/**************************************************************************** ** ** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). ** All rights reserved. ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the QtDeclarative module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the Technology Preview License Agreement accompanying ** this package. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** ** ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qdeclarativeanimation_p.h" #include "qdeclarativeanimation_p_p.h" #include "qdeclarativebehavior_p.h" #include "qdeclarativestateoperations_p.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include QT_BEGIN_NAMESPACE /*! \qmlclass Animation QDeclarativeAbstractAnimation \since 4.7 \brief The Animation element is the base of all QML animations. The Animation element cannot be used directly in a QML file. It exists to provide a set of common properties and methods, available across all the other animation types that inherit from it. Attempting to use the Animation element directly will result in an error. */ /*! \class QDeclarativeAbstractAnimation \internal */ QDeclarativeAbstractAnimation::QDeclarativeAbstractAnimation(QObject *parent) : QObject(*(new QDeclarativeAbstractAnimationPrivate), parent) { } QDeclarativeAbstractAnimation::~QDeclarativeAbstractAnimation() { } QDeclarativeAbstractAnimation::QDeclarativeAbstractAnimation(QDeclarativeAbstractAnimationPrivate &dd, QObject *parent) : QObject(dd, parent) { } /*! \qmlproperty bool Animation::running This property holds whether the animation is currently running. The \c running property can be set to declaratively control whether or not an animation is running. The following example will animate a rectangle whenever the \l MouseArea is pressed. \code Rectangle { width: 100; height: 100 NumberAnimation on x { running: myMouse.pressed from: 0; to: 100 } MouseArea { id: myMouse } } \endcode Likewise, the \c running property can be read to determine if the animation is running. In the following example the text element will indicate whether or not the animation is running. \code NumberAnimation { id: myAnimation } Text { text: myAnimation.running ? "Animation is running" : "Animation is not running" } \endcode Animations can also be started and stopped imperatively from JavaScript using the \c start() and \c stop() methods. By default, animations are not running. Though, when the animations are assigned to properties, as property value sources, they are set to running by default. */ bool QDeclarativeAbstractAnimation::isRunning() const { Q_D(const QDeclarativeAbstractAnimation); return d->running; } //commence is called to start an animation when it is used as a //simple animation, and not as part of a transition void QDeclarativeAbstractAnimationPrivate::commence() { Q_Q(QDeclarativeAbstractAnimation); QDeclarativeStateActions actions; QDeclarativeProperties properties; q->transition(actions, properties, QDeclarativeAbstractAnimation::Forward); q->qtAnimation()->start(); if (q->qtAnimation()->state() != QAbstractAnimation::Running) { running = false; emit q->completed(); } } QDeclarativeProperty QDeclarativeAbstractAnimationPrivate::createProperty(QObject *obj, const QString &str, QObject *infoObj) { QDeclarativeProperty prop(obj, str, qmlContext(infoObj)); if (!prop.isValid()) { qmlInfo(infoObj) << QDeclarativeAbstractAnimation::tr("Cannot animate non-existent property \"%1\"").arg(str); return QDeclarativeProperty(); } else if (!prop.isWritable()) { qmlInfo(infoObj) << QDeclarativeAbstractAnimation::tr("Cannot animate read-only property \"%1\"").arg(str); return QDeclarativeProperty(); } return prop; } void QDeclarativeAbstractAnimation::setRunning(bool r) { Q_D(QDeclarativeAbstractAnimation); if (!d->componentComplete) { d->running = r; if (r == false) d->avoidPropertyValueSourceStart = true; return; } if (d->running == r) return; if (d->group || d->disableUserControl) { qWarning("QDeclarativeAbstractAnimation: setRunning() cannot be used on non-root animation nodes"); return; } d->running = r; if (d->running) { if (d->alwaysRunToEnd && d->repeat && qtAnimation()->state() == QAbstractAnimation::Running) { qtAnimation()->setLoopCount(-1); } if (!d->connectedTimeLine) { QObject::connect(qtAnimation(), SIGNAL(finished()), this, SLOT(timelineComplete())); d->connectedTimeLine = true; } d->commence(); emit started(); } else { if (d->alwaysRunToEnd) { if (d->repeat) qtAnimation()->setLoopCount(qtAnimation()->currentLoop()+1); } else qtAnimation()->stop(); emit completed(); } emit runningChanged(d->running); } /*! \qmlproperty bool Animation::paused This property holds whether the animation is currently paused. The \c paused property can be set to declaratively control whether or not an animation is paused. Animations can also be paused and resumed imperatively from JavaScript using the \c pause() and \c resume() methods. By default, animations are not paused. */ bool QDeclarativeAbstractAnimation::isPaused() const { Q_D(const QDeclarativeAbstractAnimation); return d->paused; } void QDeclarativeAbstractAnimation::setPaused(bool p) { Q_D(QDeclarativeAbstractAnimation); if (d->paused == p) return; if (d->group || d->disableUserControl) { qWarning("QDeclarativeAbstractAnimation: setPaused() cannot be used on non-root animation nodes"); return; } d->paused = p; if (d->paused) qtAnimation()->pause(); else qtAnimation()->resume(); emit pausedChanged(d->paused); } void QDeclarativeAbstractAnimation::classBegin() { Q_D(QDeclarativeAbstractAnimation); d->componentComplete = false; } void QDeclarativeAbstractAnimation::componentComplete() { Q_D(QDeclarativeAbstractAnimation); d->componentComplete = true; if (d->running) { d->running = false; setRunning(true); } } /*! \qmlproperty bool Animation::alwaysRunToEnd This property holds whether the animation should run to completion when it is stopped. If this true the animation will complete its current iteration when it is stopped - either by setting the \c running property to false, or by calling the \c stop() method. The \c complete() method is not effected by this value. This behavior is most useful when the \c repeat property is set, as the animation will finish playing normally but not restart. By default, the alwaysRunToEnd property is not set. */ bool QDeclarativeAbstractAnimation::alwaysRunToEnd() const { Q_D(const QDeclarativeAbstractAnimation); return d->alwaysRunToEnd; } void QDeclarativeAbstractAnimation::setAlwaysRunToEnd(bool f) { Q_D(QDeclarativeAbstractAnimation); if (d->alwaysRunToEnd == f) return; d->alwaysRunToEnd = f; emit alwaysRunToEndChanged(f); } /*! \qmlproperty bool Animation::repeat This property holds whether the animation should repeat. If set, the animation will continuously repeat until it is explicitly stopped - either by setting the \c running property to false, or by calling the \c stop() method. In the following example, the rectangle will spin indefinately. \code Rectangle { NumberAnimation on rotation { running: true; repeat: true; from: 0 to: 360 } } \endcode */ bool QDeclarativeAbstractAnimation::repeat() const { Q_D(const QDeclarativeAbstractAnimation); return d->repeat; } void QDeclarativeAbstractAnimation::setRepeat(bool r) { Q_D(QDeclarativeAbstractAnimation); if (r == d->repeat) return; d->repeat = r; int lc = r ? -1 : 1; qtAnimation()->setLoopCount(lc); emit repeatChanged(r); } int QDeclarativeAbstractAnimation::currentTime() { return qtAnimation()->currentLoopTime(); } void QDeclarativeAbstractAnimation::setCurrentTime(int time) { qtAnimation()->setCurrentTime(time); } QDeclarativeAnimationGroup *QDeclarativeAbstractAnimation::group() const { Q_D(const QDeclarativeAbstractAnimation); return d->group; } void QDeclarativeAbstractAnimation::setGroup(QDeclarativeAnimationGroup *g) { Q_D(QDeclarativeAbstractAnimation); if (d->group == g) return; if (d->group) static_cast(d->group->d_func())->animations.removeAll(this); d->group = g; if (d->group && !static_cast(d->group->d_func())->animations.contains(this)) static_cast(d->group->d_func())->animations.append(this); //if (g) //if removed from a group, then the group should no longer be the parent setParent(g); } /*! \qmlmethod Animation::start() \brief Starts the animation. If the animation is already running, calling this method has no effect. The \c running property will be true following a call to \c start(). */ void QDeclarativeAbstractAnimation::start() { setRunning(true); } /*! \qmlmethod Animation::pause() \brief Pauses the animation. If the animation is already paused, calling this method has no effect. The \c paused property will be true following a call to \c pause(). */ void