/**

 * An interpolator where the rate of change is constant

 *

 */

public class LinearInterpolator implements Interpolator {

    public LinearInterpolator() {

    }

    public LinearInterpolator(Context context, AttributeSet attrs) {

    }

    public float getInterpolation(float input) {

        return input;

    }

}

/**

 * An interpolator where the rate of change starts out slowly and

 * and then accelerates.

 *

 */

public class AccelerateInterpolator implements Interpolator {

    private final float mFactor;

    private final double mDoubleFactor;

    public AccelerateInterpolator() {

        mFactor = 1.0f;

        mDoubleFactor = 2.0;

    }

    /**

     * Constructor

     *

     * @param factor Degree to which the animation should be eased. Seting

     *        factor to 1.0f produces a y=x^2 parabola. Increasing factor above

     *        1.0f  exaggerates the ease-in effect (i.e., it starts even

     *        slower and ends evens faster)

     */

    public AccelerateInterpolator(float factor) {

        mFactor = factor;

        mDoubleFactor = 2 * mFactor;

    }

    public AccelerateInterpolator(Context context, AttributeSet attrs) {

        TypedArray a =

            context.obtainStyledAttributes(attrs, com.android.internal.R.styleable.AccelerateInterpolator);

        mFactor = a.getFloat(com.android.internal.R.styleable.AccelerateInterpolator_factor, 1.0f);

        mDoubleFactor = 2 * mFactor;

        a.recycle();

    }

    public float getInterpolation(float input) {

        if (mFactor == 1.0f) {

            return input * input;

        } else {

            return (float)Math.pow(input, mDoubleFactor);

        }

    }

}

/**

 * An interpolator where the rate of change starts out quickly and

 * and then decelerates.

 *

 */

public class DecelerateInterpolator implements Interpolator {

    public DecelerateInterpolator() {

    }

    /**

     * Constructor

     *

     * @param factor Degree to which the animation should be eased. Setting factor to 1.0f produces

     *        an upside-down y=x^2 parabola. Increasing factor above 1.0f makes exaggerates the

     *        ease-out effect (i.e., it starts even faster and ends evens slower)

     */

    public DecelerateInterpolator(float factor) {

        mFactor = factor;

    }

    public DecelerateInterpolator(Context context, AttributeSet attrs) {

        TypedArray a =

            context.obtainStyledAttributes(attrs, com.android.internal.R.styleable.DecelerateInterpolator);

        mFactor = a.getFloat(com.android.internal.R.styleable.DecelerateInterpolator_factor, 1.0f);

        a.recycle();

    }

    public float getInterpolation(float input) {

        float result;

        if (mFactor == 1.0f) {

            result = (float)(1.0f - (1.0f - input) * (1.0f - input));

        } else {

            result = (float)(1.0f - Math.pow((1.0f - input), 2 * mFactor));

        }

        return result;

    }

    private float mFactor = 1.0f;

}

/**

 * An interpolator where the rate of change starts and ends slowly but

 * accelerates through the middle.

 *

 */

public class AccelerateDecelerateInterpolator implements Interpolator {

    public AccelerateDecelerateInterpolator() {

    }

    @SuppressWarnings({"UnusedDeclaration"})

    public AccelerateDecelerateInterpolator(Context context, AttributeSet attrs) {

    }

    public float getInterpolation(float input) {

        return (float)(Math.cos((input + 1) * Math.PI) / 2.0f) + 0.5f;

    }

}

/**

 * An interpolator where the change starts backward then flings forward.

 */

public class AnticipateInterpolator implements Interpolator {

    private final float mTension;

    public AnticipateInterpolator() {

        mTension = 2.0f;

    }

    /**

     * @param tension Amount of anticipation. When tension equals 0.0f, there is

     *                no anticipation and the interpolator becomes a simple

     *                acceleration interpolator.

     */

    public AnticipateInterpolator(float tension) {

        mTension = tension;

    }

    public AnticipateInterpolator(Context context, AttributeSet attrs) {

        TypedArray a = context.obtainStyledAttributes(attrs,

                com.android.internal.R.styleable.AnticipateInterpolator);

        mTension =

                a.getFloat(com.android.internal.R.styleable.AnticipateInterpolator_tension, 2.0f);

        a.recycle();

    }

    public float getInterpolation(float t) {

        // a(t) = t * t * ((tension + 1) * t - tension)

        return t * t * ((mTension + 1) * t - mTension);

    }

}

/**

 * An interpolator where the change flings forward and overshoots the last value

 * then comes back.

 */

public class OvershootInterpolator implements Interpolator {

    private final float mTension;

    public OvershootInterpolator() {

        mTension = 2.0f;

    }

    /**

     * @param tension Amount of overshoot. When tension equals 0.0f, there is

     *                no overshoot and the interpolator becomes a simple

     *                deceleration interpolator.

