In this example, we introduce a timer to implement animated shooting.
The CannonField now has a shooting capabilities.
void shoot();
Calling this slot will make the cannon shoot if a shot is not in the air.
private slots: void moveShot();
This private slot is used to move the shot while it is in the air, using a QTimer.
private: void paintShot( QPainter * );
This private function paints the shot.
QRect shotRect() const;
This private function returns the shot's enclosing rectangle if one is in the air, otherwise the returned rectangle is undefined.
int timerCount; QTimer * autoShootTimer; float shoot_ang; float shoot_f; };
These private variables contain information that describes the shot. The
timerCount
keeps track of the time passed since the shot was fired.
The shoot_ang
is the cannon angle and shoot_f
is the cannon force
when the shot was fired.
#include <math.h>
We include the math library because we need the sin() and cos() functions.
CannonField::CannonField( QWidget *parent, const char *name ) : QWidget( parent, name ) { ang = 45; f = 0; timerCount = 0; autoShootTimer = new QTimer( this, "movement handler" ); connect( autoShootTimer, SIGNAL(timeout()), this, SLOT(moveShot()) ); shoot_ang = 0; shoot_f = 0; setPalette( QPalette( QColor( 250, 250, 200) ) ); }
We initialize our new private variables and connect the QTimer::timeout() signal to our moveShot() slot. We'll move the shot every time the timer times out.
void CannonField::shoot() { if ( autoShootTimer->isActive() ) return; timerCount = 0; shoot_ang = ang; shoot_f = f; autoShootTimer->start( 50 ); }
This function shoots a shot unless a shot is in the air. The timerCount
is reset to zero. The shoot_ang
and shoot_f
are set to the current
cannon angle and force. Finally we start the timer.
void CannonField::moveShot() { QRegion r( shotRect() ); timerCount++; QRect shotR = shotRect(); if ( shotR.x() > width() || shotR.y() > height() ) autoShootTimer->stop(); else r = r.unite( QRegion( shotR ) ); repaint( r ); }
moveShot() is the slot that moves the shot, called every 50 milliseconds when the QTimer fires.
Its tasks are to compute the new position, repaint the screen with the shot in the new position, and if necessary stop the timer.
First we make a QRegion that holds the old shotRect(). A QRegion is capable of holding any sort of region, and we'll use it here to simplify the painting. shotRect() returns the rectangle where the shot is now - it is explained in detail later.
Then we increment the timerCount,
which has the effect of moving the
shot one step along its trajectory.
Next, we fetch the new shot rectangle.
If the shot has moved beyond the right or bottom edge of the widget, we stop the timer. Else, we add the new shotRect() to the QRegion.
Finally, we repaint the QRegion. This will send a single paint event, for just the one or two rectangles that need updating.
void CannonField::paintEvent( QPaintEvent *e ) { QRect updateR = e->rect(); QPainter p( this ); if ( updateR.intersects( cannonRect() ) ) paintCannon( &p ); if ( autoShootTimer->isActive() && updateR.intersects( shotRect() ) ) paintShot( &p ); }
The paint event function has been split in two since the previous chapter. Now, we fetch the bounding rectangle of the region that needs painting, check whether it intersects either the cannon and/or the shot, and if necessary call paintCannon() and/or paintShot().
void CannonField::paintShot( QPainter *p ) { p->setBrush( black ); p->setPen( NoPen ); p->drawRect( shotRect() ); }
This private function paints the shot by drawing a black filled rectangle.
We leave out the implementation of paintCannon(); it is the same as the paintEvent() from the previous chapter.
QRect CannonField::shotRect() const { const double gravity = 4; double time = timerCount / 4.0; double velocity = shoot_f; double radians = shoot_ang*3.14159265/180; double velx = velocity*cos( radians ); double vely = velocity*sin( radians ); double x0 = ( barrelRect.right() + 5 )*cos(radians); double y0 = ( barrelRect.right() + 5 )*sin(radians); double x = x0 + velx*time; double y = y0 + vely*time - 0.5*gravity*time*time; QRect r = QRect( 0, 0, 6, 6 ); r.moveCenter( QPoint( qRound(x), height() - 1 - qRound(y) ) ); return r; }
This private function calculates the center point of the shot and returns
the enclosing rectangle of the shot. It uses the initial cannon force and
angle in addition to timerCount,
which increases as time passes.
The formula used is the classical Newtonian formula for frictionless movement in a gravity field. For simplicity, we've chosen to disregard any Einsteinian effects.
We calculate the center point in a coordinate system where y coordinates increase upwards. After we have calculated the center point, we construct a QRect with size 6x6 and move its center point to the point calculated above. In the same operation, we convert the point into the widget's coordinate system (see The Coordinate System).
The qRound() function is an inline function defined in qglobal.h (included by all other Qt header files). qRound() rounds a double to the closest integer.
class MyWidget: public QWidget { public: MyWidget( QWidget *parent=0, const char *name=0 ); };
The only addition is the shoot button.
QPushButton *shoot = new QPushButton( "&Shoot", this, "shoot" ); shoot->setFont( QFont( "Times", 18, QFont::Bold ) );
In the constructor we create and set up the shoot button exactly like we did with the quit button. Note that the first argument to the constructor is the button text and the third is the widget's name.
connect( shoot, SIGNAL(clicked()), cannonField, SLOT(shoot()) );
Connects the clicked() signal of the shoot button to the shoot() slot of the CannonField.
The cannon can shoot, but there's nothing to shoot at.
Make the shot a filled circle (hint: QPainter::drawEllipse() may help).
Change the color of the cannon when a shot is in the air.
You may now go on to chapter twelve.
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