android/animation/KeyframeSet.java - platform/prebuilts/fullsdk/sources/android-30 - Git at Google

 /*
  * 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 android.animation;

 import android.animation.Keyframe.FloatKeyframe;
 import android.animation.Keyframe.IntKeyframe;
 import android.animation.Keyframe.ObjectKeyframe;
 import android.graphics.Path;
 import android.util.Log;

 import java.util.Arrays;
 import java.util.List;

 /**
  * This class holds a collection of Keyframe objects and is called by ValueAnimator to calculate
  * values between those keyframes for a given animation. The class internal to the animation
  * package because it is an implementation detail of how Keyframes are stored and used.
  * @hide
  */
 public class KeyframeSet implements Keyframes {

     int mNumKeyframes;

     Keyframe mFirstKeyframe;
     Keyframe mLastKeyframe;
     TimeInterpolator mInterpolator; // only used in the 2-keyframe case
     List<Keyframe> mKeyframes; // only used when there are not 2 keyframes
     TypeEvaluator mEvaluator;


     public KeyframeSet(Keyframe... keyframes) {
         mNumKeyframes = keyframes.length;
         // immutable list
         mKeyframes = Arrays.asList(keyframes);
         mFirstKeyframe = keyframes[0];
         mLastKeyframe = keyframes[mNumKeyframes - 1];
         mInterpolator = mLastKeyframe.getInterpolator();
     }

     public List<Keyframe> getKeyframes() {
         return mKeyframes;
     }

     public static KeyframeSet ofInt(int... values) {
         int numKeyframes = values.length;
         IntKeyframe keyframes[] = new IntKeyframe[Math.max(numKeyframes,2)];
         if (numKeyframes == 1) {
             keyframes[0] = (IntKeyframe) Keyframe.ofInt(0f);
             keyframes[1] = (IntKeyframe) Keyframe.ofInt(1f, values[0]);
         } else {
             keyframes[0] = (IntKeyframe) Keyframe.ofInt(0f, values[0]);
             for (int i = 1; i < numKeyframes; ++i) {
                 keyframes[i] =
                         (IntKeyframe) Keyframe.ofInt((float) i / (numKeyframes - 1), values[i]);
             }
         }
         return new IntKeyframeSet(keyframes);
     }

     public static KeyframeSet ofFloat(float... values) {
         boolean badValue = false;
         int numKeyframes = values.length;
         FloatKeyframe keyframes[] = new FloatKeyframe[Math.max(numKeyframes,2)];
         if (numKeyframes == 1) {
             keyframes[0] = (FloatKeyframe) Keyframe.ofFloat(0f);
             keyframes[1] = (FloatKeyframe) Keyframe.ofFloat(1f, values[0]);
             if (Float.isNaN(values[0])) {
                 badValue = true;
             }
         } else {
             keyframes[0] = (FloatKeyframe) Keyframe.ofFloat(0f, values[0]);
             for (int i = 1; i < numKeyframes; ++i) {
                 keyframes[i] =
                         (FloatKeyframe) Keyframe.ofFloat((float) i / (numKeyframes - 1), values[i]);
                 if (Float.isNaN(values[i])) {
                     badValue = true;
                 }
             }
         }
         if (badValue) {
             Log.w("Animator", "Bad value (NaN) in float animator");
         }
         return new FloatKeyframeSet(keyframes);
     }

