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The Custom Script Class example shows how to use QScriptClass and QScriptClassPropertyIterator to implement a custom script class.
The script class we are going to implement is called ByteArray. It provides a wrapper around the QByteArray class in Qt, with a simplified API. Why do we need such a class? Well, neither the ECMAScript Array class or String class is appropriate to use when working with arrays of bytes. Our ByteArray class will have the right semantics; objects will use only the amount of memory that is really needed (a byte is stored as a byte, not as a floating-point number or a Unicode character) and can be passed directly to C++ slots taking QByteArray arguments (no costly conversion necessary).
When the ByteArray class has been made available to the scripting environment, ByteArray objects can be constructed like so:
var ba = new ByteArray(); // constructs an empty ByteArray var ba2 = new ByteArray(10); // constructs a ByteArray of length 10 (all bytes initialized to 0)
ByteArray objects behave similar to normal Array objects. Every ByteArray object has a length property, that holds the length of the array. If a new value is assigned to the length property, the array is resized. If the array is enlarged, the new bytes are initialized to 0. (This is a difference from normal Array objects; ByteArray objects are always dense arrays.) Use normal array operations to read or write bytes in the array. The following code sets all the bytes of an array to a certain value:
for (var i = 0; i < ba.length; ++i) ba[i] = 123;
When assigning a value to an array element, the value is truncated to eight bits:
ba[0] = 257; print(ba[0]); // 1
Like normal Array objects, if the array index is greater than the current length of the array, the array is resized accordingly:
var ba3 = new ByteArray(); print(ba3.length); // 0 ba[0] = 64; print(ba3.length); // 1
Property names that aren't valid array indexes are treated like normal object properties (again, the same is the case for normal Array objects); in other words, it's perfectly fine to do something like this:
ba["foo"] = "Hello";
The above assignment won't affect the contents of the array, but will rather assign a value to the object property named "foo".
ByteArray objects have a set of methods: chop(), equals(), left(), mid(), toBase64() and so on. These map directly onto the corresponding methods in QByteArray.
var ba64 = ba.toBase64(); print(ba64.toLatin1String());
To implement the ByteArray script class in C++, we create a subclass of QScriptClass, called ByteArrayClass, and reimplement the virtual functions from QScriptClass. We also provide a Qt Script constructor function suitable for being added to a QScriptEngine's environment.
The ByteArrayClass constructor prepares the script class:
ByteArrayClass::ByteArrayClass(QScriptEngine *engine) : QObject(engine), QScriptClass(engine) { qScriptRegisterMetaType<QByteArray>(engine, toScriptValue, fromScriptValue); length = engine->toStringHandle(QLatin1String("length")); proto = engine->newQObject(new ByteArrayPrototype(this), QScriptEngine::QtOwnership, QScriptEngine::SkipMethodsInEnumeration | QScriptEngine::ExcludeSuperClassMethods | QScriptEngine::ExcludeSuperClassProperties); QScriptValue global = engine->globalObject(); proto.setPrototype(global.property("Object").property("prototype")); ctor = engine->newFunction(construct); ctor.setData(qScriptValueFromValue(engine, this)); }
First, the constructor registers a pair of conversion functions, so that C++ QByteArray objects and Qt Script ByteArray objects can move seamlessly between the C++ side and the script side. For example, if a ByteArray object is passed to a C++ slot that takes a QByteArray argument, the actual QByteArray that the ByteArray object wraps will be passed correctly.
Second, we store a handle to the string "length", so that we can quickly compare a given property name to "length" later on.
Third, we initialize the standard ByteArray prototype, to be returned by our prototype() reimplementation later on. (The implementation of the prototype is discussed later.)
Fourth, we initialize a constructor function for ByteArray, to be returned by the constructor() function. We set the internal data of the constructor to be a pointer to this ByteArrayClass object, so that the constructor, when it is invoked, can extract the pointer and use it to create a new ByteArray object.
QScriptValue ByteArrayClass::newInstance(const QByteArray &ba) { QScriptValue data = engine()->newVariant(qVariantFromValue(ba)); return engine()->newObject(this, data); }
The newInstance() function isn't part of the QScriptClass API; its purpose is to offer a convenient way to construct a ByteArray object from an existing QByteArray. We store the QByteArray as the internal data of the new object, and return the new object. QScriptEngine::newObject() will call the prototype() function of our class, ensuring that the prototype of the new object will be the standard ByteArray prototype.
QScriptValue ByteArrayClass::construct(QScriptContext *ctx, QScriptEngine *) { ByteArrayClass *cls = qscriptvalue_cast<ByteArrayClass*>(ctx->callee().data()); if (!cls) return QScriptValue(); int size = ctx->argument(0).toInt32(); return cls->newInstance(size); }
construct() is the native function that will act as a constructor for ByteArray in scripts. We extract the pointer to the class, then call a newInstance() overload that takes an initial size as argument, and return the new script object.
