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#include "qvariantanimation.h"
#include "qvariantanimation_p.h"
#include <QtCore/qrect.h>
#include <QtCore/qline.h>
#include <QtCore/qmutex.h>
#include <private/qmutexpool_p.h>
#ifndef QT_NO_ANIMATION
QT_BEGIN_NAMESPACE
/*!
\class QVariantAnimation
\ingroup animation
\brief The QVariantAnimation class provides an abstract base class for animations.
\since 4.6
This class is part of \l{The Animation Framework}. It serves as a
base class for property and item animations, with functions for
shared functionality.
QVariantAnimation cannot be used directly as it is an abstract
class; it has a pure virtual method called updateCurrentValue().
The class performs interpolation over
\l{QVariant}s, but leaves using the interpolated values to its
subclasses. Currently, Qt provides QPropertyAnimation, which
animates Qt \l{Qt's Property System}{properties}. See the
QPropertyAnimation class description if you wish to animate such
properties.
You can then set start and end values for the property by calling
setStartValue() and setEndValue(), and finally call start() to
start the animation. QVariantAnimation will interpolate the
property of the target object and emit valueChanged(). To react to
a change in the current value you have to reimplement the
updateCurrentValue() virtual function.
It is also possible to set values at specified steps situated
between the start and end value. The interpolation will then
touch these points at the specified steps. Note that the start and
end values are defined as the key values at 0.0 and 1.0.
There are two ways to affect how QVariantAnimation interpolates
the values. You can set an easing curve by calling
setEasingCurve(), and configure the duration by calling
setDuration(). You can change how the QVariants are interpolated
by creating a subclass of QVariantAnimation, and reimplementing
the virtual interpolated() function.
Subclassing QVariantAnimation can be an alternative if you have
\l{QVariant}s that you do not wish to declare as Qt properties.
Note, however, that you in most cases will be better off declaring
your QVariant as a property.
Not all QVariant types are supported. Below is a list of currently
supported QVariant types:
\list
\o \l{QMetaType::}{Int}
\o \l{QMetaType::}{Double}
\o \l{QMetaType::}{Float}
\o \l{QMetaType::}{QLine}
\o \l{QMetaType::}{QLineF}
\o \l{QMetaType::}{QPoint}
\o \l{QMetaType::}{QSize}
\o \l{QMetaType::}{QSizeF}
\o \l{QMetaType::}{QRect}
\o \l{QMetaType::}{QRectF}
\endlist
If you need to interpolate other variant types, including custom
types, you have to implement interpolation for these yourself.
You do this by reimplementing interpolated(), which returns
interpolation values for the value being interpolated.
\omit We need some snippets around here. \endomit
\sa QPropertyAnimation, QAbstractAnimation, {The Animation Framework}
*/
/*!
\fn void QVariantAnimation::valueChanged(const QVariant &value)
QVariantAnimation emits this signal whenever the current \a value changes.
\sa currentValue, startValue, endValue
*/
/*!
\fn void QVariantAnimation::updateCurrentValue(const QVariant &value) = 0;
This pure virtual function is called every time the animation's current
value changes. The \a value argument is the new current value.
