode) override { if (handle__Open == 0) { return QIODevice::open(mode); } QIODevice::OpenMode mode_ret = mode; int sigval1 = static_cast(mode_ret); bool callback_return_value = miqt_exec_callback_QIODevice_Open(this, handle__Open, sigval1); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_Open(int mode) { return QIODevice::open(static_cast(mode)); } // cgo.Handle value for overwritten implementation intptr_t handle__Close = 0; // Subclass to allow providing a Go implementation virtual void close() override { if (handle__Close == 0) { QIODevice::close(); return; } miqt_exec_callback_QIODevice_Close(this, handle__Close); } // Wrapper to allow calling protected method void virtualbase_Close() { QIODevice::close(); } // cgo.Handle value for overwritten implementation intptr_t handle__Pos = 0; // Subclass to allow providing a Go implementation virtual qint64 pos() const override { if (handle__Pos == 0) { return QIODevice::pos(); } long long callback_return_value = miqt_exec_callback_QIODevice_Pos(const_cast(this), handle__Pos); return static_cast(callback_return_value); } // Wrapper to allow calling protected method long long virtualbase_Pos() const { qint64 _ret = QIODevice::pos(); return static_cast(_ret); } // cgo.Handle value for overwritten implementation intptr_t handle__Size = 0; // Subclass to allow providing a Go implementation virtual qint64 size() const override { if (handle__Size == 0) { return QIODevice::size(); } long long callback_return_value = miqt_exec_callback_QIODevice_Size(const_cast(this), handle__Size); return static_cast(callback_return_value); } // Wrapper to allow calling protected method long long virtualbase_Size() const { qint64 _ret = QIODevice::size(); return static_cast(_ret); } // cgo.Handle value for overwritten implementation intptr_t handle__Seek = 0; // Subclass to allow providing a Go implementation virtual bool seek(qint64 pos) override { if (handle__Seek == 0) { return QIODevice::seek(pos); } qint64 pos_ret = pos; long long sigval1 = static_cast(pos_ret); bool callback_return_value = miqt_exec_callback_QIODevice_Seek(this, handle__Seek, sigval1); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_Seek(long long pos) { return QIODevice::seek(static_cast(pos)); } // cgo.Handle value for overwritten implementation intptr_t handle__AtEnd = 0; // Subclass to allow providing a Go implementation virtual bool atEnd() const override { if (handle__AtEnd == 0) { return QIODevice::atEnd(); } bool callback_return_value = miqt_exec_callback_QIODevice_AtEnd(const_cast(this), handle__AtEnd); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_AtEnd() const { return QIODevice::atEnd(); } // cgo.Handle value for overwritten implementation intptr_t handle__Reset = 0; // Subclass to allow providing a Go implementation virtual bool reset() override { if (handle__Reset == 0) { return QIODevice::reset(); } bool callback_return_value = miqt_exec_callback_QIODevice_Reset(this, handle__Reset); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_Reset() { return QIODevice::reset(); } // cgo.Handle value for overwritten implementation intptr_t handle__BytesAvailable = 0; // Subclass to allow providing a Go implementation virtual qint64 bytesAvailable() const override { if (handle__BytesAvailable == 0) { return QIODevice::bytesAvailable(); } long long callback_return_value = miqt_exec_callback_QIODevice_BytesAvailable(const_cast(this), handle__BytesAvailable); return static_cast(callback_return_value); } // Wrapper to allow calling protected method long long virtualbase_BytesAvailable() const { qint64 _ret = QIODevice::bytesAvailable(); return static_cast(_ret); } // cgo.Handle value for overwritten implementation intptr_t handle__BytesToWrite = 0; // Subclass to allow providing a Go implementation virtual qint64 bytesToWrite() const override { if (handle__BytesToWrite == 0) { return QIODevice::bytesToWrite(); } long long callback_return_value = miqt_exec_callback_QIODevice_BytesToWrite(const_cast(this), handle__BytesToWrite); return static_cast(callback_return_value); } // Wrapper to allow calling protected method long long virtualbase_BytesToWrite() const { qint64 _ret = QIODevice::bytesToWrite(); return static_cast(_ret); } // cgo.Handle value for overwritten implementation intptr_t handle__CanReadLine = 0; // Subclass to allow providing a Go implementation virtual bool canReadLine() const override { if (handle__CanReadLine == 0) { return QIODevice::canReadLine(); } bool callback_return_value = miqt_exec_callback_QIODevice_CanReadLine(const_cast(this), handle__CanReadLine); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_CanReadLine() const { return QIODevice::canReadLine(); } // cgo.Handle value for overwritten implementation intptr_t handle__WaitForReadyRead = 0; // Subclass to allow providing a Go implementation virtual bool waitForReadyRead(int msecs) override { if (handle__WaitForReadyRead == 0) { return QIODevice::waitForReadyRead(msecs); } int sigval1 = msecs; bool callback_return_value = miqt_exec_callback_QIODevice_WaitForReadyRead(this, handle__WaitForReadyRead, sigval1); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_WaitForReadyRead(int msecs) { return QIODevice::waitForReadyRead(static_cast(msecs)); } // cgo.Handle value for overwritten implementation intptr_t handle__WaitForBytesWritten = 0; // Subclass to allow providing a Go implementation virtual bool waitForBytesWritten(int msecs) override { if (handle__WaitForBytesWritten == 0) { return QIODevice::waitForBytesWritten(msecs); } int sigval1 = msecs; bool callback_return_value = miqt_exec_callback_QIODevice_WaitForBytesWritten(this, handle__WaitForBytesWritten, sigval1); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_WaitForBytesWritten(int msecs) { return QIODevice::waitForBytesWritten(static_cast(msecs)); } // cgo.Handle value for overwritten implementation intptr_t handle__ReadData = 0; // Subclass to allow providing a Go implementation virtual qint64 readData(char* data, qint64 maxlen) override { if (handle__ReadData == 0) { return 0; // Pure virtual, there is no base we can call } char* sigval1 = data; qint64 maxlen_ret = maxlen; long long sigval2 = static_cast(maxlen_ret); long long callback_return_value = miqt_exec_callback_QIODevice_ReadData(this, handle__ReadData, sigval1, sigval2); return static_cast(callback_return_value); } // cgo.Handle value for overwritten implementation intptr_t handle__ReadLineData = 0; // Subclass to allow providing a Go implementation virtual qint64 readLineData(char* data, qint64 maxlen) override { if (handle__ReadLineData == 0) { return QIODevice::readLineData(data, maxlen); } char* sigval1 = data; qint64 maxlen_ret = maxlen; long long sigval2 = static_cast(maxlen_ret); long long callback_return_value = miqt_exec_callback_QIODevice_ReadLineData(this, handle__ReadLineData, sigval1, sigval2); return static_cast(callback_return_value); } // Wrapper to allow calling protected method long long virtualbase_ReadLineData(char* data, long long maxlen) { qint64 _ret = QIODevice::readLineData(data, static_cast(maxlen)); return static_cast(_ret); } // cgo.Handle value for overwritten implementation intptr_t handle__WriteData = 0; // Subclass to allow providing a Go implementation virtual qint64 writeData(const char* data, qint64 lenVal) override { if (handle__WriteData == 0) { return 0; // Pure virtual, there is no base we can call } const char* sigval1 = (const char*) data; qint64 lenVal_ret = lenVal; long long sigval2 = static_cast(lenVal_ret); long long callback_return_value = miqt_exec_callback_QIODevice_WriteData(this, handle__WriteData, sigval1, sigval2); return static_cast(callback_return_value); } // cgo.Handle value for overwritten implementation intptr_t handle__Event = 0; // Subclass to allow providing a Go implementation virtual bool event(QEvent* event) override { if (handle__Event == 0) { return QIODevice::event(event); } QEvent* sigval1 = event; bool callback_return_value = miqt_exec_callback_QIODevice_Event(this, handle__Event, sigval1); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_Event(QEvent* event) { return QIODevice::event(event); } // cgo.Handle value for overwritten implementation intptr_t handle__EventFilter = 0; // Subclass to allow providing a Go implementation virtual bool eventFilter(QObject* watched, QEvent* event) override { if (handle__EventFilter == 0) { return QIODevice::eventFilter(watched, event); } QObject* sigval1 = watched; QEvent* sigval2 = event; bool callback_return_value = miqt_exec_callback_QIODevice_EventFilter(this, handle__EventFilter, sigval1, sigval2); return callback_return_value; } // Wrapper to allow calling protected method bool virtualbase_EventFilter(QObject* watched, QEvent* event) { return QIODevice::eventFilter(watched, event); } // cgo.Handle value for overwritten implementation intptr_t handle__TimerEvent = 0; // Subclass to allow providing a Go implementation virtual void timerEvent(QTimerEvent* event) override { if (handle__TimerEvent == 0) { QIODevice::timerEvent(event); return; } QTimerEvent* sigval1 = event; miqt_exec_callback_QIODevice_TimerEvent(this, handle__TimerEvent, sigval1); } // Wrapper to allow calling protected method void virtualbase_TimerEvent(QTimerEvent* event) { QIODevice::timerEvent(event); } // cgo.Handle value for overwritten implementation intptr_t handle__ChildEvent = 0; // Subclass to allow providing a Go implementation virtual void childEvent(QChildEvent* event) override { if (handle__ChildEvent == 0) { QIODevice::childEvent(event); return; } QChildEvent* sigval1 = event; miqt_exec_callback_QIODevice_ChildEvent(this, handle__ChildEvent, sigval1); } // Wrapper to allow calling protected method void virtualbase_ChildEvent(QChildEvent* event) { QIODevice::childEvent(event); } // cgo.Handle value for overwritten implementation intptr_t handle__CustomEvent = 0; // Subclass to allow providing a Go implementation virtual void customEvent(QEvent* event) override { if (handle__CustomEvent == 0) { QIODevice::customEvent(event); return; } QEvent* sigval1 = event; miqt_exec_callback_QIODevice_CustomEvent(this, handle__CustomEvent, sigval1); } // Wrapper to allow calling protected method void virtualbase_CustomEvent(QEvent* event) { QIODevice::customEvent(event); } // cgo.Handle value for overwritten implementation intptr_t handle__ConnectNotify = 0; // Subclass to allow providing a Go implementation virtual void connectNotify(const QMetaMethod& signal) override { if (handle__ConnectNotify == 0) { QIODevice::connectNotify(signal); return; } const QMetaMethod& signal_ret = signal; // Cast returned reference into pointer QMetaMethod* sigval1 = const_cast(&signal_ret); miqt_exec_callback_QIODevice_ConnectNotify(this, handle__ConnectNotify, sigval1); } // Wrapper to allow calling protected method void virtualbase_ConnectNotify(QMetaMethod* signal) { QIODevice::connectNotify(*signal); } // cgo.Handle value for overwritten implementation intptr_t handle__DisconnectNotify = 0; // Subclass to allow providing a Go implementation virtual void disconnectNotify(const QMetaMethod& signal) override { if (handle__DisconnectNotify == 0) { QIODevice::disconnectNotify(signal); return; } const QMetaMethod& signal_ret = signal; // Cast returned reference into pointer QMetaMethod* sigval1 = const_cast(&signal_ret); miqt_exec_callback_QIODevice_DisconnectNotify(this, handle__DisconnectNotify, sigval1); } // Wrapper to allow calling protected method void virtualbase_DisconnectNotify(QMetaMethod* signal) { QIODevice::disconnectNotify(*signal); } }; void QIODevice_new(QIODevice** outptr_QIODevice, QObject** outptr_QObject) { MiqtVirtualQIODevice* ret = new MiqtVirtualQIODevice(); *outptr_QIODevice = ret; *outptr_QObject = static_cast(ret); } void QIODevice_new2(QObject* parent, QIODevice** outptr_QIODevice, QObject** outptr_QObject) { MiqtVirtualQIODevice* ret = new MiqtVirtualQIODevice(parent); *outptr_QIODevice = ret; *outptr_QObject = static_cast(ret); } QMetaObject* QIODevice_MetaObject(const QIODevice* self) { return (QMetaObject*) self->metaObject(); } void* QIODevice_Metacast(QIODevice* self, const char* param1) { return self->qt_metacast(param1); } struct miqt_string QIODevice_Tr(const char* s) { QString _ret = QIODevice::tr(s); // Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory QByteArray _b = _ret.toUtf8(); struct miqt_string _ms; _ms.len = _b.