     */

    public OvershootInterpolator(float tension) {

        mTension = tension;

    }

    public OvershootInterpolator(Context context, AttributeSet attrs) {

        TypedArray a = context.obtainStyledAttributes(attrs,

                com.android.internal.R.styleable.OvershootInterpolator);

        mTension =

                a.getFloat(com.android.internal.R.styleable.OvershootInterpolator_tension, 2.0f);

        a.recycle();

    }

    public float getInterpolation(float t) {

        // _o(t) = t * t * ((tension + 1) * t + tension)

        // o(t) = _o(t - 1) + 1

        t -= 1.0f;

        return t * t * ((mTension + 1) * t + mTension) + 1.0f;

    }

}

/**

 * An interpolator where the change starts backward then flings forward and overshoots

 * the target value and finally goes back to the final value.

 */

public class AnticipateOvershootInterpolator implements Interpolator {

    private final float mTension;

    public AnticipateOvershootInterpolator() {

        mTension = 2.0f * 1.5f;

    }

    /**

     * @param tension Amount of anticipation/overshoot. When tension equals 0.0f,

     *                there is no anticipation/overshoot and the interpolator becomes

     *                a simple acceleration/deceleration interpolator.

     */

    public AnticipateOvershootInterpolator(float tension) {

        mTension = tension * 1.5f;

    }

    /**

     * @param tension Amount of anticipation/overshoot. When tension equals 0.0f,

     *                there is no anticipation/overshoot and the interpolator becomes

     *                a simple acceleration/deceleration interpolator.

     * @param extraTension Amount by which to multiply the tension. For instance,

     *                     to get the same overshoot as an OvershootInterpolator with

     *                     a tension of 2.0f, you would use an extraTension of 1.5f.

     */

    public AnticipateOvershootInterpolator(float tension, float extraTension) {

        mTension = tension * extraTension;

    }

    public AnticipateOvershootInterpolator(Context context, AttributeSet attrs) {

        TypedArray a = context.obtainStyledAttributes(attrs, AnticipateOvershootInterpolator);

        mTension = a.getFloat(AnticipateOvershootInterpolator_tension, 2.0f) *

                a.getFloat(AnticipateOvershootInterpolator_extraTension, 1.5f);

        a.recycle();

    }

    private static float a(float t, float s) {

        return t * t * ((s + 1) * t - s);

    }

    private static float o(float t, float s) {

        return t * t * ((s + 1) * t + s);

    }

    public float getInterpolation(float t) {

        // a(t, s) = t * t * ((s + 1) * t - s)

        // o(t, s) = t * t * ((s + 1) * t + s)

        // f(t) = 0.5 * a(t * 2, tension * extraTension), when t < 0.5

        // f(t) = 0.5 * (o(t * 2 - 2, tension * extraTension) + 2), when t <= 1.0

        if (t < 0.5f) return 0.5f * a(t * 2.0f, mTension);

        else return 0.5f * (o(t * 2.0f - 2.0f, mTension) + 2.0f);

    }

}

/**

 * An interpolator where the change bounces at the end.

 */

public class BounceInterpolator implements Interpolator {

    public BounceInterpolator() {

    }

    @SuppressWarnings({"UnusedDeclaration"})

    public BounceInterpolator(Context context, AttributeSet attrs) {

    }

    private static float bounce(float t) {

        return t * t * 8.0f;

    }

    public float getInterpolation(float t) {

        // _b(t) = t * t * 8

        // bs(t) = _b(t) for t < 0.3535

        // bs(t) = _b(t - 0.54719) + 0.7 for t < 0.7408

        // bs(t) = _b(t - 0.8526) + 0.9 for t < 0.9644

        // bs(t) = _b(t - 1.0435) + 0.95 for t <= 1.0

        // b(t) = bs(t * 1.1226)

        t *= 1.1226f;

        if (t < 0.3535f) return bounce(t);

        else if (t < 0.7408f) return bounce(t - 0.54719f) + 0.7f;

        else if (t < 0.9644f) return bounce(t - 0.8526f) + 0.9f;

        else return bounce(t - 1.0435f) + 0.95f;

    }

}

/**

 * Repeats the animation for a specified number of cycles. The

 * rate of change follows a sinusoidal pattern.

 *

 */

public class CycleInterpolator implements Interpolator {

    public CycleInterpolator(float cycles) {

        mCycles = cycles;

    }

    public CycleInterpolator(Context context, AttributeSet attrs) {

        TypedArray a =

            context.obtainStyledAttributes(attrs, com.android.internal.R.styleable.CycleInterpolator);

        mCycles = a.getFloat(com.android.internal.R.styleable.CycleInterpolator_cycles, 1.0f);

        a.recycle();

    }

    public float getInterpolation(float input) {

        return (float)(Math.sin(2 * mCycles * Math.PI * input));

    }

    private float mCycles;

}