\sa currentValue
*/
static bool animationValueLessThan(const QVariantAnimation::KeyValue &p1, const QVariantAnimation::KeyValue &p2)
{
return p1.first < p2.first;
}
static QVariant defaultInterpolator(const void *, const void *, qreal)
{
return QVariant();
}
template<> Q_INLINE_TEMPLATE QRect _q_interpolate(const QRect &f, const QRect &t, qreal progress)
{
QRect ret;
ret.setCoords(_q_interpolate(f.left(), t.left(), progress),
_q_interpolate(f.top(), t.top(), progress),
_q_interpolate(f.right(), t.right(), progress),
_q_interpolate(f.bottom(), t.bottom(), progress));
return ret;
}
template<> Q_INLINE_TEMPLATE QRectF _q_interpolate(const QRectF &f, const QRectF &t, qreal progress)
{
qreal x1, y1, w1, h1;
f.getRect(&x1, &y1, &w1, &h1);
qreal x2, y2, w2, h2;
t.getRect(&x2, &y2, &w2, &h2);
return QRectF(_q_interpolate(x1, x2, progress), _q_interpolate(y1, y2, progress),
_q_interpolate(w1, w2, progress), _q_interpolate(h1, h2, progress));
}
template<> Q_INLINE_TEMPLATE QLine _q_interpolate(const QLine &f, const QLine &t, qreal progress)
{
return QLine( _q_interpolate(f.p1(), t.p1(), progress), _q_interpolate(f.p2(), t.p2(), progress));
}
template<> Q_INLINE_TEMPLATE QLineF _q_interpolate(const QLineF &f, const QLineF &t, qreal progress)
{
return QLineF( _q_interpolate(f.p1(), t.p1(), progress), _q_interpolate(f.p2(), t.p2(), progress));
}
QVariantAnimationPrivate::QVariantAnimationPrivate() : duration(250), interpolator(&defaultInterpolator)
{ }
void QVariantAnimationPrivate::convertValues(int t)
{
//this ensures that all the keyValues are of type t
for (int i = 0; i < keyValues.count(); ++i) {
QVariantAnimation::KeyValue &pair = keyValues[i];
pair.second.convert(static_cast<QVariant::Type>(t));
}
//we also need update to the current interval if needed
currentInterval.start.second.convert(static_cast<QVariant::Type>(t));
currentInterval.end.second.convert(static_cast<QVariant::Type>(t));
//... and the interpolator
updateInterpolator();
}
void QVariantAnimationPrivate::updateInterpolator()
{
int type = currentInterval.start.second.userType();
if (type == currentInterval.end.second.userType())
interpolator = getInterpolator(type);
else
interpolator = 0;
//we make sure that the interpolator is always set to something
if (!interpolator)
interpolator = &defaultInterpolator;
}
/*!
\internal
The goal of this function is to update the currentInterval member. As a consequence, we also
need to update the currentValue.
Set \a force to true to always recalculate the interval.
*/
void QVariantAnimationPrivate::recalculateCurrentInterval(bool force/*=false*/)
{
// can't interpolate if we don't have at least 2 values
if ((keyValues.count() + (defaultStartEndValue.isValid() ? 1 : 0)) < 2)
return;
const qreal progress = easing.valueForProgress(((duration == 0) ? qreal(1) : qreal(currentTime) / qreal(duration)));
//0 and 1 are still the boundaries
if (force || (currentInterval.start.first > 0 && progress < currentInterval.start.first)
|| (currentInterval.end.first < 1 && progress > currentInterval.end.first)) {
//let's update currentInterval
QVariantAnimation::KeyValues::const_iterator it = qLowerBound(keyValues.constBegin(),
keyValues.constEnd(),
qMakePair(progress, QVariant()),
animationValueLessThan);
if (it == keyValues.constBegin()) {
//the item pointed to by it is the start element in the range
if (it->first == 0 && keyValues.count() > 1) {
currentInterval.start = *it;
currentInterval.end = *(it+1);
} else {
currentInterval.start = qMakePair(qreal(0), defaultStartEndValue);
currentInterval.end = *it;
}
} else if (it == keyValues.constEnd()) {
--it; //position the iterator on the last item
if (it->first == 1 && keyValues.count() > 1) {
//we have an end value (item with progress = 1)
currentInterval.start = *(it-1);
currentInterval.end = *it;
} else {
//we use the default end value here
currentInterval.start = *it;
currentInterval.end = qMakePair(qreal(1), defaultStartEndValue);
}