     public static KeyframeSet ofKeyframe(Keyframe... keyframes) {
         // if all keyframes of same primitive type, create the appropriate KeyframeSet
         int numKeyframes = keyframes.length;
         boolean hasFloat = false;
         boolean hasInt = false;
         boolean hasOther = false;
         for (int i = 0; i < numKeyframes; ++i) {
             if (keyframes[i] instanceof FloatKeyframe) {
                 hasFloat = true;
             } else if (keyframes[i] instanceof IntKeyframe) {
                 hasInt = true;
             } else {
                 hasOther = true;
             }
         }
         if (hasFloat && !hasInt && !hasOther) {
             FloatKeyframe floatKeyframes[] = new FloatKeyframe[numKeyframes];
             for (int i = 0; i < numKeyframes; ++i) {
                 floatKeyframes[i] = (FloatKeyframe) keyframes[i];
             }
             return new FloatKeyframeSet(floatKeyframes);
         } else if (hasInt && !hasFloat && !hasOther) {
             IntKeyframe intKeyframes[] = new IntKeyframe[numKeyframes];
             for (int i = 0; i < numKeyframes; ++i) {
                 intKeyframes[i] = (IntKeyframe) keyframes[i];
             }
             return new IntKeyframeSet(intKeyframes);
         } else {
             return new KeyframeSet(keyframes);
         }
     }

     public static KeyframeSet ofObject(Object... values) {
         int numKeyframes = values.length;
         ObjectKeyframe keyframes[] = new ObjectKeyframe[Math.max(numKeyframes,2)];
         if (numKeyframes == 1) {
             keyframes[0] = (ObjectKeyframe) Keyframe.ofObject(0f);
             keyframes[1] = (ObjectKeyframe) Keyframe.ofObject(1f, values[0]);
         } else {
             keyframes[0] = (ObjectKeyframe) Keyframe.ofObject(0f, values[0]);
             for (int i = 1; i < numKeyframes; ++i) {
                 keyframes[i] = (ObjectKeyframe) Keyframe.ofObject((float) i / (numKeyframes - 1), values[i]);
             }
         }
         return new KeyframeSet(keyframes);
     }

     public static PathKeyframes ofPath(Path path) {
         return new PathKeyframes(path);
     }

     public static PathKeyframes ofPath(Path path, float error) {
         return new PathKeyframes(path, error);
     }

     /**
      * Sets the TypeEvaluator to be used when calculating animated values. This object
      * is required only for KeyframeSets that are not either IntKeyframeSet or FloatKeyframeSet,
      * both of which assume their own evaluator to speed up calculations with those primitive
      * types.
      *
      * @param evaluator The TypeEvaluator to be used to calculate animated values.
      */
     public void setEvaluator(TypeEvaluator evaluator) {
         mEvaluator = evaluator;
     }

     @Override
     public Class getType() {
         return mFirstKeyframe.getType();
     }

     @Override
     public KeyframeSet clone() {
         List<Keyframe> keyframes = mKeyframes;
         int numKeyframes = mKeyframes.size();
         final Keyframe[] newKeyframes = new Keyframe[numKeyframes];
         for (int i = 0; i < numKeyframes; ++i) {
             newKeyframes[i] = keyframes.get(i).clone();
         }
         KeyframeSet newSet = new KeyframeSet(newKeyframes);
         return newSet;
     }