QDeclarativeAbstractAnimation::pause() { setPaused(true); } /*! \qmlmethod Animation::resume() \brief Resumes a paused animation. If the animation is not paused, calling this method has no effect. The \c paused property will be false following a call to \c resume(). */ void QDeclarativeAbstractAnimation::resume() { setPaused(false); } /*! \qmlmethod Animation::stop() \brief Stops the animation. If the animation is not running, calling this method has no effect. The \c running property will be false following a call to \c stop(). Normally \c stop() stops the animation immediately, and the animation has no further influence on property values. In this example animation \code Rectangle { NumberAnimation on x { from: 0; to: 100; duration: 500 } } \endcode was stopped at time 250ms, the \c x property will have a value of 50. However, if the \c alwaysRunToEnd property is set, the animation will continue running until it completes and then stop. The \c running property will still become false immediately. */ void QDeclarativeAbstractAnimation::stop() { setRunning(false); } /*! \qmlmethod Animation::restart() \brief Restarts the animation. This is a convenience method, and is equivalent to calling \c stop() and then \c start(). */ void QDeclarativeAbstractAnimation::restart() { stop(); start(); } /*! \qmlmethod Animation::complete() \brief Stops the animation, jumping to the final property values. If the animation is not running, calling this method has no effect. The \c running property will be false following a call to \c complete(). Unlike \c stop(), \c complete() immediately fast-forwards the animation to its end. In the following example, \code Rectangle { NumberAnimation on x { from: 0; to: 100; duration: 500 } } \endcode calling \c stop() at time 250ms will result in the \c x property having a value of 50, while calling \c complete() will set the \c x property to 100, exactly as though the animation had played the whole way through. */ void QDeclarativeAbstractAnimation::complete() { if (isRunning()) { qtAnimation()->setCurrentTime(qtAnimation()->duration()); } } void QDeclarativeAbstractAnimation::setTarget(const QDeclarativeProperty &p) { Q_D(QDeclarativeAbstractAnimation); d->defaultProperty = p; if (!d->avoidPropertyValueSourceStart) setRunning(true); } /* we rely on setTarget only being called when used as a value source so this function allows us to do the same thing as setTarget without that assumption */ void QDeclarativeAbstractAnimation::setDefaultTarget(const QDeclarativeProperty &p) { Q_D(QDeclarativeAbstractAnimation); d->defaultProperty = p; } /* don't allow start/stop/pause/resume to be manually invoked, because something else (like a Behavior) already has control over the animation. */ void QDeclarativeAbstractAnimation::setDisableUserControl() { Q_D(QDeclarativeAbstractAnimation); d->disableUserControl = true; } void QDeclarativeAbstractAnimation::transition(QDeclarativeStateActions &actions, QDeclarativeProperties &modified, TransitionDirection direction) { Q_UNUSED(actions); Q_UNUSED(modified); Q_UNUSED(direction); } void QDeclarativeAbstractAnimation::timelineComplete() { Q_D(QDeclarativeAbstractAnimation); setRunning(false); if (d->alwaysRunToEnd && d->repeat) { qtAnimation()->setLoopCount(-1); } } /*! \qmlclass PauseAnimation QDeclarativePauseAnimation \since 4.7 \inherits Animation \brief The PauseAnimation element provides a pause for an animation. When used in a SequentialAnimation, PauseAnimation is a step when nothing happens, for a specified duration. A 500ms animation sequence, with a 100ms pause between two animations: \code SequentialAnimation { NumberAnimation { ... duration: 200 } PauseAnimation { duration: 100 } NumberAnimation { ... duration: 200 } } \endcode */ /*! \internal \class QDeclarativePauseAnimation */ QDeclarativePauseAnimation::QDeclarativePauseAnimation(QObject *parent) : QDeclarativeAbstractAnimation(*(new QDeclarativePauseAnimationPrivate), parent) { Q_D(QDeclarativePauseAnimation); d->init(); } QDeclarativePauseAnimation::~QDeclarativePauseAnimation() { } void QDeclarativePauseAnimationPrivate::init() { Q_Q(QDeclarativePauseAnimation); pa = new QPauseAnimation; QDeclarative_setParent_noEvent(pa, q); } /*! \qmlproperty int PauseAnimation::duration This property holds the duration of the pause in milliseconds The default value is 250. */ int QDeclarativePauseAnimation::duration() const { Q_D(const QDeclarativePauseAnimation); return d->pa->duration(); } void QDeclarativePauseAnimation::setDuration(int duration) { if (duration < 0) { qmlInfo(this) << tr("Cannot set a duration of < 0"); return; } Q_D(QDeclarativePauseAnimation); if (d->pa->duration() == duration) return; d->pa->setDuration(duration); emit durationChanged(duration); } QAbstractAnimation *QDeclarativePauseAnimation::qtAnimation() { Q_D(QDeclarativePauseAnimation); return d->pa; } /*! \qmlclass ColorAnimation QDeclarativeColorAnimation \since 4.7 \inherits PropertyAnimation \brief The ColorAnimation element allows you to animate color changes. \code ColorAnimation { from: "white"; to: "#c0c0c0"; duration: 100 } \endcode When used in a transition, ColorAnimation will by default animate all properties of type color that are changing. If a property or properties are explicitly set for the animation, then those will be used instead. */ /*! \internal \class QDeclarativeColorAnimation */ QDeclarativeColorAnimation::QDeclarativeColorAnimation(QObject *parent) : QDeclarativePropertyAnimation(parent) { Q_D(QDeclarativePropertyAnimation); d->interpolatorType = QMetaType::QColor; d->interpolator = QVariantAnimationPrivate::getInterpolator(d->interpolatorType); d->defaultToInterpolatorType = true; } QDeclarativeColorAnimation::~QDeclarativeColorAnimation() { } /*! \qmlproperty color ColorAnimation::from This property holds the starting color. */ QColor QDeclarativeColorAnimation::from() const { Q_D(const QDeclarativePropertyAnimation); return d->from.value(); } void QDeclarativeColorAnimation::setFrom(const QColor &f) { QDeclarativePropertyAnimation::setFrom(f); } /*! \qmlproperty color ColorAnimation::to This property holds the ending color. */ QColor QDeclarativeColorAnimation::to() const { Q_D(const QDeclarativePropertyAnimation); return d->to.value(); } void QDeclarativeColorAnimation::setTo(const QColor &t) { QDeclarativePropertyAnimation::setTo(t); } /*! \qmlclass ScriptAction QDeclarativeScriptAction \since 4.7 \inherits Animation \brief The ScriptAction element allows scripts to be run during an animation. */ /*! \internal \class QDeclarativeScriptAction */ QDeclarativeScriptAction::QDeclarativeScriptAction(QObject *parent) :QDeclarativeAbstractAnimation(*(new QDeclarativeScriptActionPrivate), parent) { Q_D(QDeclarativeScriptAction); d->init(); } QDeclarativeScriptAction::~QDeclarativeScriptAction() { } void QDeclarativeScriptActionPrivate::init() { Q_Q(QDeclarativeScriptAction); rsa = new QActionAnimation(&proxy); QDeclarative_setParent_noEvent(rsa, q); } /*! \qmlproperty script ScriptAction::script This property holds the script to run. */ QDeclarativeScriptString QDeclarativeScriptAction::script() const { Q_D(const QDeclarativeScriptAction); return d->script; } void QDeclarativeScriptAction::setScript(const QDeclarativeScriptString &script) { Q_D(QDeclarativeScriptAction); d->script = script; } /*! \qmlproperty QString ScriptAction::stateChangeScriptName This property holds the the name of the StateChangeScript to run. This property is only valid when ScriptAction is used as part of a transition. If both script and stateChangeScriptName are set, stateChangeScriptName will be used. */ QString QDeclarativeScriptAction::stateChangeScriptName() const { Q_D(const QDeclarativeScriptAction); return d->name; } void QDeclarativeScriptAction::setStateChangeScriptName(const QString &name) { Q_D(QDeclarativeScriptAction); d->name = name; } void QDeclarativeScriptActionPrivate::execute() { QDeclarativeScriptString scriptStr = hasRunScriptScript ? runScriptScript : script; const QString &str = scriptStr.script(); if (!str.isEmpty()) { QDeclarativeExpression expr(scriptStr.context(), str, scriptStr.scopeObject()); expr.value(); } } void QDeclarativeScriptAction::transition(QDeclarativeStateActions &actions, QDeclarativeProperties &modified, TransitionDirection direction) { Q_D(QDeclarativeScriptAction); Q_UNUSED(modified); Q_UNUSED(direction); d->hasRunScriptScript = false; for (int ii = 0; ii < actions.count(); ++ii) { QDeclarativeAction &action = actions[ii]; if (action.event && action.event->typeName() == QLatin1String("StateChangeScript") && static_cast(action.event)->name() == d->name) { //### how should we handle reverse