} else {
currentInterval.start = *(it-1);
currentInterval.end = *it;
}
// update all the values of the currentInterval
updateInterpolator();
}
setCurrentValueForProgress(progress);
}
void QVariantAnimationPrivate::setCurrentValueForProgress(const qreal progress)
{
Q_Q(QVariantAnimation);
const qreal startProgress = currentInterval.start.first;
const qreal endProgress = currentInterval.end.first;
const qreal localProgress = (progress - startProgress) / (endProgress - startProgress);
QVariant ret = q->interpolated(currentInterval.start.second,
currentInterval.end.second,
localProgress);
qSwap(currentValue, ret);
q->updateCurrentValue(currentValue);
static QBasicAtomicInt changedSignalIndex = Q_BASIC_ATOMIC_INITIALIZER(0);
if (!changedSignalIndex) {
//we keep the mask so that we emit valueChanged only when needed (for performance reasons)
changedSignalIndex.testAndSetRelaxed(0, signalIndex("valueChanged(QVariant)"));
}
if (isSignalConnected(changedSignalIndex) && currentValue != ret) {
//the value has changed
emit q->valueChanged(currentValue);
}
}
QVariant QVariantAnimationPrivate::valueAt(qreal step) const
{
QVariantAnimation::KeyValues::const_iterator result =
qBinaryFind(keyValues.begin(), keyValues.end(), qMakePair(step, QVariant()), animationValueLessThan);
if (result != keyValues.constEnd())
return result->second;
return QVariant();
}
void QVariantAnimationPrivate::setValueAt(qreal step, const QVariant &value)
{
if (step < qreal(0.0) || step > qreal(1.0)) {
qWarning("QVariantAnimation::setValueAt: invalid step = %f", step);
return;
}
QVariantAnimation::KeyValue pair(step, value);
QVariantAnimation::KeyValues::iterator result = qLowerBound(keyValues.begin(), keyValues.end(), pair, animationValueLessThan);
if (result == keyValues.end() || result->first != step) {
keyValues.insert(result, pair);
} else {
if (value.isValid())
result->second = value; // replaces the previous value
else
keyValues.erase(result); // removes the previous value
}
recalculateCurrentInterval(/*force=*/true);
}
void QVariantAnimationPrivate::setDefaultStartEndValue(const QVariant &value)
{
defaultStartEndValue = value;
recalculateCurrentInterval(/*force=*/true);
}
/*!
Construct a QVariantAnimation object. \a parent is passed to QAbstractAnimation's
constructor.
*/
QVariantAnimation::QVariantAnimation(QObject *parent) : QAbstractAnimation(*new QVariantAnimationPrivate, parent)
{
}
/*!
\internal
*/
QVariantAnimation::QVariantAnimation(QVariantAnimationPrivate &dd, QObject *parent) : QAbstractAnimation(dd, parent)
{
}
/*!
Destroys the animation.
*/
QVariantAnimation::~QVariantAnimation()
{
}
/*!
\property QVariantAnimation::easingCurve
\brief the easing curve of the animation
This property defines the easing curve of the animation. By
default, a linear easing curve is used, resulting in linear
interpolation. Other curves are provided, for instance,
QEasingCurve::InCirc, which provides a circular entry curve.
Another example is QEasingCurve::InOutElastic, which provides an
elastic effect on the values of the interpolated variant.
The easing curve is used with the interpolator, the interpolated()
virtual function, the animation's duration, and iterationCount, to
control how the current value changes as the animation progresses.
*/
QEasingCurve QVariantAnimation::easingCurve() const
{
Q_D(const QVariantAnimation);
return d->easing;
}
void QVariantAnimation::setEasingCurve(const QEasingCurve &easing)
{
Q_D(QVariantAnimation);
d->easing = easing;
d->recalculateCurrentInterval();
}
typedef QVector<QVariantAnimation::Interpolator> QInterpolatorVector;
Q_GLOBAL_STATIC(QInterpolatorVector, registeredInterpolators)
/*!
\fn void qRegisterAnimationInterpolator(QVariant (*func)(const T &from, const T &to, qreal progress))
\relates QVariantAnimation
\threadsafe
Registers a custom interpolator \a func for the template type \c{T}.
The interpolator has to be registered before the animation is constructed.