     /**
      * Gets the animated value, given the elapsed fraction of the animation (interpolated by the
      * animation's interpolator) and the evaluator used to calculate in-between values. This
      * function maps the input fraction to the appropriate keyframe interval and a fraction
      * between them and returns the interpolated value. Note that the input fraction may fall
      * outside the [0-1] bounds, if the animation's interpolator made that happen (e.g., a
      * spring interpolation that might send the fraction past 1.0). We handle this situation by
      * just using the two keyframes at the appropriate end when the value is outside those bounds.
      *
      * @param fraction The elapsed fraction of the animation
      * @return The animated value.
      */
     public Object getValue(float fraction) {
         // Special-case optimization for the common case of only two keyframes
         if (mNumKeyframes == 2) {
             if (mInterpolator != null) {
                 fraction = mInterpolator.getInterpolation(fraction);
             }
             return mEvaluator.evaluate(fraction, mFirstKeyframe.getValue(),
                     mLastKeyframe.getValue());
         }
         if (fraction <= 0f) {
             final Keyframe nextKeyframe = mKeyframes.get(1);
             final TimeInterpolator interpolator = nextKeyframe.getInterpolator();
             if (interpolator != null) {
                 fraction = interpolator.getInterpolation(fraction);
             }
             final float prevFraction = mFirstKeyframe.getFraction();
             float intervalFraction = (fraction - prevFraction) /
                 (nextKeyframe.getFraction() - prevFraction);
             return mEvaluator.evaluate(intervalFraction, mFirstKeyframe.getValue(),
                     nextKeyframe.getValue());
         } else if (fraction >= 1f) {
             final Keyframe prevKeyframe = mKeyframes.get(mNumKeyframes - 2);
             final TimeInterpolator interpolator = mLastKeyframe.getInterpolator();
             if (interpolator != null) {
                 fraction = interpolator.getInterpolation(fraction);
             }
             final float prevFraction = prevKeyframe.getFraction();
             float intervalFraction = (fraction - prevFraction) /
                 (mLastKeyframe.getFraction() - prevFraction);
             return mEvaluator.evaluate(intervalFraction, prevKeyframe.getValue(),
                     mLastKeyframe.getValue());
         }
         Keyframe prevKeyframe = mFirstKeyframe;
         for (int i = 1; i < mNumKeyframes; ++i) {
             Keyframe nextKeyframe = mKeyframes.get(i);
             if (fraction < nextKeyframe.getFraction()) {
                 final TimeInterpolator interpolator = nextKeyframe.getInterpolator();
                 final float prevFraction = prevKeyframe.getFraction();
                 float intervalFraction = (fraction - prevFraction) /
                     (nextKeyframe.getFraction() - prevFraction);
                 // Apply interpolator on the proportional duration.
                 if (interpolator != null) {
                     intervalFraction = interpolator.getInterpolation(intervalFraction);
                 }
                 return mEvaluator.evaluate(intervalFraction, prevKeyframe.getValue(),
                         nextKeyframe.getValue());
             }
             prevKeyframe = nextKeyframe;
         }
         // shouldn't reach here
         return mLastKeyframe.getValue();
     }

     @Override
     public String toString() {
         String returnVal = " ";
         for (int i = 0; i < mNumKeyframes; ++i) {
             returnVal += mKeyframes.get(i).getValue() + "  ";
         }
         return returnVal;
     }
 }
	/*
	* 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 android.animation;

	import android.animation.Keyframe.FloatKeyframe;
	import android.animation.Keyframe.IntKeyframe;
	import android.animation.Keyframe.ObjectKeyframe;
	import android.graphics.Path;
	import android.util.Log;

	import java.util.Arrays;
	import java.util.List;

	/**
	* This class holds a collection of Keyframe objects and is called by ValueAnimator to calculate
	* values between those keyframes for a given animation. The class internal to the animation
	* package because it is an implementation detail of how Keyframes are stored and used.
	* @hide
	*/
	public class KeyframeSet implements Keyframes {

	int mNumKeyframes;

	Keyframe mFirstKeyframe;
	Keyframe mLastKeyframe;
	TimeInterpolator mInterpolator; // only used in the 2-keyframe case
	List<Keyframe> mKeyframes; // only used when there are not 2 keyframes
	TypeEvaluator mEvaluator;


	public KeyframeSet(Keyframe... keyframes) {
	mNumKeyframes = keyframes.length;
	// immutable list
	mKeyframes = Arrays.asList(keyframes);
	mFirstKeyframe = keyframes[0];
	mLastKeyframe = keyframes[mNumKeyframes - 1];
	mInterpolator = mLastKeyframe.getInterpolator();
	}

	public List<Keyframe> getKeyframes() {
	return mKeyframes;
	}

	public static KeyframeSet ofInt(int... values) {
	int numKeyframes = values.length;
	IntKeyframe keyframes[] = new IntKeyframe[Math.max(numKeyframes,2)];
	if (numKeyframes == 1) {
	keyframes[0] = (IntKeyframe) Keyframe.ofInt(0f);
	keyframes[1] = (IntKeyframe) Keyframe.ofInt(1f, values[0]);
	} else {
	keyframes[0] = (IntKeyframe) Keyframe.ofInt(0f, values[0]);
	for (int i = 1; i < numKeyframes; ++i) {
	keyframes[i] =
	(IntKeyframe) Keyframe.ofInt((float) i / (numKeyframes - 1), values[i]);
	}
	}
	return new IntKeyframeSet(keyframes);
	}

