Параллакс -- именно то, что тебе нужно.
Вот пример того что ты хочешь получить: https://www.youtube.com/watch?v=cJ7F5vpk6OU
Да и тот пример который ты показал в линке -- это ТОЖЕ ПАРАЛАКС.
Как действует внутри сам эфект паралакса:
- Отрисовываешь все нужные картинки "слоями".
- Пишешь некоторую функцию для смещения каждого из слоев. Чем дальше находится картинка(условно, "дальше") -- тем медленнее должна она двигаться. В общем-то функция должна быть одна, только изменяться размер смещения должен по коэфициэнту.
- Привязываешь все функции к значению акселерометра/гироскопа телефона и изменяешь при каждой следующей отрисовке кадра.
Готовой формулы нет -- нужно экспериментировать в зависимости от того что ты хочешь получить:
- Может быть только горизонтальный паралакс-эфект
- Или по двум осям (вверх и вниз)
- Или же по всем осям -- в т.ч. приближение и отдаление при опускании и поднимании телефона).
Гуглится по запросу "java parallax scrolling accelerometer".
Есть пример библиотеки которая это делает, как раз, на джаве: https://github.com/nvanbenschoten/motion
При чем сразу с апликухой-примером которую можно поставить на мобильный и проверить вживую: https://github.com/nvanbenschoten/motion/releases/download/v1.1.2/motion-sample.apk
В самой апликухе внизу ползунок перетащи вправо до упора что бы лучше было видно сам эфект.
UPD:
Вот еще одна паралакс библиотека на джаве:
https://github.com/SchibstedSpain/Parallax-Layer-Layout
И еще одна тоже на джаве:
https://github.com/tvbarthel/ParallaxSampleGitHub
И пример: https://www.youtube.com/watch?v=KyNBZLzWxYI
У тебя есть выбор!
Вот пример кода из библиотеки приведенной выше
attrs
<declare-styleable name="ParallaxImageView">
<attr name="motionIntensity" format="float"/>
<attr name="motionTiltSensitivity" format="float"/>
<attr name="motionScaledIntensity" format="boolean"/>
</declare-styleable>
ParallaxImageView
public class ParallaxImageView extends
android.support.v7.widget.AppCompatImageView implements SensorEventListener
{
private static final String TAG = ParallaxImageView.class.getName();
/**
* If the x and y axis' intensities are scaled to the image's aspect ratio (true) or
* equal to the smaller of the axis' intensities (false). If true, the image will be able to
* translate up to it's view bounds, independent of aspect ratio. If not true,
* the image will limit it's translation equally so that motion in either axis results
* in proportional translation.
*/
private boolean mScaledIntensities = false;
/**
* The intensity of the parallax effect, giving the perspective of depth.
*/
private float mParallaxIntensity = 1.2f;
/**
* The maximum percentage of offset translation that the image can move for each
* sensor input. Set to a negative number to disable.
*/
private float mMaximumJump = .1f;
// Instance variables used during matrix manipulation.