To unregister (and use the default interpolator) set \a func to 0.
*/
/*!
\internal
\typedef QVariantAnimation::Interpolator
This is a typedef for a pointer to a function with the following
signature:
\code
QVariant myInterpolator(const QVariant &from, const QVariant &to, qreal progress);
\endcode
*/
/*! \internal
* Registers a custom interpolator \a func for the specific \a interpolationType.
* The interpolator has to be registered before the animation is constructed.
* To unregister (and use the default interpolator) set \a func to 0.
*/
void QVariantAnimation::registerInterpolator(QVariantAnimation::Interpolator func, int interpolationType)
{
// will override any existing interpolators
QInterpolatorVector *interpolators = registeredInterpolators();
QMutexLocker locker(QMutexPool::globalInstanceGet(interpolators));
if (int(interpolationType) >= interpolators->count())
interpolators->resize(int(interpolationType) + 1);
interpolators->replace(interpolationType, func);
}
template<typename T> static inline QVariantAnimation::Interpolator castToInterpolator(QVariant (*func)(const T &from, const T &to, qreal progress))
{
return reinterpret_cast<QVariantAnimation::Interpolator>(func);
}
QVariantAnimation::Interpolator QVariantAnimationPrivate::getInterpolator(int interpolationType)
{
QInterpolatorVector *interpolators = registeredInterpolators();
QMutexLocker locker(QMutexPool::globalInstanceGet(interpolators));
QVariantAnimation::Interpolator ret = 0;
if (interpolationType < interpolators->count()) {
ret = interpolators->at(interpolationType);
if (ret) return ret;
}
switch(interpolationType)
{
case QMetaType::Int:
return castToInterpolator(_q_interpolateVariant<int>);
case QMetaType::Double:
return castToInterpolator(_q_interpolateVariant<double>);
case QMetaType::Float:
return castToInterpolator(_q_interpolateVariant<float>);
case QMetaType::QLine:
return castToInterpolator(_q_interpolateVariant<QLine>);
case QMetaType::QLineF:
return castToInterpolator(_q_interpolateVariant<QLineF>);
case QMetaType::QPoint:
return castToInterpolator(_q_interpolateVariant<QPoint>);
case QMetaType::QPointF:
return castToInterpolator(_q_interpolateVariant<QPointF>);
case QMetaType::QSize:
return castToInterpolator(_q_interpolateVariant<QSize>);
case QMetaType::QSizeF:
return castToInterpolator(_q_interpolateVariant<QSizeF>);
case QMetaType::QRect:
return castToInterpolator(_q_interpolateVariant<QRect>);
case QMetaType::QRectF:
return castToInterpolator(_q_interpolateVariant<QRectF>);
default:
return 0; //this type is not handled
}
}
/*!
\property QVariantAnimation::duration
\brief the duration of the animation
This property describes the duration in milliseconds of the
animation. The default duration is 250 milliseconds.
\sa QAbstractAnimation::duration()
*/
int QVariantAnimation::duration() const
{
Q_D(const QVariantAnimation);
return d->duration;
}
void QVariantAnimation::setDuration(int msecs)
{
Q_D(QVariantAnimation);
if (msecs < 0) {
qWarning("QVariantAnimation::setDuration: cannot set a negative duration");
return;
}
if (d->duration == msecs)
return;
d->duration = msecs;
d->recalculateCurrentInterval();
}
/*!
\property QVariantAnimation::startValue
\brief the optional start value of the animation
This property describes the optional start value of the animation. If
omitted, or if a null QVariant is assigned as the start value, the
animation will use the current position of the end when the animation
is started.
\sa endValue
*/
QVariant QVariantAnimation::startValue() const
{
return keyValueAt(0);
}
void QVariantAnimation::setStartValue(const QVariant &value)
{
setKeyValueAt(0, value);
}
/*!
\property QVariantAnimation::endValue
\brief the end value of the animation
This property describes the end value of the animation.
