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/****************************************************************************
**
** Copyright (C) 1992-2008 Trolltech ASA. All rights reserved.
**
** This file is part of an example program for TQt. This example
** program may be used, distributed and modified without limitation.
**
*****************************************************************************/
#include "aclock.h"
#include <ntqtimer.h>
#include <ntqpainter.h>
#include <ntqbitmap.h>
//
// Constructs an analog clock widget that uses an internal TQTimer.
//
AnalogClock::AnalogClock( TQWidget *parent, const char *name )
: TQWidget( parent, name )
{
time = TQTime::currentTime(); // get current time
internalTimer = new TQTimer( this ); // create internal timer
connect( internalTimer, SIGNAL(timeout()), SLOT(timeout()) );
internalTimer->start( 5000 ); // emit signal every 5 seconds
}
void AnalogClock::mousePressEvent( TQMouseEvent *e )
{
if(isTopLevel())
clickPos = e->pos() + TQPoint(geometry().topLeft() - frameGeometry().topLeft());
}
void AnalogClock::mouseMoveEvent( TQMouseEvent *e )
{
if(isTopLevel())
move( e->globalPos() - clickPos );
}
//
// The TQTimer::timeout() signal is received by this slot.
//
//
// When we set an explicit time we don't want the timeout() slot to be
// called anymore as this relies on currentTime()
//
void AnalogClock::setTime( const TQTime & t )
{
time = t;
disconnect( internalTimer, SIGNAL(timeout()), this, SLOT(timeout()) );
if (autoMask())
updateMask();
else
update();
}
void AnalogClock::timeout()
{
TQTime old_time = time;
time = TQTime::currentTime();
if ( old_time.minute() != time.minute()
|| old_time.hour() != time.hour() ) { // minute or hour has changed
if (autoMask())
updateMask();
else
update();
}
}
void AnalogClock::paintEvent( TQPaintEvent * )
{
if ( autoMask() )
return;
TQPainter paint( this );
paint.setBrush( colorGroup().foreground() );
drawClock( &paint );
}
// If the clock is transparent, we use updateMask()
// instead of paintEvent()
void AnalogClock::updateMask() // paint clock mask
{
TQBitmap bm( size() );
bm.fill( color0 ); //transparent
TQPainter paint;
paint.begin( &bm, this );
paint.setBrush( color1 ); // use non-transparent color
paint.setPen( color1 );
drawClock( &paint );
paint.end();
setMask( bm );
}
//
// The clock is painted using a 1000x1000 square coordinate system, in
// the a centered square, as big as possible. The painter's pen and
// brush colors are used.
//
void AnalogClock::drawClock( TQPainter *paint )
{
paint->save();
paint->setWindow( -500,-500, 1000,1000 );
TQRect v = paint->viewport();
int d = TQMIN( v.width(), v.height() );
paint->setViewport( v.left() + (v.width()-d)/2,
v.top() + (v.height()-d)/2, d, d );
TQPointArray pts;
paint->save();
paint->rotate( 30*(time.hour()%12-3) + time.minute()/2 );
pts.setPoints( 4, -20,0, 0,-20, 300,0, 0,20 );
paint->drawConvexPolygon( pts );
paint->restore();
paint->save();
paint->rotate( (time.minute()-15)*6 );
pts.setPoints( 4, -10,0, 0,-10, 400,0, 0,10 );
paint->drawConvexPolygon( pts );
paint->restore();
for ( int i=0; i<12; i++ ) {
paint->drawLine( 440,0, 460,0 );
paint->rotate( 30 );
}
paint->restore();
}
void AnalogClock::setAutoMask(bool b)
{
if (b)
setBackgroundMode( PaletteForeground );
else
setBackgroundMode( PaletteBackground );
TQWidget::setAutoMask(b);
}
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