	public static KeyframeSet ofFloat(float... values) {
	boolean badValue = false;
	int numKeyframes = values.length;
	FloatKeyframe keyframes[] = new FloatKeyframe[Math.max(numKeyframes,2)];
	if (numKeyframes == 1) {
	keyframes[0] = (FloatKeyframe) Keyframe.ofFloat(0f);
	keyframes[1] = (FloatKeyframe) Keyframe.ofFloat(1f, values[0]);
	if (Float.isNaN(values[0])) {
	badValue = true;
	}
	} else {
	keyframes[0] = (FloatKeyframe) Keyframe.ofFloat(0f, values[0]);
	for (int i = 1; i < numKeyframes; ++i) {
	keyframes[i] =
	(FloatKeyframe) Keyframe.ofFloat((float) i / (numKeyframes - 1), values[i]);
	if (Float.isNaN(values[i])) {
	badValue = true;
	}
	}
	}
	if (badValue) {
	Log.w("Animator", "Bad value (NaN) in float animator");
	}
	return new FloatKeyframeSet(keyframes);
	}

	public static KeyframeSet ofKeyframe(Keyframe... keyframes) {
	// if all keyframes of same primitive type, create the appropriate KeyframeSet
	int numKeyframes = keyframes.length;
	boolean hasFloat = false;
	boolean hasInt = false;
	boolean hasOther = false;
	for (int i = 0; i < numKeyframes; ++i) {
	if (keyframes[i] instanceof FloatKeyframe) {
	hasFloat = true;
	} else if (keyframes[i] instanceof IntKeyframe) {
	hasInt = true;
	} else {
	hasOther = true;
	}
	}
	if (hasFloat && !hasInt && !hasOther) {
	FloatKeyframe floatKeyframes[] = new FloatKeyframe[numKeyframes];
	for (int i = 0; i < numKeyframes; ++i) {
	floatKeyframes[i] = (FloatKeyframe) keyframes[i];
	}
	return new FloatKeyframeSet(floatKeyframes);
	} else if (hasInt && !hasFloat && !hasOther) {
	IntKeyframe intKeyframes[] = new IntKeyframe[numKeyframes];
	for (int i = 0; i < numKeyframes; ++i) {
	intKeyframes[i] = (IntKeyframe) keyframes[i];
	}
	return new IntKeyframeSet(intKeyframes);
	} else {
	return new KeyframeSet(keyframes);
	}
	}

	public static KeyframeSet ofObject(Object... values) {
	int numKeyframes = values.length;
	ObjectKeyframe keyframes[] = new ObjectKeyframe[Math.max(numKeyframes,2)];
	if (numKeyframes == 1) {
	keyframes[0] = (ObjectKeyframe) Keyframe.ofObject(0f);
	keyframes[1] = (ObjectKeyframe) Keyframe.ofObject(1f, values[0]);
	} else {
	keyframes[0] = (ObjectKeyframe) Keyframe.ofObject(0f, values[0]);
	for (int i = 1; i < numKeyframes; ++i) {
	keyframes[i] = (ObjectKeyframe) Keyframe.ofObject((float) i / (numKeyframes - 1), values[i]);
	}
	}
	return new KeyframeSet(keyframes);
	}

	public static PathKeyframes ofPath(Path path) {
	return new PathKeyframes(path);
	}

	public static PathKeyframes ofPath(Path path, float error) {
	return new PathKeyframes(path, error);
	}

	/**
	* Sets the TypeEvaluator to be used when calculating animated values. This object
	* is required only for KeyframeSets that are not either IntKeyframeSet or FloatKeyframeSet,
	* both of which assume their own evaluator to speed up calculations with those primitive
	* types.
	*
	* @param evaluator The TypeEvaluator to be used to calculate animated values.
	*/
	public void setEvaluator(TypeEvaluator evaluator) {
	mEvaluator = evaluator;
	}

