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TQObject, the base class of all TQt objects, provides the basic timer support in TQt. With TQObject::startTimer(), you start a timer with an interval in milliseconds as argument. The function returns a unique integer timer id. The timer will now "fire" every interval milliseconds, until you explicitly call TQObject::killTimer() with the timer id.
For this mechanism to work, the application must run in an event loop. You start an event loop with TQApplication::exec(). When a timer fires, the application sends a TQTimerEvent, and the flow of control leaves the event loop until the timer event is processed. This implies that a timer cannot fire while your application is busy doing something else. In other words: the accuracy of timers depends on the granularity of your application.
There is practically no upper limit for the interval value (more than one year is possible). The accuracy depends on the underlying operating system. Windows 95/98 has 55 millisecond (18.2 times per second) accuracy; other systems that we have tested (UNIX X11 and Windows NT) can handle 1 millisecond intervals.
The main API for the timer functionality is TQTimer. That class provides regular timers that emit a signal when the timer fires, and inherits TQObject so that it fits well into the ownership structure of most GUI programs. The normal way of using it is like this:
TQTimer * counter = new TQTimer( this ); connect( counter, TQ_SIGNAL(timeout()), this, TQ_SLOT(updateCaption()) ); counter->start( 1000 );
The counter timer is made into a child of this widget, so that when this widget is deleted, the timer is deleted too. Next, its timeout signal is connected to the slot that will do the work, and finally it's started.
TQTimer also provides a simple one-shot timer API. TQButton uses this to show the button being pressed down and then (0.1 seconds later) be released when the keyboard is used to "press" a button, for example:
TQTimer::singleShot( 100, this, TQ_SLOT(animateTimeout()) );
0.1 seconds after this line of code is executed, the same button's animateTimeout() slot is called.
Here is an outline of a slightly longer example that combines object communication via signals and slots with a TQTimer object. It demonstrates how to use timers to perform intensive calculations in a single-threaded application without blocking the user interface.
// The Mandelbrot class uses a TQTimer to calculate the mandelbrot // set one scanline at a time without blocking the CPU. It // inherits TQObject to use signals and slots. Calling start() // starts the calculation. The done() signal is emitted when it // has finished. Note that this example is not complete, just an // outline. class Mandelbrot : public TQObject { TQ_OBJECT // required for signals/slots public: Mandelbrot( TQObject *parent=0, const char *name ); ... public slots: void start(); signals: void done(); private slots: void calculate(); private: TQTimer timer; ... }; // // Constructs and initializes a Mandelbrot object. // Mandelbrot::Mandelbrot( TQObject *parent=0, const char *name ) : TQObject( parent, name ) { connect( &timer, TQ_SIGNAL(timeout()), TQ_SLOT(calculate()) ); ... } // // Starts the calculation task. The internal calculate() slot // will be activated every 10 milliseconds. // void Mandelbrot::start() { if ( !timer.isActive() ) // not already running timer.start( 10 ); // timeout every 10 ms } // // Calculates one scanline at a time. // Emits the done() signal when finished. // void Mandelbrot::calculate() { ... // perform the calculation for a scanline if ( finished ) { // no more scanlines timer.stop(); emit done(); } }
Copyright © 2007 Trolltech | Trademarks | TQt 3.3.8
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