direction? d->runScriptScript = static_cast(action.event)->script(); d->hasRunScriptScript = true; action.actionDone = true; break; //assumes names are unique } } } QAbstractAnimation *QDeclarativeScriptAction::qtAnimation() { Q_D(QDeclarativeScriptAction); return d->rsa; } /*! \qmlclass PropertyAction QDeclarativePropertyAction \since 4.7 \inherits Animation \brief The PropertyAction element allows immediate property changes during animation. Explicitly set \c theimage.smooth=true during a transition: \code PropertyAction { target: theimage; property: "smooth"; value: true } \endcode Set \c thewebview.url to the value set for the destination state: \code PropertyAction { target: thewebview; property: "url" } \endcode The PropertyAction is immediate - the target property is not animated to the selected value in any way. */ /*! \internal \class QDeclarativePropertyAction */ QDeclarativePropertyAction::QDeclarativePropertyAction(QObject *parent) : QDeclarativeAbstractAnimation(*(new QDeclarativePropertyActionPrivate), parent) { Q_D(QDeclarativePropertyAction); d->init(); } QDeclarativePropertyAction::~QDeclarativePropertyAction() { } void QDeclarativePropertyActionPrivate::init() { Q_Q(QDeclarativePropertyAction); spa = new QActionAnimation; QDeclarative_setParent_noEvent(spa, q); } /*! \qmlproperty Object PropertyAction::target This property holds an explicit target object to animate. The exact effect of the \c target property depends on how the animation is being used. Refer to the \l animation documentation for details. */ QObject *QDeclarativePropertyAction::target() const { Q_D(const QDeclarativePropertyAction); return d->target; } void QDeclarativePropertyAction::setTarget(QObject *o) { Q_D(QDeclarativePropertyAction); if (d->target == o) return; d->target = o; emit targetChanged(d->target, d->propertyName); } QString QDeclarativePropertyAction::property() const { Q_D(const QDeclarativePropertyAction); return d->propertyName; } void QDeclarativePropertyAction::setProperty(const QString &n) { Q_D(QDeclarativePropertyAction); if (d->propertyName == n) return; d->propertyName = n; emit targetChanged(d->target, d->propertyName); } /*! \qmlproperty string PropertyAction::property \qmlproperty string PropertyAction::properties \qmlproperty Object PropertyAction::target \qmlproperty list PropertyAction::targets These properties are used as a set to determine which properties should be affected by this action. The details of how these properties are interpreted in different situations is covered in the \l{PropertyAnimation::properties}{corresponding} PropertyAnimation documentation. \sa exclude */ QString QDeclarativePropertyAction::properties() const { Q_D(const QDeclarativePropertyAction); return d->properties; } void QDeclarativePropertyAction::setProperties(const QString &p) { Q_D(QDeclarativePropertyAction); if (d->properties == p) return; d->properties = p; emit propertiesChanged(p); } QDeclarativeListProperty QDeclarativePropertyAction::targets() { Q_D(QDeclarativePropertyAction); return QDeclarativeListProperty(this, d->targets); } /*! \qmlproperty list PropertyAction::exclude This property holds the objects not to be affected by this animation. \sa targets */ QDeclarativeListProperty QDeclarativePropertyAction::exclude() { Q_D(QDeclarativePropertyAction); return QDeclarativeListProperty(this, d->exclude); } /*! \qmlproperty any PropertyAction::value This property holds the value to be set on the property. If not set, then the value defined for the end state of the transition. */ QVariant QDeclarativePropertyAction::value() const { Q_D(const QDeclarativePropertyAction); return d->value; } void QDeclarativePropertyAction::setValue(const QVariant &v) { Q_D(QDeclarativePropertyAction); if (d->value.isNull || d->value != v) { d->value = v; emit valueChanged(v); } } QAbstractAnimation *QDeclarativePropertyAction::qtAnimation() { Q_D(QDeclarativePropertyAction); return d->spa; } void QDeclarativePropertyAction::transition(QDeclarativeStateActions &actions, QDeclarativeProperties &modified, TransitionDirection direction) { Q_D(QDeclarativePropertyAction); Q_UNUSED(direction); struct QDeclarativeSetPropertyAnimationAction : public QAbstractAnimationAction { QDeclarativeStateActions actions; virtual void doAction() { for (int ii = 0; ii < actions.count(); ++ii) { const QDeclarativeAction &action = actions.at(ii); QDeclarativePropertyPrivate::write(action.property, action.toValue, QDeclarativePropertyPrivate::BypassInterceptor | QDeclarativePropertyPrivate::DontRemoveBinding); } } }; QStringList props = d->properties.isEmpty() ? QStringList() : d->properties.split(QLatin1Char(',')); for (int ii = 0; ii < props.count(); ++ii) props[ii] = props.at(ii).trimmed(); if (!d->propertyName.isEmpty()) props << d->propertyName; QList targets = d->targets; if (d->target) targets.append(d->target); bool hasSelectors = !props.isEmpty() || !targets.isEmpty() || !d->exclude.isEmpty(); if (d->defaultProperty.isValid() && !hasSelectors) { props << d->defaultProperty.name(); targets << d->defaultProperty.object(); } QDeclarativeSetPropertyAnimationAction *data = new QDeclarativeSetPropertyAnimationAction; bool hasExplicit = false; //an explicit animation has been specified if (d->value.isValid()) { for (int i = 0; i < props.count(); ++i) { for (int j = 0; j < targets.count(); ++j) { QDeclarativeAction myAction; myAction.property = d->createProperty(targets.at(j), props.at(i), this); if (myAction.property.isValid()) { myAction.toValue = d->value; QDeclarativePropertyAnimationPrivate::convertVariant(myAction.toValue, myAction.property.propertyType()); data->actions << myAction; hasExplicit = true; for (int ii = 0; ii < actions.count(); ++ii) { QDeclarativeAction &action = actions[ii]; if (action.property.object() == myAction.property.object() && myAction.property.name() == action.property.name()) { modified << action.property; break; //### any chance there could be multiples? } } } } } } if (!hasExplicit) for (int ii = 0; ii < actions.count(); ++ii) { QDeclarativeAction &action = actions[ii]; QObject *obj = action.property.object(); QString propertyName = action.property.name(); QObject *sObj = action.specifiedObject; QString sPropertyName = action.specifiedProperty; bool same = (obj == sObj); if ((targets.isEmpty() || targets.contains(obj) || (!same && targets.contains(sObj))) && (!d->exclude.contains(obj)) && (same || (!d->exclude.contains(sObj))) && (props.contains(propertyName) || (!same && props.contains(sPropertyName)))) { QDeclarativeAction myAction = action; if (d->value.isValid()) myAction.toValue = d->value; QDeclarativePropertyAnimationPrivate::convertVariant(myAction.toValue, myAction.property.propertyType()); modified << action.property; data->actions << myAction; action.fromValue = myAction.toValue; } } if (data->actions.count()) { d->spa->setAnimAction(data, QAbstractAnimation::DeleteWhenStopped); } else { delete data; } } /*! \qmlclass ParentAction QDeclarativeParentAction \since 4.7 \inherits Animation \brief The ParentAction element allows parent changes during animation. ParentAction provides a way to specify at what point in a Transition a ParentChange should occur. \qml State { ParentChange { target: myItem parent: newParent } } Transition { SequentialAnimation { PropertyAnimation { ... } ParentAction {} //reparent myItem now PropertyAnimation { ... } } } \endqml It also provides a way to explicitly reparent an item during an animation. \qml SequentialAnimation { ParentAction { target: myItem; parent: newParent } PropertyAnimation {} } \endqml The ParentAction is immediate - it is not animated in any way. */ QDeclarativeParentAction::QDeclarativeParentAction(QObject *parent) : QDeclarativeAbstractAnimation(*(new QDeclarativeParentActionPrivate), parent) { Q_D(QDeclarativeParentAction); d->init(); } QDeclarativeParentAction::~QDeclarativeParentAction() { } void QDeclarativeParentActionPrivate::init() { Q_Q(QDeclarativeParentAction); cpa = new QActionAnimation; QDeclarative_setParent_noEvent(cpa, q); } /*! \qmlproperty Item ParentAction::target This property holds a target item to reparent. In the following example, \c myItem will be reparented by the ParentAction, while \c myOtherItem will not. \qml State { ParentChange { target: myItem parent: newParent } ParentChange { target: myOtherItem parent: otherNewParent } } Transition { SequentialAnimation { PropertyAnimation { ... } ParentAction { target: myItem } PropertyAnimation { ... } } } \endqml */ QDeclarativeItem *QDeclarativeParentAction::object() const { Q_D(const QDeclarativeParentAction); return d->pcTarget; } void QDeclarativeParentAction::setObject(QDeclarativeItem *target) { Q_D(QDeclarativeParentAction); d->pcTarget = target; } /*! \qmlproperty Item ParentAction::parent The item to reparent to (i.e. the new parent). */ QDeclarativeItem *QDeclarativeParentAction::parent() const { Q_D(const QDeclarativeParentAction); return d->pcParent; } void QDeclarativeParentAction::setParent(QDeclarativeItem *parent) { Q_D(QDeclarativeParentAction); d->pcParent = parent; } void QDeclarativeParentActionPrivate::doAction() { QDeclarativeParentChange pc; pc.setObject(pcTarget); pc.setParent(pcParent); pc.execute(); } QAbstractAnimation *QDeclarativeParentAction::qtAnimation() { Q_D(QDeclarativeParentAction); return d->cpa; } void QDeclarativeParentAction::transition(QDeclarativeStateActions &actions, QDeclarativeProperties &modified, TransitionDirection direction) { Q_D(QDeclarativeParentAction); Q_UNUSED(modified); Q_UNUSED(direction); struct QDeclarativeParentActionData : public QAbstractAnimationAction { QDeclarativeParentActionData(): pc(0) {} ~QDeclarativeParentActionData() { delete pc; } QDeclarativeStateActions actions; bool reverse; QDeclarativeParentChange *pc; virtual void doAction() { for (int ii = 0; ii < actions.count(); ++ii) { const QDeclarativeAction &action = actions.at(ii); if (reverse) action.event->reverse(); else action.event->execute(); } } }; QDeclarativeParentActionData *data = new QDeclarativeParentActionData; //### need to correctly handle modified/done bool hasExplicit = false; if (d->pcTarget && d->pcParent) { data->reverse = false; QDeclarativeAction myAction; QDeclarativeParentChange *pc = new QDeclarativeParentChange; pc->setObject(d->pcTarget); pc->setParent(d->pcParent); myAction.event = pc; data->pc = pc; data->actions << myAction; hasExplicit = true; } if (!hasExplicit) for (int ii = 0; ii < actions.count(); ++ii) { QDeclarativeAction &action = actions[ii]; if (action.event && action.event->typeName() == QLatin1String("ParentChange") && (!d->pcTarget || static_cast(action.event)->object() == d->pcTarget)) { QDeclarativeAction myAction = action; data->reverse = action.reverseEvent; //### this logic differs from PropertyAnimation // (probably a result of modified vs. done) if (d->pcParent) { //### should we disallow this case? QDeclarativeParentChange *pc = new QDeclarativeParentChange; pc->setObject(d->pcTarget); pc->setParent(static_cast(action.event)->parent()); myAction.event = pc; data->pc = pc; data->actions << myAction; break; //only match one } else { action.actionDone = true; data->actions << myAction; } } } if (data->actions.count()) { d->cpa->setAnimAction(data, QAbstractAnimation::DeleteWhenStopped); } else { delete data; } } /*! \qmlclass NumberAnimation QDeclarativeNumberAnimation \since 4.7 \inherits PropertyAnimation \brief The NumberAnimation element allows you to animate changes in properties of type qreal. Animate a set of properties over 200ms, from their values in the start state to their values in the end state of the transition: \code NumberAnimation { properties: "x,y,scale"; duration: 200 } \endcode */ /*! \internal \class QDeclarativeNumberAnimation */ QDeclarativeNumberAnimation::QDeclarativeNumberAnimation(QObject *parent) : QDeclarativePropertyAnimation(parent) { Q_D(QDeclarativePropertyAnimation); d->interpolatorType = QMetaType::QReal; d->interpolator = QVariantAnimationPrivate::getInterpolator(d->interpolatorType); } QDeclarativeNumberAnimation::~QDeclarativeNumberAnimation() { } /*! \qmlproperty real NumberAnimation::from This property holds the starting value. If not set, then the value defined in the start state of the transition. */ qreal QDeclarativeNumberAnimation::from() const { Q_D(const QDeclarativePropertyAnimation); return d->from.toReal(); } void QDeclarativeNumberAnimation::setFrom(qreal f) { QDeclarativePropertyAnimation::setFrom(f); } /*! \qmlproperty real NumberAnimation::to This property holds the ending value. If not set, then the value defined in the end state of the transition or Behavior. */ qreal QDeclarativeNumberAnimation::to() const { Q_D(const QDeclarativePropertyAnimation); return d->to.toReal(); } void QDeclarativeNumberAnimation::setTo(qreal t) { QDeclarativePropertyAnimation::setTo(t); } /*! \qmlclass Vector3dAnimation QDeclarativeVector3dAnimation \since 4.7 \inherits PropertyAnimation \brief The Vector3dAnimation element allows you to animate changes in properties of type QVector3d. */ /*! \internal \class QDeclarativeVector3dAnimation */ QDeclarativeVector3dAnimation::QDeclarativeVector3dAnimation(QObject *parent) : QDeclarativePropertyAnimation(parent) { Q_D(QDeclarativePropertyAnimation); d->interpolatorType = QMetaType::QVector3D; d->interpolator = QVariantAnimationPrivate::getInterpolator(d->interpolatorType); d->defaultToInterpolatorType = true; } QDeclarativeVector3dAnimation::~QDeclarativeVector3dAnimation() { } /*! \qmlproperty real Vector3dAnimation::from This property holds the starting value. If not set, then the value defined in the start state of the transition. */ QVector3D QDeclarativeVector3dAnimation::from() const { Q_D(const QDeclarativePropertyAnimation); return d->from.value(); } void QDeclarativeVector3dAnimation::setFrom(QVector3D f) { QDeclarativePropertyAnimation::setFrom(f); } /*! \qmlproperty real Vector3dAnimation::to This property holds the ending value. If not set, then the value defined in the end state of the transition or Behavior. */ QVector3D QDeclarativeVector3dAnimation::to() const { Q_D(const QDeclarativePropertyAnimation); return d->to.value(); } void QDeclarativeVector3dAnimation::setTo(QVector3D t) { QDeclarativePropertyAnimation::setTo(t); } /*! \qmlclass RotationAnimation QDeclarativeRotationAnimation \since 4.7 \inherits PropertyAnimation \brief The RotationAnimation element allows you to animate rotations. RotationAnimation is a specialized PropertyAnimation that gives control over the direction of rotation. The RotationAnimation in the following example ensures that we always take the shortest rotation path when switching between our states. \qml states: { State { name: "180"; PropertyChanges { target: myItem; rotation: 180 } } State { name: "-180"; PropertyChanges { target: myItem; rotation: -180 } } State { name: "180"; PropertyChanges { target: myItem; rotation: 270 } } } transition: Transition { RotationAnimation { direction: RotationAnimation.Shortest } } \endqml By default, when used in a transition RotationAnimation will rotate all properties named "rotation" or "angle". You can override this by providing your own properties via \c properties or \c property. */ /*! \internal \class QDeclarativeRotationAnimation */ QVariant _q_interpolateShortestRotation(qreal &f, qreal &t, qreal progress) { qreal newt = t; qreal diff = t-f; while(diff > 180.0){ newt -= 360.0; diff -= 360.0; } while(diff < -180.0){ newt += 360.0; diff += 360.0; } return QVariant(f + (newt - f) * progress); } QVariant _q_interpolateClockwiseRotation(qreal &f, qreal &t, qreal progress) { qreal newt = t; qreal diff = t-f; while(diff < 0.0){ newt += 360.0; diff += 360.0; } return QVariant(f + (newt - f) * progress); } QVariant _q_interpolateCounterclockwiseRotation(qreal &f, qreal &t, qreal progress) { qreal newt = t; qreal diff = t-f; while(diff > 0.0){ newt -= 360.0; diff -= 360.0; } return QVariant(f + (newt - f) * progress); } QDeclarativeRotationAnimation::QDeclarativeRotationAnimation(QObject *parent) : QDeclarativePropertyAnimation(*(new QDeclarativeRotationAnimationPrivate), parent) { Q_D(QDeclarativeRotationAnimation); d->interpolatorType = QMetaType::QReal; d->interpolator = reinterpret_cast(&_q_interpolateShortestRotation); d->defaultProperties = QLatin1String("rotation,angle"); } QDeclarativeRotationAnimation::~QDeclarativeRotationAnimation() { } /*! \qmlproperty real RotationAnimation::from This property holds the starting value. If not set, then the value defined in the start state of the transition. */ qreal QDeclarativeRotationAnimation::from() const { Q_D(const QDeclarativeRotationAnimation); return d->from.toReal(); } void QDeclarativeRotationAnimation::setFrom(qreal f) { QDeclarativePropertyAnimation::setFrom(f); } /*! \qmlproperty real RotationAnimation::to This property holds the ending value. If not set, then the value defined in the end state of the transition or Behavior. */ qreal QDeclarativeRotationAnimation::to() const { Q_D(const QDeclarativeRotationAnimation); return d->to.toReal(); } void QDeclarativeRotationAnimation::setTo(qreal t) { QDeclarativePropertyAnimation::setTo(t); } /*! \qmlproperty enum RotationAnimation::direction The direction in which to rotate. Possible values are Numerical, Clockwise, Counterclockwise, or Shortest. \table \row \o Numerical \o Rotate by