\sa startValue
*/
QVariant QVariantAnimation::endValue() const
{
return keyValueAt(1);
}
void QVariantAnimation::setEndValue(const QVariant &value)
{
setKeyValueAt(1, value);
}
/*!
Returns the key frame value for the given \a step. The given \a step
must be in the range 0 to 1. If there is no KeyValue for \a step,
it returns an invalid QVariant.
\sa keyValues(), setKeyValueAt()
*/
QVariant QVariantAnimation::keyValueAt(qreal step) const
{
return d_func()->valueAt(step);
}
/*!
\typedef QVariantAnimation::KeyValue
This is a typedef for QPair<qreal, QVariant>.
*/
/*!
\typedef QVariantAnimation::KeyValues
This is a typedef for QVector<KeyValue>
*/
/*!
Creates a key frame at the given \a step with the given \a value.
The given \a step must be in the range 0 to 1.
\sa setKeyValues(), keyValueAt()
*/
void QVariantAnimation::setKeyValueAt(qreal step, const QVariant &value)
{
d_func()->setValueAt(step, value);
}
/*!
Returns the key frames of this animation.
\sa keyValueAt(), setKeyValues()
*/
QVariantAnimation::KeyValues QVariantAnimation::keyValues() const
{
return d_func()->keyValues;
}
/*!
Replaces the current set of key frames with the given \a keyValues.
the step of the key frames must be in the range 0 to 1.
\sa keyValues(), keyValueAt()
*/
void QVariantAnimation::setKeyValues(const KeyValues &keyValues)
{
Q_D(QVariantAnimation);
d->keyValues = keyValues;
qSort(d->keyValues.begin(), d->keyValues.end(), animationValueLessThan);
d->recalculateCurrentInterval(/*force=*/true);
}
/*!
\property QVariantAnimation::currentValue
\brief the current value of the animation.
This property describes the current value; an interpolated value
between the \l{startValue}{start value} and the \l{endValue}{end
value}, using the current time for progress. The value itself is
obtained from interpolated(), which is called repeatedly as the
animation is running.
QVariantAnimation calls the virtual updateCurrentValue() function
when the current value changes. This is particularly useful for
subclasses that need to track updates. For example,
QPropertyAnimation uses this function to animate Qt \l{Qt's
Property System}{properties}.
\sa startValue, endValue
*/
QVariant QVariantAnimation::currentValue() const
{
Q_D(const QVariantAnimation);
if (!d->currentValue.isValid())
const_cast<QVariantAnimationPrivate*>(d)->recalculateCurrentInterval();
return d->currentValue;
}
/*!
\reimp
*/
bool QVariantAnimation::event(QEvent *event)
{
return QAbstractAnimation::event(event);
}
/*!
\reimp
*/
void QVariantAnimation::updateState(QAbstractAnimation::State oldState,
QAbstractAnimation::State newState)
{
Q_UNUSED(oldState);
Q_UNUSED(newState);
}
/*!
This virtual function returns the linear interpolation between
variants \a from and \a to, at \a progress, usually a value
between 0 and 1. You can reimplement this function in a subclass
of QVariantAnimation to provide your own interpolation algorithm.
Note that in order for the interpolation to work with a
QEasingCurve that return a value smaller than 0 or larger than 1
(such as QEasingCurve::InBack) you should make sure that it can
extrapolate. If the semantic of the datatype does not allow
extrapolation this function should handle that gracefully.
You should call the QVariantAnimation implementation of this
function if you want your class to handle the types already
supported by Qt (see class QVariantAnimation description for a
list of supported types).
\sa QEasingCurve
*/
QVariant QVariantAnimation::interpolated(const QVariant &from, const QVariant &to, qreal progress) const
{
return d_func()->interpolator(from.constData(), to.constData(), progress);
}
/*!
\reimp
*/
void QVariantAnimation::updateCurrentTime(int)
{
d_func()->recalculateCurrentInterval();
}
QT_END_NAMESPACE
#include "moc_qvariantanimation.cpp"
#endif //QT_NO_ANIMATION