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Custom IO Device
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Writing a Custom I/O Device
This is a port of the article in Qt Quarterly 12 about writing a custom QIODevice
- Note: a more complex example can be found here Simple_Crypt_IO_Device
Usage:
The following code snippet shows how we would use the custom I/O device to encrypt data and store the result in a file:
QFile file("output.dat");
CryptDevice cryptDevice(&file)
QTextStream out(&cryptDevice);
cryptDevice.open(QIODevice::WriteOnly);
out << "Hello World";
And on the possible usage (in our example code in git [1])
Encryption
QByteArray dataArray;
QBuffer bufferUsedLikeAFile(&dataArray);
CryptDevice deviceFilter(&bufferUsedLikeAFile);
deviceFilter.open(QIODevice::WriteOnly);
QTextStream stream(&deviceFilter);
QString szText = rawText->toPlainText();
stream << szText;
Decryption
QBuffer bufferUsedLikeAFile(&dataArray);
CryptDevice deviceFilter(&bufferUsedLikeAFile);
deviceFilter.open(QIODevice::ReadOnly);
QTextStream stream(&deviceFilter);
QString szText = stream.readAll();
decryptedText->setPlainText(szText);
Example image of the test app:
The Custom I/O Device
Writing a custom QIODevice class in Qt 4 involves inheriting QIODevice and then reimplementing a set of virtual functions.
There is a big difference regarding writing a custom IO device compared to Qt 3: you only have to rewrite 2 functions:
- qint64 QIODevice::readData ( char * data, qint64 maxSize )
- qint64 QIODevice::writeData ( const char * data, qint64 maxSize )
Our CryptDevice class will be a sequential I/O device. Whether it's synchronous or asynchronous depends on the underlying QIODevice.
Source Code
The class definition looks like this:
class CryptDevice : public QIODevice
{
Q_OBJECT
public:
CryptDevice(QIODevice* deviceToUse, QObject* parent = 0);
bool open(OpenMode mode);
void close();
bool isSequential() const;
protected:
qint64 readData(char* data, qint64 maxSize);
qint64 writeData(const char* data, qint64 maxSize);
private:
QIODevice* underlyingDevice;
Q_DISABLE_COPY(CryptDevice)
};
The constructor definition is pretty straightforward
CryptDevice::CryptDevice(QIODevice* deviceToUse, QObject* parent) :
QIODevice(parent),
underlyingDevice(deviceToUse)
{
}
As our device should be sequential, we re-implement isSequential
bool CryptDevice::isSequential() const
{
return true;
}
In
open()
, we open the underlying device if it's not already open and set the device state to mode.
bool CryptDevice::open(OpenMode mode)
{
bool underlyingOk;
if (underlyingDevice->isOpen())
underlyingOk = (underlyingDevice->openMode() != mode);
else
underlyingOk = underlyingDevice->open(mode);
if (underlyingOk)
{
setOpenMode(mode);
return true;
}
return false;
}
Closing is trivial.
void CryptDevice::close()
{
underlyingDevice->close();
setOpenMode(NotOpen);
}
When reading a block, we call
read()
on the underlying device. At the end, we XOR each byte read from the device with the magic constant 0x5E.
qint64 CryptDevice::readData(char* data, qint64 maxSize)
{
qint64 deviceRead = underlyingDevice->read(data, maxSize);
if (deviceRead == –1)
return -1;
for (qint64 i = 0; i < deviceRead; +''i)
data[i] = data[i] ^ 0x5E;
return deviceRead;
}
When writing a block, we create a temporary buffer with the XOR'd data. A more efficient implementation would use a 4096-byte buffer on the stack and call
write()
multiple times if size is larger than the buffer.
qint64 CryptDevice::writeData(const char* data, qint64 maxSize)
{
QByteArray buffer((int)maxSize, 0);
for (int i = 0; i < (int)maxSize;''+i)
buffer[i] = data[i] ^ 0x5E;
return underlyingDevice->write(buffer.data(), maxSize);
}