linearly interpolating between the two numbers. A rotation from 10 to 350 will rotate 340 degrees clockwise. \row \o Clockwise \o Rotate clockwise between the two values \row \o Counterclockwise \o Rotate counterclockwise between the two values \row \o Shortest \o Rotate in the direction that produces the shortest animation path. A rotation from 10 to 350 will rotate 20 degrees counterclockwise. \endtable The default direction is Shortest. */ QDeclarativeRotationAnimation::RotationDirection QDeclarativeRotationAnimation::direction() const { Q_D(const QDeclarativeRotationAnimation); return d->direction; } void QDeclarativeRotationAnimation::setDirection(QDeclarativeRotationAnimation::RotationDirection direction) { Q_D(QDeclarativeRotationAnimation); if (d->direction == direction) return; d->direction = direction; switch(d->direction) { case Clockwise: d->interpolator = reinterpret_cast(&_q_interpolateClockwiseRotation); break; case Counterclockwise: d->interpolator = reinterpret_cast(&_q_interpolateCounterclockwiseRotation); break; case Shortest: d->interpolator = reinterpret_cast(&_q_interpolateShortestRotation); break; default: d->interpolator = QVariantAnimationPrivate::getInterpolator(d->interpolatorType); break; } emit directionChanged(); } QDeclarativeAnimationGroup::QDeclarativeAnimationGroup(QObject *parent) : QDeclarativeAbstractAnimation(*(new QDeclarativeAnimationGroupPrivate), parent) { } QDeclarativeAnimationGroup::QDeclarativeAnimationGroup(QDeclarativeAnimationGroupPrivate &dd, QObject *parent) : QDeclarativeAbstractAnimation(dd, parent) { } void QDeclarativeAnimationGroupPrivate::append_animation(QDeclarativeListProperty *list, QDeclarativeAbstractAnimation *a) { QDeclarativeAnimationGroup *q = qobject_cast(list->object); if (q) { q->d_func()->animations.append(a); a->setGroup(q); q->d_func()->ag->addAnimation(a->qtAnimation()); } } void QDeclarativeAnimationGroupPrivate::clear_animation(QDeclarativeListProperty *list) { QDeclarativeAnimationGroup *q = qobject_cast(list->object); if (q) { for (int i = 0; i < q->d_func()->animations.count(); ++i) q->d_func()->animations.at(i)->setGroup(0); q->d_func()->animations.clear(); } } QDeclarativeAnimationGroup::~QDeclarativeAnimationGroup() { } QDeclarativeListProperty QDeclarativeAnimationGroup::animations() { Q_D(QDeclarativeAnimationGroup); QDeclarativeListProperty list(this, d->animations); list.append = &QDeclarativeAnimationGroupPrivate::append_animation; list.clear = &QDeclarativeAnimationGroupPrivate::clear_animation; return list; } /*! \qmlclass SequentialAnimation QDeclarativeSequentialAnimation \since 4.7 \inherits Animation \brief The SequentialAnimation element allows you to run animations sequentially. Animations controlled in SequentialAnimation will be run one after the other. The following example chains two numeric animations together. The \c MyItem object will animate from its current x position to 100, and then back to 0. \code SequentialAnimation { NumberAnimation { target: MyItem; property: "x"; to: 100 } NumberAnimation { target: MyItem; property: "x"; to: 0 } } \endcode \sa ParallelAnimation */ QDeclarativeSequentialAnimation::QDeclarativeSequentialAnimation(QObject *parent) : QDeclarativeAnimationGroup(parent) { Q_D(QDeclarativeAnimationGroup); d->ag = new QSequentialAnimationGroup; QDeclarative_setParent_noEvent(d->ag, this); } QDeclarativeSequentialAnimation::~QDeclarativeSequentialAnimation() { } QAbstractAnimation *QDeclarativeSequentialAnimation::qtAnimation() { Q_D(QDeclarativeAnimationGroup); return d->ag; } void QDeclarativeSequentialAnimation::transition(QDeclarativeStateActions &actions, QDeclarativeProperties &modified, TransitionDirection direction) { Q_D(QDeclarativeAnimationGroup); int inc = 1; int from = 0; if (direction == Backward) { inc = -1; from = d->animations.count() - 1; } bool valid = d->defaultProperty.isValid(); for (int ii = from; ii < d->animations.count() && ii >= 0; ii += inc) { if (valid) d->animations.at(ii)->setDefaultTarget(d->defaultProperty); d->animations.at(ii)->transition(actions, modified, direction); } } /*! \qmlclass ParallelAnimation QDeclarativeParallelAnimation \since 4.7 \inherits Animation \brief The ParallelAnimation element allows you to run animations in parallel. Animations contained in ParallelAnimation will be run at the same time. The following animation demonstrates animating the \c MyItem item to (100,100) by animating the x and y properties in parallel. \code ParallelAnimation { NumberAnimation { target: MyItem; property: "x"; to: 100 } NumberAnimation { target: MyItem; property: "y"; to: 100 } } \endcode \sa SequentialAnimation */ /*! \internal \class QDeclarativeParallelAnimation */ QDeclarativeParallelAnimation::QDeclarativeParallelAnimation(QObject *parent) : QDeclarativeAnimationGroup(parent) { Q_D(QDeclarativeAnimationGroup); d->ag = new QParallelAnimationGroup; QDeclarative_setParent_noEvent(d->ag, this); } QDeclarativeParallelAnimation::~QDeclarativeParallelAnimation() { } QAbstractAnimation *QDeclarativeParallelAnimation::qtAnimation() { Q_D(QDeclarativeAnimationGroup); return d->ag; } void QDeclarativeParallelAnimation::transition(QDeclarativeStateActions &actions, QDeclarativeProperties &modified, TransitionDirection direction) { Q_D(QDeclarativeAnimationGroup); bool valid = d->defaultProperty.isValid(); for (int ii = 0; ii < d->animations.count(); ++ii) { if (valid) d->animations.at(ii)->setDefaultTarget(d->defaultProperty); d->animations.at(ii)->transition(actions, modified, direction); } } //convert a variant from string type to another animatable type void QDeclarativePropertyAnimationPrivate::convertVariant(QVariant &variant, int type) { if (variant.userType() != QVariant::String) { variant.convert((QVariant::Type)type); return; } switch (type) { case QVariant::Rect: { variant.setValue(QDeclarativeStringConverters::rectFFromString(variant.toString()).toRect()); break; } case QVariant::RectF: { variant.setValue(QDeclarativeStringConverters::rectFFromString(variant.toString())); break; } case QVariant::Point: { variant.setValue(QDeclarativeStringConverters::pointFFromString(variant.toString()).toPoint()); break; } case QVariant::PointF: { variant.setValue(QDeclarativeStringConverters::pointFFromString(variant.toString())); break; } case QVariant::Size: { variant.setValue(QDeclarativeStringConverters::sizeFFromString(variant.toString()).toSize()); break; } case QVariant::SizeF: { variant.setValue(QDeclarativeStringConverters::sizeFFromString(variant.toString())); break; } case QVariant::Color: { variant.setValue(QDeclarativeStringConverters::colorFromString(variant.toString())); break; } case QVariant::Vector3D: { variant.setValue(QDeclarativeStringConverters::vector3DFromString(variant.toString())); break; } default: if (QDeclarativeValueTypeFactory::isValueType((uint)type)) { variant.convert((QVariant::Type)type); } else { QDeclarativeMetaType::StringConverter converter = QDeclarativeMetaType::customStringConverter(type); if (converter) variant = converter(variant.toString()); } break; } } /*! \qmlclass PropertyAnimation QDeclarativePropertyAnimation \since 4.7 \inherits Animation \brief The PropertyAnimation element allows you to animate property changes. PropertyAnimation provides a way to animate changes to a property's value. It can be used in many different situations: \list \o In a Transition Animate any objects that have changed their x or y properties in the target state using an InOutQuad easing curve: \qml Transition { PropertyAnimation { properties: "x,y"; easing.type: "InOutQuad" } } \endqml \o In a Behavior Animate all changes to a rectangle's x property. \qml Rectangle { Behavior on x { PropertyAnimation {} } } \endqml \o As a property value source Repeatedly animate the rectangle's x property. \qml Rectangle { SequentialAnimation on x { repeat: true PropertyAnimation { to: 50 } PropertyAnimation { to: 0 } } } \endqml \o In a signal handler Fade out \c theObject when clicked: \qml MouseArea { anchors.fill: theObject onClicked: PropertyAnimation { target: theObject; property: "opacity"; to: 0 } } \endqml \o Standalone Animate \c theObject's size property over 200ms, from its current size to 20-by-20: \qml PropertyAnimation { target: theObject; property: "size"; to: "20x20"; duration: 200 } \endqml \endlist Depending on how the animation is used, the set of properties normally used will be different. For more information see the individual property documentation, as well as the \l{QML Animation} introduction. */ QDeclarativePropertyAnimation::QDeclarativePropertyAnimation(QObject *parent) : QDeclarativeAbstractAnimation(*(new