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/*
 * Copyright (C) 2010 The Android Open Source Project
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package com.actionbarsherlock.internal.nineoldandroids.animation;

import android.view.animation.Interpolator;

/**
 * This class holds a time/value pair for an animation. The Keyframe class is used
 * by {@link ValueAnimator} to define the values that the animation target will have over the course
 * of the animation. As the time proceeds from one keyframe to the other, the value of the
 * target object will animate between the value at the previous keyframe and the value at the
 * next keyframe. Each keyframe also holds an optional {@link TimeInterpolator}
 * object, which defines the time interpolation over the intervalue preceding the keyframe.
 *
 * 

The Keyframe class itself is abstract. The type-specific factory methods will return * a subclass of Keyframe specific to the type of value being stored. This is done to improve * performance when dealing with the most common cases (e.g., float and * int values). Other types will fall into a more general Keyframe class that * treats its values as Objects. Unless your animation requires dealing with a custom type * or a data structure that needs to be animated directly (and evaluated using an implementation * of {@link TypeEvaluator}), you should stick to using float and int as animations using those * types have lower runtime overhead than other types.

*/ @SuppressWarnings("rawtypes") public abstract class Keyframe implements Cloneable { /** * The time at which mValue will hold true. */ float mFraction; /** * The type of the value in this Keyframe. This type is determined at construction time, * based on the type of the value object passed into the constructor. */ Class mValueType; /** * The optional time interpolator for the interval preceding this keyframe. A null interpolator * (the default) results in linear interpolation over the interval. */ private /*Time*/Interpolator mInterpolator = null; /** * Flag to indicate whether this keyframe has a valid value. This flag is used when an * animation first starts, to populate placeholder keyframes with real values derived * from the target object. */ boolean mHasValue = false; /** * Constructs a Keyframe object with the given time and value. The time defines the * time, as a proportion of an overall animation's duration, at which the value will hold true * for the animation. The value for the animation between keyframes will be calculated as * an interpolation between the values at those keyframes. * * @param fraction The time, expressed as a value between 0 and 1, representing the fraction * of time elapsed of the overall animation duration. * @param value The value that the object will animate to as the animation time approaches * the time in this keyframe, and the the value animated from as the time passes the time in * this keyframe. */ public static Keyframe ofInt(float fraction, int value) { return new IntKeyframe(fraction, value); } /** * Constructs a Keyframe object with the given time. The value at this time will be derived * from the target object when the animation first starts (note that this implies that keyframes * with no initial value must be used as part of an {@link ObjectAnimator}). * The time defines the * time, as a proportion of an overall animation's duration, at which the value will hold true * for the animation. The value for the animation between keyframes will be calculated as * an interpolation between the values at those keyframes. * * @param fraction The time, expressed as a value between 0 and 1, representing the fraction * of time elapsed of the overall animation duration. */ public static Keyframe ofInt(float fraction) { return new IntKeyframe(fraction); } /** * Constructs a Keyframe object with the given time and value. The time defines the * time, as a proportion of an overall animation's duration, at which the value will hold true * for the animation. The value for the animation between keyframes will be calculated as * an interpolation between the values at those keyframes. * * @param fraction The time, expressed as a value between 0 and 1, representing the fraction * of time elapsed of the overall animation duration. * @param value The value that the object will animate to as the animation time approaches * the time in this keyframe, and the the value animated from as the time passes the time in * this keyframe. */ public static Keyframe ofFloat(float fraction, float value) { return new FloatKeyframe(fraction, value); } /** * Constructs a Keyframe object with the given time. The value at this time will be derived * from the target object when the animation first starts (note that this implies that keyframes * with no initial value must be used as part of an {@link ObjectAnimator}). * The time defines the * time, as a proportion of an overall animation's duration, at which the value will hold true * for the animation. The value for the animation between keyframes will be calculated as * an interpolation between the values at those keyframes. * * @param fraction The time, expressed as a value between 0 and 1, representing the fraction * of time elapsed of the overall animation duration. */ public static Keyframe ofFloat(float fraction) { return new FloatKeyframe(fraction); } /** * Constructs a Keyframe object with the given time and value. The time defines the * time, as a proportion of an overall animation's duration, at which the value will hold true * for the animation. The value for the animation between keyframes will be calculated as * an interpolation between the values at those keyframes. * * @param fraction The time, expressed as