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _b.data(), _ms.len); return _ms; } struct miqt_string QIODevice_TrUtf8(const char* s) { QString _ret = QIODevice::trUtf8(s); // Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory QByteArray _b = _ret.toUtf8(); struct miqt_string _ms; _ms.len = _b.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _b.data(), _ms.len); return _ms; } int QIODevice_OpenMode(const QIODevice* self) { QIODevice::OpenMode _ret = self->openMode(); return static_cast(_ret); } void QIODevice_SetTextModeEnabled(QIODevice* self, bool enabled) { self->setTextModeEnabled(enabled); } bool QIODevice_IsTextModeEnabled(const QIODevice* self) { return self->isTextModeEnabled(); } bool QIODevice_IsOpen(const QIODevice* self) { return self->isOpen(); } bool QIODevice_IsReadable(const QIODevice* self) { return self->isReadable(); } bool QIODevice_IsWritable(const QIODevice* self) { return self->isWritable(); } bool QIODevice_IsSequential(const QIODevice* self) { return self->isSequential(); } int QIODevice_ReadChannelCount(const QIODevice* self) { return self->readChannelCount(); } int QIODevice_WriteChannelCount(const QIODevice* self) { return self->writeChannelCount(); } int QIODevice_CurrentReadChannel(const QIODevice* self) { return self->currentReadChannel(); } void QIODevice_SetCurrentReadChannel(QIODevice* self, int channel) { self->setCurrentReadChannel(static_cast(channel)); } int QIODevice_CurrentWriteChannel(const QIODevice* self) { return self->currentWriteChannel(); } void QIODevice_SetCurrentWriteChannel(QIODevice* self, int channel) { self->setCurrentWriteChannel(static_cast(channel)); } bool QIODevice_Open(QIODevice* self, int mode) { return self->open(static_cast(mode)); } void QIODevice_Close(QIODevice* self) { self->close(); } long long QIODevice_Pos(const QIODevice* self) { qint64 _ret = self->pos(); return static_cast(_ret); } long long QIODevice_Size(const QIODevice* self) { qint64 _ret = self->size(); return static_cast(_ret); } bool QIODevice_Seek(QIODevice* self, long long pos) { return self->seek(static_cast(pos)); } bool QIODevice_AtEnd(const QIODevice* self) { return self->atEnd(); } bool QIODevice_Reset(QIODevice* self) { return self->reset(); } long long QIODevice_BytesAvailable(const QIODevice* self) { qint64 _ret = self->bytesAvailable(); return static_cast(_ret); } long long QIODevice_BytesToWrite(const QIODevice* self) { qint64 _ret = self->bytesToWrite(); return static_cast(_ret); } long long QIODevice_Read(QIODevice* self, char* data, long long maxlen) { qint64 _ret = self->read(data, static_cast(maxlen)); return static_cast(_ret); } struct miqt_string QIODevice_ReadWithMaxlen(QIODevice* self, long long maxlen) { QByteArray _qb = self->read(static_cast(maxlen)); struct miqt_string _ms; _ms.len = _qb.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _qb.data(), _ms.len); return _ms; } struct miqt_string QIODevice_ReadAll(QIODevice* self) { QByteArray _qb = self->readAll(); struct miqt_string _ms; _ms.len = _qb.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _qb.data(), _ms.len); return _ms; } long long QIODevice_ReadLine(QIODevice* self, char* data, long long maxlen) { qint64 _ret = self->readLine(data, static_cast(maxlen)); return static_cast(_ret); } struct miqt_string QIODevice_ReadLine2(QIODevice* self) { QByteArray _qb = self->readLine(); struct miqt_string _ms; _ms.len = _qb.