	@Override
	public Class getType() {
	return mFirstKeyframe.getType();
	}

	@Override
	public KeyframeSet clone() {
	List<Keyframe> keyframes = mKeyframes;
	int numKeyframes = mKeyframes.size();
	final Keyframe[] newKeyframes = new Keyframe[numKeyframes];
	for (int i = 0; i < numKeyframes; ++i) {
	newKeyframes[i] = keyframes.get(i).clone();
	}
	KeyframeSet newSet = new KeyframeSet(newKeyframes);
	return newSet;
	}

	/**
	* Gets the animated value, given the elapsed fraction of the animation (interpolated by the
	* animation's interpolator) and the evaluator used to calculate in-between values. This
	* function maps the input fraction to the appropriate keyframe interval and a fraction
	* between them and returns the interpolated value. Note that the input fraction may fall
	* outside the [0-1] bounds, if the animation's interpolator made that happen (e.g., a
	* spring interpolation that might send the fraction past 1.0). We handle this situation by
	* just using the two keyframes at the appropriate end when the value is outside those bounds.
	*
	* @param fraction The elapsed fraction of the animation
	* @return The animated value.
	*/
	public Object getValue(float fraction) {
	// Special-case optimization for the common case of only two keyframes
	if (mNumKeyframes == 2) {
	if (mInterpolator != null) {
	fraction = mInterpolator.getInterpolation(fraction);
	}
	return mEvaluator.evaluate(fraction, mFirstKeyframe.getValue(),
	mLastKeyframe.getValue());
	}
	if (fraction <= 0f) {
	final Keyframe nextKeyframe = mKeyframes.get(1);
	final TimeInterpolator interpolator = nextKeyframe.getInterpolator();
	if (interpolator != null) {
	fraction = interpolator.getInterpolation(fraction);
	}
	final float prevFraction = mFirstKeyframe.getFraction();
	float intervalFraction = (fraction - prevFraction) /
	(nextKeyframe.getFraction() - prevFraction);
	return mEvaluator.evaluate(intervalFraction, mFirstKeyframe.getValue(),
	nextKeyframe.getValue());
	} else if (fraction >= 1f) {
	final Keyframe prevKeyframe = mKeyframes.get(mNumKeyframes - 2);
	final TimeInterpolator interpolator = mLastKeyframe.getInterpolator();
	if (interpolator != null) {
	fraction = interpolator.getInterpolation(fraction);
	}
	final float prevFraction = prevKeyframe.getFraction();
	float intervalFraction = (fraction - prevFraction) /
	(mLastKeyframe.getFraction() - prevFraction);
	return mEvaluator.evaluate(intervalFraction, prevKeyframe.getValue(),
	mLastKeyframe.getValue());
	}
	Keyframe prevKeyframe = mFirstKeyframe;
	for (int i = 1; i < mNumKeyframes; ++i) {
	Keyframe nextKeyframe = mKeyframes.get(i);
	if (fraction < nextKeyframe.getFraction()) {
	final TimeInterpolator interpolator = nextKeyframe.getInterpolator();
	final float prevFraction = prevKeyframe.getFraction();
	float intervalFraction = (fraction - prevFraction) /
	(nextKeyframe.getFraction() - prevFraction);
	// Apply interpolator on the proportional duration.
	if (interpolator != null) {
	intervalFraction = interpolator.getInterpolation(intervalFraction);
	}
	return mEvaluator.evaluate(intervalFraction, prevKeyframe.getValue(),
	nextKeyframe.getValue());
	}
	prevKeyframe = nextKeyframe;
	}
	// shouldn't reach here
	return mLastKeyframe.getValue();
	}

	@Override
	public String toString() {
	String returnVal = " ";
	for (int i = 0; i < mNumKeyframes; ++i) {
	returnVal += mKeyframes.get(i).getValue() + " ";
	}
	return returnVal;
	}
	}