a value between 0 and 1, representing the fraction * of time elapsed of the overall animation duration. * @param value The value that the object will animate to as the animation time approaches * the time in this keyframe, and the the value animated from as the time passes the time in * this keyframe. */ public static Keyframe ofObject(float fraction, Object value) { return new ObjectKeyframe(fraction, value); } /** * Constructs a Keyframe object with the given time. The value at this time will be derived * from the target object when the animation first starts (note that this implies that keyframes * with no initial value must be used as part of an {@link ObjectAnimator}). * The time defines the * time, as a proportion of an overall animation's duration, at which the value will hold true * for the animation. The value for the animation between keyframes will be calculated as * an interpolation between the values at those keyframes. * * @param fraction The time, expressed as a value between 0 and 1, representing the fraction * of time elapsed of the overall animation duration. */ public static Keyframe ofObject(float fraction) { return new ObjectKeyframe(fraction, null); } /** * Indicates whether this keyframe has a valid value. This method is called internally when * an {@link ObjectAnimator} first starts; keyframes without values are assigned values at * that time by deriving the value for the property from the target object. * * @return boolean Whether this object has a value assigned. */ public boolean hasValue() { return mHasValue; } /** * Gets the value for this Keyframe. * * @return The value for this Keyframe. */ public abstract Object getValue(); /** * Sets the value for this Keyframe. * * @param value value for this Keyframe. */ public abstract void setValue(Object value); /** * Gets the time for this keyframe, as a fraction of the overall animation duration. * * @return The time associated with this keyframe, as a fraction of the overall animation * duration. This should be a value between 0 and 1. */ public float getFraction() { return mFraction; } /** * Sets the time for this keyframe, as a fraction of the overall animation duration. * * @param fraction time associated with this keyframe, as a fraction of the overall animation * duration. This should be a value between 0 and 1. */ public void setFraction(float fraction) { mFraction = fraction; } /** * Gets the optional interpolator for this Keyframe. A value of null indicates * that there is no interpolation, which is the same as linear interpolation. * * @return The optional interpolator for this Keyframe. */ public /*Time*/Interpolator getInterpolator() { return mInterpolator; } /** * Sets the optional interpolator for this Keyframe. A value of null indicates * that there is no interpolation, which is the same as linear interpolation. * * @return The optional interpolator for this Keyframe. */ public void setInterpolator(/*Time*/Interpolator interpolator) { mInterpolator = interpolator; } /** * Gets the type of keyframe. This information is used by ValueAnimator to determine the type of * {@link TypeEvaluator} to use when calculating values between keyframes. The type is based * on the type of Keyframe created. * * @return The type of the value stored in the Keyframe. */ public Class getType() { return mValueType; } @Override public abstract Keyframe clone(); /** * This internal subclass is used for all types which are not int or float. */ static class ObjectKeyframe extends Keyframe { /** * The value of the animation at the time mFraction. */ Object mValue; ObjectKeyframe(float fraction, Object value) { mFraction = fraction; mValue = value; mHasValue = (value != null); mValueType = mHasValue ? value.getClass() : Object.class; } public Object getValue() { return mValue; } public void setValue(Object value) { mValue = value; mHasValue = (value != null); } @Override public ObjectKeyframe clone() { ObjectKeyframe kfClone = new ObjectKeyframe(getFraction(), mValue); kfClone.setInterpolator(getInterpolator()); return kfClone; } } /** * Internal subclass used when the keyframe value is of type int. */ static class IntKeyframe extends Keyframe { /** * The value of the animation at the time mFraction. */ int mValue; IntKeyframe(float fraction, int value) { mFraction = fraction; mValue = value; mValueType = int.class; mHasValue = true; } IntKeyframe(float fraction) { mFraction = fraction; mValueType = int.class; } public int getIntValue() { return mValue; } public Object getValue() { return mValue; } public void setValue(Object value) { if (value != null && value.getClass() == Integer.class) { mValue = ((Integer)value).intValue(); mHasValue = true; } } @Override public IntKeyframe clone() { IntKeyframe kfClone = new IntKeyframe(getFraction(), mValue); kfClone.setInterpolator(getInterpolator()); return kfClone; } } /** * Internal subclass used when the keyframe value is of type float. */ static class FloatKeyframe extends Keyframe { /** * The value of the animation at the time mFraction. */ float mValue; FloatKeyframe(float fraction, float value) { mFraction = fraction; mValue = value; mValueType = float.class; mHasValue = true; } FloatKeyframe(float fraction) { mFraction = fraction; mValueType = float.class; } public float getFloatValue() { return mValue; } public Object getValue() { return mValue; } public void setValue(Object value) { if (value != null && value.getClass() == Float.class) { mValue = ((Float)value).floatValue(); mHasValue = true; } } @Override public FloatKeyframe clone() { FloatKeyframe kfClone = new FloatKeyframe(getFraction(), mValue); kfClone.setInterpolator(getInterpolator()); return kfClone; } } }




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