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _qb.data(), _ms.len); return _ms; } bool QIODevice_CanReadLine(const QIODevice* self) { return self->canReadLine(); } void QIODevice_StartTransaction(QIODevice* self) { self->startTransaction(); } void QIODevice_CommitTransaction(QIODevice* self) { self->commitTransaction(); } void QIODevice_RollbackTransaction(QIODevice* self) { self->rollbackTransaction(); } bool QIODevice_IsTransactionStarted(const QIODevice* self) { return self->isTransactionStarted(); } long long QIODevice_Write(QIODevice* self, const char* data, long long lenVal) { qint64 _ret = self->write(data, static_cast(lenVal)); return static_cast(_ret); } long long QIODevice_WriteWithData(QIODevice* self, const char* data) { qint64 _ret = self->write(data); return static_cast(_ret); } long long QIODevice_Write2(QIODevice* self, struct miqt_string data) { QByteArray data_QByteArray(data.data, data.len); qint64 _ret = self->write(data_QByteArray); return static_cast(_ret); } long long QIODevice_Peek(QIODevice* self, char* data, long long maxlen) { qint64 _ret = self->peek(data, static_cast(maxlen)); return static_cast(_ret); } struct miqt_string QIODevice_PeekWithMaxlen(QIODevice* self, long long maxlen) { QByteArray _qb = self->peek(static_cast(maxlen)); struct miqt_string _ms; _ms.len = _qb.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _qb.data(), _ms.len); return _ms; } long long QIODevice_Skip(QIODevice* self, long long maxSize) { qint64 _ret = self->skip(static_cast(maxSize)); return static_cast(_ret); } bool QIODevice_WaitForReadyRead(QIODevice* self, int msecs) { return self->waitForReadyRead(static_cast(msecs)); } bool QIODevice_WaitForBytesWritten(QIODevice* self, int msecs) { return self->waitForBytesWritten(static_cast(msecs)); } void QIODevice_UngetChar(QIODevice* self, char c) { self->ungetChar(static_cast(c)); } bool QIODevice_PutChar(QIODevice* self, char c) { return self->putChar(static_cast(c)); } bool QIODevice_GetChar(QIODevice* self, char* c) { return self->getChar(c); } struct miqt_string QIODevice_ErrorString(const QIODevice* self) { QString _ret = self->errorString(); // Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory QByteArray _b = _ret.toUtf8(); struct miqt_string _ms; _ms.len = _b.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _b.data(), _ms.len); return _ms; } void QIODevice_ReadyRead(QIODevice* self) { self->readyRead(); } void QIODevice_connect_ReadyRead(QIODevice* self, intptr_t slot) { MiqtVirtualQIODevice::connect(self, static_cast(&QIODevice::readyRead), self, [=]() { miqt_exec_callback_QIODevice_ReadyRead(slot); }); } void QIODevice_ChannelReadyRead(QIODevice* self, int channel) { self->channelReadyRead(static_cast(channel)); } void QIODevice_connect_ChannelReadyRead(QIODevice* self, intptr_t slot) { MiqtVirtualQIODevice::connect(self, static_cast(&QIODevice::channelReadyRead), self, [=](int channel) { int sigval1 = channel; miqt_exec_callback_QIODevice_ChannelReadyRead(slot, sigval1); }); } void QIODevice_BytesWritten(QIODevice* self, long long bytes) { self->bytesWritten(static_cast(bytes)); } void QIODevice_connect_BytesWritten(QIODevice* self, intptr_t slot) { MiqtVirtualQIODevice::connect(self, static_cast(&QIODevice::bytesWritten), self, [=](qint64 bytes) { qint64 bytes_ret = bytes; long long sigval1 = static_cast(bytes_ret); miqt_exec_callback_QIODevice_BytesWritten(slot, sigval1); }); } void QIODevice_ChannelBytesWritten(QIODevice* self, int channel, long long bytes) { self->channelBytesWritten(static_cast(channel), static_cast(bytes)); } void QIODevice_connect_ChannelBytesWritten(QIODevice* self, intptr_t slot) { MiqtVirtualQIODevice::connect(self, static_cast(&QIODevice::channelBytesWritten), self, [=](int channel, qint64 bytes) { int sigval1 = channel; qint64 bytes_ret = bytes; long long sigval2 = static_cast(bytes_ret); miqt_exec_callback_QIODevice_ChannelBytesWritten(slot, sigval1, sigval2); }); } void QIODevice_AboutToClose(QIODevice* self) { self->aboutToClose(); } void