QScriptClass::QueryFlags ByteArrayClass::queryProperty(const QScriptValue &object, const QScriptString &name, QueryFlags flags, uint *id) { QByteArray *ba = qscriptvalue_cast<QByteArray*>(object.data()); if (!ba) return 0; if (name == length) { return flags; } else { qint32 pos = toArrayIndex(name); if (pos == -1) return 0; *id = pos; if ((flags & HandlesReadAccess) && (pos >= ba->size())) flags &= ~HandlesReadAccess; return flags; } }
queryProperty() is the function that Qt Script will call whenever someone tries to access a property of a ByteArray object. We first get a pointer to the underlying QByteArray. We check if the property being accessed is the special length property; if so, we return, indicating that we will handle every kind of access to this property (e.g. both read and write). Otherwise, we attempt to convert the property name to an array index. If this fails, we return, indicating that we don't want to handle this property. Otherwise, we have a valid array index, and store it in the id argument, so that we don't have to recompute it in e.g. property() or setProperty(). If the index is greater than or equal to the QByteArray's size, we indicate that we don't want to handle read access (but we still want to handle writes, if requested).
QScriptValue ByteArrayClass::property(const QScriptValue &object, const QScriptString &name, uint id) { QByteArray *ba = qscriptvalue_cast<QByteArray*>(object.data()); if (!ba) return QScriptValue(); if (name == length) { return QScriptValue(engine(), ba->length()); } else { qint32 pos = id; if ((pos < 0) || (pos >= ba->size())) return QScriptValue(); return QScriptValue(engine(), uint(ba->at(pos)) & 255); } return QScriptValue(); }
In the property() reimplementation, we do similar checks as in queryProperty() to find out which property is being requested, and then return the value of that property.
void ByteArrayClass::setProperty(QScriptValue &object, const QScriptString &name, uint id, const QScriptValue &value) { QByteArray *ba = qscriptvalue_cast<QByteArray*>(object.data()); if (!ba) return; if (name == length) { ba->resize(value.toInt32()); } else { qint32 pos = id; if (pos < 0) return; if (ba->size() <= pos) ba->resize(pos + 1); (*ba)[pos] = char(value.toInt32()); } }
The setProperty() reimplementation has a structure that is similar to property(). If the length property is being set, we resize the underlying QByteArray to the given length. Otherwise, we grab the array index that was calculated in the queryProperty() function, enlarge the array if necessary, and write the given value to the array.
QScriptValue::PropertyFlags ByteArrayClass::propertyFlags( const QScriptValue &/*object*/, const QScriptString &name, uint /*id*/) { if (name == length) { return QScriptValue::Undeletable | QScriptValue::SkipInEnumeration; } return QScriptValue::Undeletable; }
The propertyFlags() reimplementation specifies that the length property can't be deleted, and that it is not enumerable. Array elements can't be deleted.
QScriptClassPropertyIterator *ByteArrayClass::newIterator(const QScriptValue &object) { return new ByteArrayClassPropertyIterator(object); }
We want the array elements to show up when a ByteArray object is used in for-in statements and together with QScriptValueIterator. Therefore, we reimplement the newIterator() function and have it return a new iterator for a given ByteArray.
bool ByteArrayClassPropertyIterator::hasNext() const { QByteArray *ba = qscriptvalue_cast<QByteArray*>(object().data()); return m_index < ba->size(); } void ByteArrayClassPropertyIterator::next() { m_last = m_index; ++m_index; } bool ByteArrayClassPropertyIterator::hasPrevious() const { return (m_index > 0); } void ByteArrayClassPropertyIterator::previous() { --m_index; m_last = m_index; } void ByteArrayClassPropertyIterator::toFront() { m_index = 0; m_last = -1; } void ByteArrayClassPropertyIterator::toBack() { QByteArray *ba = qscriptvalue_cast<QByteArray*>(object().data()); m_index = ba->size(); m_last = -1; } QScriptString ByteArrayClassPropertyIterator::name() const { return QScriptString(); } uint ByteArrayClassPropertyIterator::id() const { return m_last; }
The ByteArrayClassPropertyIterator class is simple. It maintains an index into the underlying QByteArray, and checks and updates the index in hasNext(), next() and so on.
The prototype class, ByteArrayPrototype, implements the ByteArray functions as slots.
class ByteArrayPrototype : public QObject, public QScriptable { Q_OBJECT public: ByteArrayPrototype(QObject *parent = 0); ~ByteArrayPrototype(); public slots: void chop(int n); bool equals(const QByteArray &other); QByteArray left(int len) const; QByteArray mid(int pos, int len = -1) const; QScriptValue remove(int pos, int len); QByteArray right(int len) const; QByteArray simplified() const; QByteArray toBase64() const; QByteArray toLower() const; QByteArray toUpper() const; QByteArray trimmed() const; void truncate(int pos); QString toLatin1String() const; QScriptValue valueOf() const; private: QByteArray *thisByteArray() const; };
There is a small helper function, thisByteArray(), that returns a pointer to the QByteArray being operated upon:
QByteArray *ByteArrayPrototype::thisByteArray() const { return qscriptvalue_cast<QByteArray*>(thisObject().data()); }
The slots simply forward the calls to the QByteArray. Examples:
QByteArray ByteArrayPrototype::mid(int pos, int len) const { return thisByteArray()->mid(pos, len); } QScriptValue ByteArrayPrototype::remove(int pos, int len) { thisByteArray()->remove(pos, len); return thisObject(); }
The remove() function is noteworthy; if we look at QByteArray::remove(), we see that it should return a reference to the QByteArray itself (i.e. not a copy). To get the same behavior in scripts, we return the script object (thisObject()).
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