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Properties

TQt provides a sophisticated property system similar to those supplied by some compiler vendors. However, as a compiler- and platform-independent library, TQt cannot rely on non-standard compiler features like __property or [property]. Our solution works with any standard C++ compiler on every platform we support. It's based on the meta-object system that also provides object communication through signals and slots.

The Q_PROPERTY macro in a class declaration declares a property. Properties can only be declared in classes that inherit TQObject. A second macro, Q_OVERRIDE, can be used to override some aspects of an inherited property in a subclass. (See Q_OVERRIDE.)

To the outer world, a property appears to be similar to a data member. But properties have several features that distinguish them from ordinary data members:

The read, write, and reset functions must be public member functions from the class in which the property is defined.

Properties can be read and written through generic functions in TQObject without knowing anything about the class in use. These two function calls are equivalent:

    // TQButton *b and TQObject *o point to the same button
    b->setDown( TRUE );
    o->setProperty( "down", TRUE );

Equivalent, that is, except that the first is faster, and provides much better diagnostics at compile time. When practical, the first is better. However, since you can get a list of all available properties for any TQObject through its TQMetaObject, TQObject::setProperty() can give you control over classes that weren't available at compile time.

As well as TQObject::setProperty(), there is a corresponding TQObject::property() function. TQMetaObject::propertyNames() returns the names of all available properties. TQMetaObject::property() returns the property data for a named property: a TQMetaProperty object.

Here's a simple example that shows the most important property functions in use:

    class MyClass : public TQObject
    {
        TQ_OBJECT
    public:
        MyClass( TQObject * parent=0, const char * name=0 );
        ~MyClass();

        enum Priority { High, Low, VeryHigh, VeryLow };
        void setPriority( Priority );
        Priority priority() const;
    };

The class has a property "priority" that is not yet known to the meta object system. In order to make the property known, you must declare it with the Q_PROPERTY macro. The syntax is as follows:

Q_PROPERTY( type name READ getFunction [WRITE setFunction]
            [RESET resetFunction] [DESIGNABLE bool] 
            [SCRIPTABLE bool] [STORED bool] )

For the declaration to be valid, the get function must be const and to return either the type itself, a pointer to it, or a reference to it. The optional write function must return void and must take exactly one argument, either the type itself, a pointer or a const reference to it. The meta object compiler enforces this.

The type of a property can be any TQVariant supported type or an enumeration type declared in the class itself. Since MyClass uses the enumeration type Priority for the property, this type must be registered with the property system as well.

There are two exceptions to the above: The type of a property can also be either TQValueList<TQVariant> or TQMap<TQString,TQVariant>. In these cases the type must be specified as TQValueList or as TQMap (i.e. without their template parameters).

It is possible to set a value by name, like this:

    obj->setProperty( "priority", "VeryHigh" );
In the case of TQValueList and TQMap properties the value passes is a TQVariant whose value is the entire list or map.

Enumeration types are registered with the Q_ENUMS macro. Here's the final class declaration including the property related declarations:

    class MyClass : public TQObject
    {
        TQ_OBJECT
        Q_PROPERTY( Priority priority READ priority WRITE setPriority )
        Q_ENUMS( Priority )
    public:
        MyClass( TQObject * parent=0, const char * name=0 );
        ~MyClass();

        enum Priority { High, Low, VeryHigh, VeryLow };
        void setPriority( Priority );
        Priority priority() const;
    };

Another similar macro is Q_SETS. Like Q_ENUMS, it registers an enumeration type but marks it in addition as a "set", i.e. the enumeration values can be OR-ed together. An I/O class might have enumeration values "Read" and "Write" and accept "Read|Write": such an enum is best handled with Q_SETS, rather than Q_ENUMS.

The remaining keywords in the Q_PROPERTY section are RESET, DESIGNABLE, SCRIPTABLE and STORED.

RESET names a function that will set the property to its default state (which may have changed since initialization). The function must return void and take no arguments.

DESIGNABLE declares whether this property is suitable for modification by a GUI design tool. The default is TRUE for writable properties; otherwise FALSE. Instead of TRUE or FALSE, you can specify a boolean member function.

SCRIPTABLE declares whether this property is suited for access by a scripting engine. The default is TRUE. Instead of TRUE or FALSE, you can specify a boolean member function.

STORED declares whether the property's value must be remembered when storing an object's state. Stored makes only sense for writable properties. The default value is TRUE. Technically superfluous properties (like TQPoint pos if TQRect geometry is already a property) define this to be FALSE.

Connected to the property system is an additional macro, "Q_CLASSINFO", that can be used to attach additional name/value-pairs to a class' meta object, for example:

    Q_CLASSINFO( "Version", "3.0.0" )

Like other meta data, class information is accessible at runtime through the meta object, see TQMetaObject::classInfo() for details.

Q_OVERRIDE

When you inherit a TQObject subclass you may wish to override some aspects of some of the class's properties.

For example, in TQWidget we have the autoMask property defined like this:

    Q_PROPERTY( bool autoMask READ autoMask WRITE setAutoMask DESIGNABLE false SCRIPTABLE false )

But we need to make the auto mask property designable in some TQWidget subclasses. Similarly some classes will need this property to be scriptable (e.g. for TQSA). This is achieved by overriding these features of the property in a subclass. In TQCheckBox, for example, we achieve this using the following code:

    Q_OVERRIDE( bool autoMask DESIGNABLE true SCRIPTABLE true )

Another example is TQToolButton. By default TQToolButton has a read-only "toggleButton" property, because that's what it inherits from TQButton:

    Q_PROPERTY( bool toggleButton READ isToggleButton )

But we want to make our tool buttons able to be toggled, so we write a WRITE function in TQToolButton, and use the following property override to make it acessible:

    Q_OVERRIDE( bool toggleButton WRITE setToggleButton )
The result is read-write (and scriptable and designable, since we now have a WRITE function) boolean property "toggleButton" for tool buttons.


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TQt 3.3.8