QDeclarativePropertyAnimationPrivate), parent) { Q_D(QDeclarativePropertyAnimation); d->init(); } QDeclarativePropertyAnimation::QDeclarativePropertyAnimation(QDeclarativePropertyAnimationPrivate &dd, QObject *parent) : QDeclarativeAbstractAnimation(dd, parent) { Q_D(QDeclarativePropertyAnimation); d->init(); } QDeclarativePropertyAnimation::~QDeclarativePropertyAnimation() { } void QDeclarativePropertyAnimationPrivate::init() { Q_Q(QDeclarativePropertyAnimation); va = new QDeclarativeBulkValueAnimator; QDeclarative_setParent_noEvent(va, q); } /*! \qmlproperty int PropertyAnimation::duration This property holds the duration of the transition, in milliseconds. The default value is 250. */ int QDeclarativePropertyAnimation::duration() const { Q_D(const QDeclarativePropertyAnimation); return d->va->duration(); } void QDeclarativePropertyAnimation::setDuration(int duration) { if (duration < 0) { qmlInfo(this) << tr("Cannot set a duration of < 0"); return; } Q_D(QDeclarativePropertyAnimation); if (d->va->duration() == duration) return; d->va->setDuration(duration); emit durationChanged(duration); } /*! \qmlproperty real PropertyAnimation::from This property holds the starting value. If not set, then the value defined in the start state of the transition. */ QVariant QDeclarativePropertyAnimation::from() const { Q_D(const QDeclarativePropertyAnimation); return d->from; } void QDeclarativePropertyAnimation::setFrom(const QVariant &f) { Q_D(QDeclarativePropertyAnimation); if (d->fromIsDefined && f == d->from) return; d->from = f; d->fromIsDefined = f.isValid(); emit fromChanged(f); } /*! \qmlproperty real PropertyAnimation::to This property holds the ending value. If not set, then the value defined in the end state of the transition or Behavior. */ QVariant QDeclarativePropertyAnimation::to() const { Q_D(const QDeclarativePropertyAnimation); return d->to; } void QDeclarativePropertyAnimation::setTo(const QVariant &t) { Q_D(QDeclarativePropertyAnimation); if (d->toIsDefined && t == d->to) return; d->to = t; d->toIsDefined = t.isValid(); emit toChanged(t); } /*! \qmlproperty QEasingCurve PropertyAnimation::easing \brief the easing curve used for the transition. For the easing you can specify the following parameters: type, amplitude, period and overshoot. \qml PropertyAnimation { properties: "y"; easing.type: "InOutElastc"; easing.amplitude: 2.0; easing.period: 1.5 } \endqml Available types are: \table \row \o \c Linear \o Easing curve for a linear (t) function: velocity is constant. \o \inlineimage qeasingcurve-linear.png \row \o \c InQuad \o Easing curve for a quadratic (t^2) function: accelerating from zero velocity. \o \inlineimage qeasingcurve-inquad.png \row \o \c OutQuad \o Easing curve for a quadratic (t^2) function: decelerating to zero velocity. \o \inlineimage qeasingcurve-outquad.png \row \o \c InOutQuad \o Easing curve for a quadratic (t^2) function: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutquad.png \row \o \c OutInQuad \o Easing curve for a quadratic (t^2) function: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outinquad.png \row \o \c InCubic \o Easing curve for a cubic (t^3) function: accelerating from zero velocity. \o \inlineimage qeasingcurve-incubic.png \row \o \c OutCubic \o Easing curve for a cubic (t^3) function: decelerating from zero velocity. \o \inlineimage qeasingcurve-outcubic.png \row \o \c InOutCubic \o Easing curve for a cubic (t^3) function: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutcubic.png \row \o \c OutInCubic \o Easing curve for a cubic (t^3) function: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outincubic.png \row \o \c InQuart \o Easing curve for a quartic (t^4) function: accelerating from zero velocity. \o \inlineimage qeasingcurve-inquart.png \row \o \c OutQuart \o Easing curve for a cubic (t^4) function: decelerating from zero velocity. \o \inlineimage qeasingcurve-outquart.png \row \o \c InOutQuart \o Easing curve for a cubic (t^4) function: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutquart.png \row \o \c OutInQuart \o Easing curve for a cubic (t^4) function: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outinquart.png \row \o \c InQuint \o Easing curve for a quintic (t^5) function: accelerating from zero velocity. \o \inlineimage qeasingcurve-inquint.png \row \o \c OutQuint \o Easing curve for a cubic (t^5) function: decelerating from zero velocity. \o \inlineimage qeasingcurve-outquint.png \row \o \c InOutQuint \o Easing curve for a cubic (t^5) function: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutquint.png \row \o \c OutInQuint \o Easing curve for a cubic (t^5) function: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outinquint.png \row \o \c InSine \o Easing curve for a sinusoidal (sin(t)) function: accelerating from zero velocity. \o \inlineimage qeasingcurve-insine.png \row \o \c OutSine \o Easing curve for a sinusoidal (sin(t)) function: decelerating from zero velocity. \o \inlineimage qeasingcurve-outsine.png \row \o \c InOutSine \o Easing curve for a sinusoidal (sin(t)) function: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutsine.png \row \o \c OutInSine \o Easing curve for a sinusoidal (sin(t)) function: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outinsine.png \row \o \c InExpo \o Easing curve for an exponential (2^t) function: accelerating from zero velocity. \o \inlineimage qeasingcurve-inexpo.png \row \o \c OutExpo \o Easing curve for an exponential (2^t) function: decelerating from zero velocity. \o \inlineimage qeasingcurve-outexpo.png \row \o \c InOutExpo \o Easing curve for an exponential (2^t) function: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutexpo.png \row \o \c OutInExpo \o Easing curve for an exponential (2^t) function: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outinexpo.png \row \o \c InCirc \o Easing curve for a circular (sqrt(1-t^2)) function: accelerating from zero velocity. \o \inlineimage qeasingcurve-incirc.png \row \o \c OutCirc \o Easing curve for a circular (sqrt(1-t^2)) function: decelerating from zero velocity. \o \inlineimage qeasingcurve-outcirc.png \row \o \c InOutCirc \o Easing curve for a circular (sqrt(1-t^2)) function: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutcirc.png \row \o \c OutInCirc \o Easing curve for a circular (sqrt(1-t^2)) function: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outincirc.png \row \o \c InElastic \o Easing curve for an elastic (exponentially decaying sine wave) function: accelerating from zero velocity. \br The peak amplitude can be set with the \e amplitude parameter, and the period of decay by the \e period parameter. \o \inlineimage qeasingcurve-inelastic.png \row \o \c OutElastic \o Easing curve for an elastic (exponentially decaying sine wave) function: decelerating from zero velocity. \br The peak amplitude can be set with the \e amplitude parameter, and the period of decay by the \e period parameter. \o \inlineimage qeasingcurve-outelastic.png \row \o \c InOutElastic \o Easing curve for an elastic (exponentially decaying sine wave) function: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutelastic.png \row \o \c OutInElastic \o Easing curve for an elastic (exponentially decaying sine wave) function: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outinelastic.png \row \o \c InBack \o Easing curve for a back (overshooting cubic function: (s+1)*t^3 - s*t^2) easing in: accelerating from zero velocity. \o \inlineimage qeasingcurve-inback.png \row \o \c OutBack \o Easing curve for a back (overshooting cubic function: (s+1)*t^3 - s*t^2) easing out: decelerating to zero velocity. \o \inlineimage qeasingcurve-outback.png \row \o \c InOutBack \o Easing curve for a back (overshooting cubic function: (s+1)*t^3 - s*t^2) easing in/out: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutback.png \row \o \c OutInBack \o Easing curve for a back (overshooting cubic easing: (s+1)*t^3 - s*t^2) easing out/in: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outinback.png \row \o \c InBounce \o Easing curve for a bounce (exponentially decaying parabolic bounce) function: accelerating from zero velocity. \o \inlineimage qeasingcurve-inbounce.png \row \o \c OutBounce \o Easing curve for a bounce (exponentially decaying parabolic bounce) function: decelerating from zero velocity. \o \inlineimage qeasingcurve-outbounce.png \row \o \c InOutBounce \o Easing curve for a bounce (exponentially decaying parabolic bounce) function easing in/out: acceleration until halfway, then deceleration. \o \inlineimage qeasingcurve-inoutbounce.png \row \o \c OutInBounce \o Easing curve for a bounce (exponentially decaying parabolic bounce) function easing out/in: deceleration until halfway, then acceleration. \o \inlineimage qeasingcurve-outinbounce.png \endtable easing.amplitude is not applicable for all curve types. It is only applicable for bounce and elastic curves (curves of type QEasingCurve::InBounce, QEasingCurve::OutBounce, QEasingCurve::InOutBounce, QEasingCurve::OutInBounce, QEasingCurve::InElastic, QEasingCurve::OutElastic, QEasingCurve::InOutElastic or QEasingCurve::OutInElastic). easing.overshoot is not applicable for all curve types. It is only applicable if type is: QEasingCurve::InBack, QEasingCurve::OutBack, QEasingCurve::InOutBack or QEasingCurve::OutInBack. easing.period is not applicable for all curve types. It is only applicable if type is: QEasingCurve::InElastic, QEasingCurve::OutElastic, QEasingCurve::InOutElastic or QEasingCurve::OutInElastic. */ QEasingCurve QDeclarativePropertyAnimation::easing() const { Q_D(const QDeclarativePropertyAnimation); return d->easing; } void QDeclarativePropertyAnimation::setEasing(const QEasingCurve &e) { Q_D(QDeclarativePropertyAnimation); if (d->easing == e) return; d->easing = e; d->va->setEasingCurve(d->easing); emit easingChanged(e); } QObject *QDeclarativePropertyAnimation::target() const { Q_D(const QDeclarativePropertyAnimation); return d->target; } void QDeclarativePropertyAnimation::setTarget(QObject *o) { Q_D(QDeclarativePropertyAnimation); if (d->target == o) return; d->target = o; emit targetChanged(d->target, d->propertyName); } QString QDeclarativePropertyAnimation::property() const { Q_D(const QDeclarativePropertyAnimation); return d->propertyName; } void QDeclarativePropertyAnimation::setProperty(const QString &n) { Q_D(QDeclarativePropertyAnimation); if (d->propertyName == n) return; d->propertyName = n; emit targetChanged(d->target, d->propertyName); } QString QDeclarativePropertyAnimation::properties() const { Q_D(const QDeclarativePropertyAnimation); return d->properties; } void QDeclarativePropertyAnimation::setProperties(const QString &prop) { Q_D(QDeclarativePropertyAnimation); if (d->properties == prop) return; d->properties = prop; emit propertiesChanged(prop); } /*! \qmlproperty string PropertyAnimation::property \qmlproperty string PropertyAnimation::properties \qmlproperty Object PropertyAnimation::target \qmlproperty list PropertyAnimation::targets These properties are used as a set to determine which properties should be animated. The singular and plural forms are functionally identical, e.g. \qml NumberAnimation { target: theItem; property: "x"; to: 500 } \endqml has the same meaning as \qml NumberAnimation { targets: theItem; properties: "x"; to: 500 } \endqml The singular forms are slightly optimized, so if you do have only a single target/property to animate you should try to use them. In many cases these properties do not need to be explicitly specified -- they can be inferred from the animation framework. \table 80% \row \o Value Source / Behavior \o When an animation is used as a value source or in a Behavior, the default target and property name to be animated can both be inferred. \qml Rectangle { id: theRect width: 100; height: 100 color: Qt.rgba(0,0,1) NumberAnimation on x { to: 500; repeat: true } //animate theRect's x property Behavior on y { NumberAnimation {} } //animate theRect's y property } \endqml \row \o Transition \o When used in a transition, a property animation is assumed to match \e all targets but \e no properties. In practice, that means you need to specify at least the properties in order for the animation to do anything. \qml Rectangle { id: theRect width: 100; height: 100 color: Qt.rgba(0,0,1) Item { id: uselessItem } states: State { name: "state1" PropertyChanges { target: theRect; x: 200; y: 200; z: 4 } PropertyChanges { target: uselessItem; x: 10; y: 10; z: 2 } } transitions: Transition { //animate both theRect's and uselessItem's x and y to their final values NumberAnimation { properties: "x,y" } //animate theRect's z to its final value NumberAnimation { target: theRect; property: "z" } } } \endqml \row \o Standalone \o When an animation is used standalone, both the target and property need to be explicitly specified. \qml Rectangle { id: theRect width: 100; height: 100 color: Qt.rgba(0,0,1) //need to explicitly specify target and property NumberAnimation { id: theAnim; target: theRect; property: "x" to: 500 } MouseArea { anchors.fill: parent onClicked: theAnim.start() } } \endqml \endtable As seen in the above example, properties is specified as a comma-separated string of property names to animate. \sa exclude */ QDeclarativeListProperty QDeclarativePropertyAnimation::targets() { Q_D(QDeclarativePropertyAnimation); return QDeclarativeListProperty(this, d->targets); } /*! \qmlproperty list PropertyAnimation::exclude This property holds the items not to be affected by this animation. \sa targets */ QDeclarativeListProperty QDeclarativePropertyAnimation::exclude() { Q_D(QDeclarativePropertyAnimation); return QDeclarativeListProperty(this, d->exclude); } QAbstractAnimation *QDeclarativePropertyAnimation::qtAnimation() { Q_D(QDeclarativePropertyAnimation); return d->va; } struct PropertyUpdater : public QDeclarativeBulkValueUpdater { QDeclarativeStateActions actions; int interpolatorType; //for Number/ColorAnimation int prevInterpolatorType; //for generic QVariantAnimation::Interpolator interpolator; bool reverse; bool fromSourced; bool fromDefined; bool *wasDeleted; PropertyUpdater() : prevInterpolatorType(0), wasDeleted(0) {} ~PropertyUpdater() { if (wasDeleted) *wasDeleted = true; } void setValue(qreal v) { bool deleted = false; wasDeleted = &deleted; if (reverse) //QVariantAnimation sends us 1->0 when reversed, but we are expecting 0->1 v = 1 - v; for (int ii = 0; ii < actions.count(); ++ii) { QDeclarativeAction &action = actions[ii]; if (v == 1.) QDeclarativePropertyPrivate::write(action.property, action.toValue, QDeclarativePropertyPrivate::BypassInterceptor | QDeclarativePropertyPrivate::DontRemoveBinding); else { if (!fromSourced && !fromDefined) { action.fromValue = action.property.read(); if (interpolatorType) QDeclarativePropertyAnimationPrivate::convertVariant(action.fromValue, interpolatorType); } if (!interpolatorType) { int propType = action.property.propertyType(); if (!prevInterpolatorType || prevInterpolatorType != propType) { prevInterpolatorType = propType; interpolator = QVariantAnimationPrivate::getInterpolator(prevInterpolatorType); } } if (interpolator) QDeclarativePropertyPrivate::write(action.property, interpolator(action.fromValue.constData(), action.toValue.constData(), v), QDeclarativePropertyPrivate::BypassInterceptor | QDeclarativePropertyPrivate::DontRemoveBinding); } if (deleted) return; } wasDeleted = 0; fromSourced = true; } }; void QDeclarativePropertyAnimation::transition(QDeclarativeStateActions &actions, QDeclarativeProperties &modified, TransitionDirection direction) { Q_D(QDeclarativePropertyAnimation); QStringList props = d->properties.isEmpty() ? QStringList() : d->properties.split(QLatin1Char(',')); for (int ii = 0; ii < props.count(); ++ii) props[ii] = props.at(ii).trimmed(); if (!d->propertyName.isEmpty()) props << d->propertyName; QList targets = d->targets; if (d->target) targets.append(d->target); bool hasSelectors = !props.isEmpty() || !targets.isEmpty() || !d->exclude.isEmpty(); bool useType = (props.isEmpty() && d->defaultToInterpolatorType) ? true : false; if (d->defaultProperty.isValid() && !hasSelectors) { props << d->defaultProperty.name(); targets << d->defaultProperty.object(); } if (props.isEmpty() && !d->defaultProperties.isEmpty()) { props << d->defaultProperties.split(QLatin1Char(',')); } PropertyUpdater *data = new PropertyUpdater; data->interpolatorType = d->interpolatorType; data->interpolator = d->interpolator; data->reverse = direction == Backward ? true : false; data->fromSourced = false; data->fromDefined = d->fromIsDefined; bool hasExplicit = false; //an explicit animation has been specified if (d->toIsDefined) { for (int i = 0; i < props.count(); ++i) { for (int j = 0; j < targets.count(); ++j) { QDeclarativeAction myAction; myAction.property = d->createProperty(targets.at(j), props.at(i), this); if (myAction.property.isValid()) { if (d->fromIsDefined) { myAction.fromValue = d->from; d->convertVariant(myAction.fromValue, d->interpolatorType ? d->interpolatorType : myAction.property.propertyType()); } myAction.toValue = d->to; d->convertVariant(myAction.toValue, d->interpolatorType ? d->interpolatorType : myAction.property.propertyType()); data->actions << myAction; hasExplicit = true; for (int ii = 0; ii < actions.count(); ++ii) { QDeclarativeAction &action = actions[ii]; if (action.property.object() == myAction.property.object() && myAction.property.name() == action.property.name()) { modified << action.property; break; //### any chance there could be multiples? } } } } } } if (!hasExplicit) for (int ii = 0; ii < actions.count(); ++ii) { QDeclarativeAction &action = actions[ii]; QObject *obj = action.property.object(); QString propertyName = action.property.name(); QObject *sObj = action.specifiedObject; QString sPropertyName = action.specifiedProperty; bool same = (obj == sObj); if ((targets.isEmpty() || targets.contains(obj) || (!same && targets.contains(sObj))) && (!d->exclude.contains(obj)) && (same || (!d->exclude.contains(sObj))) && (props.contains(propertyName) || (!same && props.contains(sPropertyName)) || (useType && action.property.propertyType() == d->interpolatorType))) { QDeclarativeAction myAction = action; if (d->fromIsDefined) myAction.fromValue = d->from; else myAction.fromValue = QVariant(); if (d->toIsDefined) myAction.toValue = d->to; d->convertVariant(myAction.fromValue, d->interpolatorType ? d->interpolatorType : myAction.property.propertyType()); d->convertVariant(myAction.toValue, d->interpolatorType ? d->interpolatorType : myAction.property.propertyType()); modified << action.property; data->actions << myAction; action.fromValue = myAction.toValue; } } if (data->actions.count()) { if (!d->rangeIsSet) { d->va->setStartValue(qreal(0)); d->va->setEndValue(qreal(1)); d->rangeIsSet = true; } d->va->setAnimValue(data, QAbstractAnimation::DeleteWhenStopped); d->va->setFromSourcedValue(&data->fromSourced); } else { delete data; } } QDeclarativeParentAnimation::QDeclarativeParentAnimation(QObject *parent) : QDeclarativeAnimationGroup(*(new QDeclarativeParentAnimationPrivate), parent) { Q_D(QDeclarativeParentAnimation); d->topLevelGroup = new QSequentialAnimationGroup; QDeclarative_setParent_noEvent(d->topLevelGroup, this); d->startAction = new QActionAnimation; d->topLevelGroup->addAnimation(d->startAction); d->ag = new QParallelAnimationGroup; d->topLevelGroup->addAnimation(d->ag); d->endAction = new QActionAnimation; d->topLevelGroup->addAnimation(d->endAction); } QDeclarativeParentAnimation::~QDeclarativeParentAnimation() { } QDeclarativeItem *QDeclarativeParentAnimation::target() const { Q_D(const QDeclarativeParentAnimation); return d->target; } void QDeclarativeParentAnimation::setTarget(QDeclarativeItem *target) { Q_D(QDeclarativeParentAnimation); d->target = target; } QDeclarativeItem *QDeclarativeParentAnimation::newParent() const { Q_D(const QDeclarativeParentAnimation); return d->newParent; } void QDeclarativeParentAnimation::setNewParent(QDeclarativeItem *newParent) { Q_D(QDeclarativeParentAnimation); d->newParent = newParent; } QDeclarativeItem *QDeclarativeParentAnimation::via() const { Q_D(const QDeclarativeParentAnimation); return d->via; } void QDeclarativeParentAnimation::setVia(QDeclarativeItem *via) { Q_D(QDeclarativeParentAnimation); d->via = via; } //### mirrors same-named function in QDeclarativeItem QPointF QDeclarativeParentAnimationPrivate::computeTransformOrigin(QDeclarativeItem::TransformOrigin origin, qreal width, qreal height) const { switch(origin) { default: case QDeclarativeItem::TopLeft: return QPointF(0, 0); case QDeclarativeItem::Top: return QPointF(width / 2., 0); case QDeclarativeItem::TopRight: return QPointF(width, 0); case QDeclarativeItem::Left: return QPointF(0, height / 2.); case QDeclarativeItem::Center: return QPointF(width / 2., height / 2.); case QDeclarativeItem::Right: return QPointF(width, height / 2.); case QDeclarativeItem::BottomLeft: return QPointF(0, height); case QDeclarativeItem::Bottom: return QPointF(width / 2., height); case QDeclarativeItem::BottomRight: return QPointF(width, height); } } void QDeclarativeParentAnimation::transition(QDeclarativeStateActions &actions, QDeclarativeProperties &modified, TransitionDirection direction) { Q_D(QDeclarativeParentAnimation); struct QDeclarativeParentActionData : public QAbstractAnimationAction { QDeclarativeParentActionData(): pc(0) {} ~QDeclarativeParentActionData() { delete pc; } QDeclarativeStateActions actions; bool reverse; QDeclarativeParentChange *pc; virtual void doAction() { for (int ii = 0; ii < actions.count(); ++ii) { const QDeclarativeAction &action = actions.at(ii); if (reverse) action.event->reverse(); else action.event->execute(); } } }; QDeclarativeParentActionData *data = new QDeclarativeParentActionData; QDeclarativeParentActionData *viaData = new QDeclarativeParentActionData; for (int i = 0; i < actions.size(); ++i) { QDeclarativeAction &action = actions[i]; if (action.event && action.event->typeName() == QLatin1String("ParentChange") && (!d->target || static_cast(action.event)->object() == d->target)) { QDeclarativeParentChange *pc = static_cast(action.event); QDeclarativeAction myAction = action; data->reverse = action.reverseEvent; action.actionDone = true; data->actions << myAction; if (d->via) { viaData->reverse = false; QDeclarativeAction myAction; QDeclarativeParentChange *vpc = new QDeclarativeParentChange; vpc->setObject(pc->object()); vpc->setParent(d->via); myAction.event = vpc; viaData->pc = vpc; viaData->actions << myAction; QDeclarativeAction dummyAction; QDeclarativeAction &xAction = pc->xIsSet() ? actions[++i] : dummyAction; QDeclarativeAction &yAction = pc->yIsSet() ? actions[++i] : dummyAction; QDeclarativeAction &sAction = pc->scaleIsSet() ? actions[++i] : dummyAction; QDeclarativeAction &rAction = pc->rotationIsSet() ? actions[++i] : dummyAction; bool forward = (direction == QDeclarativeAbstractAnimation::Forward); QDeclarativeItem *target = pc->object(); QDeclarativeItem *targetParent = forward ? pc->parent() : pc->originalParent(); //### this mirrors the logic in QDeclarativeParentChange. bool ok; const QTransform &transform = targetParent->itemTransform(d->via, &ok); if (transform.type() >= QTransform::TxShear || !ok) { qmlInfo(this) << QDeclarativeParentAnimation::tr("Unable to preserve appearance under complex transform"); ok = false; } qreal scale = 1; qreal rotation = 0; if (ok && transform.type() != QTransform::TxRotate) { if (transform.m11() == transform.m22()) scale = transform.m11(); else { qmlInfo(this) << QDeclarativeParentAnimation::tr("Unable to preserve appearance under non-uniform scale"); ok = false; } } else if (ok && transform.type() == QTransform::TxRotate) { if (transform.m11() == transform.m22()) scale = qSqrt(transform.m11()*transform.m11() + transform.m12()*transform.m12()); else { qmlInfo(this) << QDeclarativeParentAnimation::tr("Unable to preserve appearance under non-uniform scale"); ok = false; } if (scale != 0) rotation = atan2(transform.m12()/scale, transform.m11()/scale) * 180/M_PI; else { qmlInfo(this) << QDeclarativeParentAnimation::tr("Unable to preserve appearance under scale of 0"); ok = false; } } const QPointF &point = transform.map(QPointF(xAction.toValue.toReal(),yAction.toValue.toReal())); qreal x = point.x(); qreal y = point.y(); if (ok && target->transformOrigin() != QDeclarativeItem::TopLeft) { qreal w = target->width(); qreal h = target->height(); if (pc->widthIsSet()) w = actions[++i].toValue.toReal(); if (pc->heightIsSet()) h = actions[++i].toValue.toReal(); const QPointF &transformOrigin = d->computeTransformOrigin(target->transformOrigin(), w,h); qreal tempxt = transformOrigin.x(); qreal tempyt = transformOrigin.y(); QTransform t; t.translate(-tempxt, -tempyt); t.rotate(rotation); t.scale(scale, scale); t.translate(tempxt, tempyt); const QPointF &offset = t.map(QPointF(0,0)); x += offset.x(); y += offset.y(); } if (ok) { //qDebug() << x << y << rotation << scale; xAction.toValue = x; yAction.toValue = y; sAction.toValue = sAction.toValue.toReal() * scale; rAction.toValue = rAction.toValue.toReal() + rotation; } } } } if (data->actions.count()) { if (direction == QDeclarativeAbstractAnimation::Forward) { d->startAction->setAnimAction(d->via ? viaData : data, QActionAnimation::DeleteWhenStopped); d->endAction->setAnimAction(d->via ? data : 0, QActionAnimation::DeleteWhenStopped); } else { d->endAction->setAnimAction(d->via ? viaData : data, QActionAnimation::DeleteWhenStopped); d->startAction->setAnimAction(d->via ? data : 0, QActionAnimation::DeleteWhenStopped); } } else { delete data; delete viaData; } //take care of any child animations bool valid = d->defaultProperty.isValid(); for (int ii = 0; ii < d->animations.count(); ++ii) { if (valid) d->animations.at(ii)->setDefaultTarget(d->defaultProperty); d->animations.at(ii)->transition(actions, modified, direction); } } QAbstractAnimation *QDeclarativeParentAnimation::qtAnimation() { Q_D(QDeclarativeParentAnimation); return d->topLevelGroup; } QT_END_NAMESPACE