QIODevice_connect_AboutToClose(QIODevice* self, intptr_t slot) { MiqtVirtualQIODevice::connect(self, static_cast(&QIODevice::aboutToClose), self, [=]() { miqt_exec_callback_QIODevice_AboutToClose(slot); }); } void QIODevice_ReadChannelFinished(QIODevice* self) { self->readChannelFinished(); } void QIODevice_connect_ReadChannelFinished(QIODevice* self, intptr_t slot) { MiqtVirtualQIODevice::connect(self, static_cast(&QIODevice::readChannelFinished), self, [=]() { miqt_exec_callback_QIODevice_ReadChannelFinished(slot); }); } struct miqt_string QIODevice_Tr2(const char* s, const char* c) { QString _ret = QIODevice::tr(s, c); // Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory QByteArray _b = _ret.toUtf8(); struct miqt_string _ms; _ms.len = _b.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _b.data(), _ms.len); return _ms; } struct miqt_string QIODevice_Tr3(const char* s, const char* c, int n) { QString _ret = QIODevice::tr(s, c, static_cast(n)); // Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory QByteArray _b = _ret.toUtf8(); struct miqt_string _ms; _ms.len = _b.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _b.data(), _ms.len); return _ms; } struct miqt_string QIODevice_TrUtf82(const char* s, const char* c) { QString _ret = QIODevice::trUtf8(s, c); // Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory QByteArray _b = _ret.toUtf8(); struct miqt_string _ms; _ms.len = _b.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _b.data(), _ms.len); return _ms; } struct miqt_string QIODevice_TrUtf83(const char* s, const char* c, int n) { QString _ret = QIODevice::trUtf8(s, c, static_cast(n)); // Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory QByteArray _b = _ret.toUtf8(); struct miqt_string _ms; _ms.len = _b.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _b.data(), _ms.len); return _ms; } struct miqt_string QIODevice_ReadLine1(QIODevice* self, long long maxlen) { QByteArray _qb = self->readLine(static_cast(maxlen)); struct miqt_string _ms; _ms.len = _qb.length(); _ms.data = static_cast(malloc(_ms.len)); memcpy(_ms.data, _qb.data(), _ms.len); return _ms; } void QIODevice_override_virtual_IsSequential(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__IsSequential = slot; } bool QIODevice_virtualbase_IsSequential(const void* self) { return ( (const MiqtVirtualQIODevice*)(self) )->virtualbase_IsSequential(); } void QIODevice_override_virtual_Open(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__Open = slot; } bool QIODevice_virtualbase_Open(void* self, int mode) { return ( (MiqtVirtualQIODevice*)(self) )->virtualbase_Open(mode); } void QIODevice_override_virtual_Close(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__Close = slot; } void QIODevice_virtualbase_Close(void* self) { ( (MiqtVirtualQIODevice*)(self) )->virtualbase_Close(); } void QIODevice_override_virtual_Pos(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__Pos = slot; } long long QIODevice_virtualbase_Pos(const void* self) { return ( (const MiqtVirtualQIODevice*)(self) )->virtualbase_Pos(); } void QIODevice_override_virtual_Size(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__Size = slot; } long long QIODevice_virtualbase_Size(const void* self) { return ( (const MiqtVirtualQIODevice*)(self) )->virtualbase_Size(); } void QIODevice_override_virtual_Seek(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__Seek = slot; } bool QIODevice_virtualbase_Seek(void* self, long long pos) { return ( (MiqtVirtualQIODevice*)(self) )->virtualbase_Seek(pos); } void QIODevice_override_virtual_AtEnd(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__AtEnd = slot; } bool QIODevice_virtualbase_AtEnd(const void* self) { return ( (const MiqtVirtualQIODevice*)(self) )->virtualbase_AtEnd(); } void QIODevice_override_virtual_Reset(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__Reset = slot; } bool QIODevice_virtualbase_Reset(void* self) { return ( (MiqtVirtualQIODevice*)(self) )->virtualbase_Reset(); } void QIODevice_override_virtual_BytesAvailable(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__BytesAvailable = slot; } long long QIODevice_virtualbase_BytesAvailable(const void* self) { return ( (const MiqtVirtualQIODevice*)(self) )->virtualbase_BytesAvailable(); } void QIODevice_override_virtual_BytesToWrite(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__BytesToWrite = slot; } long long QIODevice_virtualbase_BytesToWrite(const void* self) { return ( (const MiqtVirtualQIODevice*)(self) )->virtualbase_BytesToWrite(); } void QIODevice_override_virtual_CanReadLine(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__CanReadLine = slot; } bool QIODevice_virtualbase_CanReadLine(const void* self) { return ( (const MiqtVirtualQIODevice*)(self) )->virtualbase_CanReadLine(); } void QIODevice_override_virtual_WaitForReadyRead(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__WaitForReadyRead = slot; } bool QIODevice_virtualbase_WaitForReadyRead(void* self, int msecs) { return ( (MiqtVirtualQIODevice*)(self) )->virtualbase_WaitForReadyRead(msecs); } void QIODevice_override_virtual_WaitForBytesWritten(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__WaitForBytesWritten = slot; } bool QIODevice_virtualbase_WaitForBytesWritten(void* self, int msecs) { return ( (MiqtVirtualQIODevice*)(self) )->virtualbase_WaitForBytesWritten(msecs); } void QIODevice_override_virtual_ReadData(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__ReadData = slot; } void QIODevice_override_virtual_ReadLineData(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__ReadLineData = slot; } long long QIODevice_virtualbase_ReadLineData(void* self, char* data, long long maxlen) { return ( (MiqtVirtualQIODevice*)(self) )->virtualbase_ReadLineData(data, maxlen); } void QIODevice_override_virtual_WriteData(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__WriteData = slot; } void QIODevice_override_virtual_Event(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__Event = slot; } bool QIODevice_virtualbase_Event(void* self, QEvent* event) { return ( (MiqtVirtualQIODevice*)(self) )->virtualbase_Event(event); } void QIODevice_override_virtual_EventFilter(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__EventFilter = slot; } bool QIODevice_virtualbase_EventFilter(void* self, QObject* watched, QEvent* event) { return ( (MiqtVirtualQIODevice*)(self) )->virtualbase_EventFilter(watched, event); } void QIODevice_override_virtual_TimerEvent(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__TimerEvent = slot; } void QIODevice_virtualbase_TimerEvent(void* self, QTimerEvent* event) { ( (MiqtVirtualQIODevice*)(self) )->virtualbase_TimerEvent(event); } void QIODevice_override_virtual_ChildEvent(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__ChildEvent = slot; } void QIODevice_virtualbase_ChildEvent(void* self, QChildEvent* event) { ( (MiqtVirtualQIODevice*)(self) )->virtualbase_ChildEvent(event); } void QIODevice_override_virtual_CustomEvent(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__CustomEvent = slot; } void QIODevice_virtualbase_CustomEvent(void* self, QEvent* event) { ( (MiqtVirtualQIODevice*)(self) )->virtualbase_CustomEvent(event); } void QIODevice_override_virtual_ConnectNotify(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__ConnectNotify = slot; } void QIODevice_virtualbase_ConnectNotify(void* self, QMetaMethod* signal) { ( (MiqtVirtualQIODevice*)(self) )->virtualbase_ConnectNotify(signal); } void QIODevice_override_virtual_DisconnectNotify(void* self, intptr_t slot) { dynamic_cast( (QIODevice*)(self) )->handle__DisconnectNotify = slot; } void QIODevice_virtualbase_DisconnectNotify(void* self, QMetaMethod* signal) { ( (MiqtVirtualQIODevice*)(self) )->virtualbase_DisconnectNotify(signal); } void QIODevice_Delete(QIODevice* self, bool isSubclass) { if (isSubclass) { delete dynamic_cast( self ); } else { delete self; } }