private SensorInterpreter mSensorInterpreter;
private SensorManager mSensorManager;
private Matrix mTranslationMatrix;
private float mXTranslation;
private float mYTranslation;
private float mXOffset;
private float mYOffset;
public ParallaxImageView(Context context)
{
this(context, null);
}
public ParallaxImageView(Context context, AttributeSet attrs)
{
this(context, attrs, 0);
}
public ParallaxImageView(Context context, AttributeSet attrs, int defStyle)
{
super(context, attrs, defStyle);
// Instantiate future objects
mTranslationMatrix = new Matrix();
mSensorInterpreter = new SensorInterpreter();
// Sets scale type
setScaleType(ScaleType.MATRIX);
// Set available attributes
if (attrs != null)
{
final TypedArray customAttrs = context.obtainStyledAttributes(attrs, R.styleable.ParallaxImageView);
if (customAttrs != null)
{
if (customAttrs.hasValue(R.styleable.ParallaxImageView_motionIntensity))
{
setParallaxIntensity(
customAttrs.getFloat(R.styleable.ParallaxImageView_motionIntensity,
mParallaxIntensity));
}
if (customAttrs.hasValue(R.styleable.ParallaxImageView_motionScaledIntensity))
{
setScaledIntensities(customAttrs.getBoolean(R.styleable.ParallaxImageView_motionScaledIntensity, mScaledIntensities));
}
if (customAttrs.hasValue(R.styleable.ParallaxImageView_motionTiltSensitivity))
{
setTiltSensitivity(customAttrs.getFloat(R.styleable.ParallaxImageView_motionTiltSensitivity, mSensorInterpreter.getTiltSensitivity()));
}
customAttrs.recycle();
}
}
// Configure matrix as early as possible by posting to MessageQueue
post(this::configureMatrix);
}
@Override
protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec)
{
super.onMeasure(widthMeasureSpec, heightMeasureSpec);
configureMatrix();
}
@Override
public void onSensorChanged(SensorEvent event)
{
if (mSensorInterpreter == null)
{
return;
}
final float[] vectors = mSensorInterpreter.interpretSensorEvent(getContext(), event);
// Return if interpretation of data failed
if (vectors == null)
{
return;
}
// Set translation on ImageView matrix
setTranslate(vectors[2], -vectors[1]);
}
@Override
public void onAccuracyChanged(Sensor sensor, int accuracy)
{
}
/**
* Registers a sensor manager with the parallax ImageView. Should be called in onResume
* or onStart lifecycle callbacks from an Activity or Fragment.
*/
public void registerSensorManager()
{
registerSensorManager(SensorManager.SENSOR_DELAY_FASTEST);
}
/**
* Registers a sensor manager with the parallax ImageView. Should be called in onResume
* or onStart lifecycle callbacks from an Activity or Fragment.
*
* @param samplingPeriodUs the sensor sampling period rate
*/
public void registerSensorManager(int samplingPeriodUs)
{
if (getContext() == null || mSensorManager != null)
{
return;
}
// Acquires a sensor manager
mSensorManager = (SensorManager) getContext().getSystemService(Context.SENSOR_SERVICE);
if (mSensorManager != null)
{
mSensorManager.registerListener(this, mSensorManager.getDefaultSensor(Sensor.TYPE_ROTATION_VECTOR), samplingPeriodUs);
}
}
/**
* Unregisters the ParallaxImageView's SensorManager. Should be called in onPause or onStop
* lifecycle callbacks from an Activity or Fragment to avoid leaking sensor usage.
*/
public void unregisterSensorManager()
{
unregisterSensorManager(false);
}
/**
* Unregisters the ParallaxImageView's SensorManager. Should be called in onPause from
* an Activity or Fragment to avoid continuing sensor usage.
*
* @param resetTranslation if the image translation should be reset to the origin
*/
public void unregisterSensorManager(boolean resetTranslation)
{
if (mSensorManager == null || mSensorInterpreter == null)
{
return;
}
mSensorManager.unregisterListener(this);
mSensorManager = null;
mSensorInterpreter.reset();
if (resetTranslation)
{
setTranslate(0, 0);
}
}
/**
* Sets the intensity of the parallax effect. The stronger the effect, the more distance
* the image will have to move around.
*
* @param parallaxIntensity the new intensity
*/
public void setParallaxIntensity(float parallaxIntensity)
{
if (parallaxIntensity < 1)
{
throw new IllegalArgumentException("Parallax effect must have a intensity of 1.0 or greater");
}
mParallaxIntensity = parallaxIntensity;
configureMatrix();
}
/**
* Sets the parallax tilt sensitivity for the image view. The stronger the sensitivity,
* the more a given tilt will adjust the image and the smaller needed tilt to reach the
* image bounds.
*
* @param sensitivity the new tilt sensitivity
*/
public void setTiltSensitivity(float sensitivity)
{
mSensorInterpreter.setTiltSensitivity(sensitivity);
}
/**
* Sets whether translation should be limited to the image's bounds or should be limited
* to the smaller of the two axis' translation limits.
*
* @param scaledIntensities the scaledIntensities flag
*/
public void setScaledIntensities(boolean scaledIntensities)
{
mScaledIntensities = scaledIntensities;
}
/**
* Sets the maximum percentage of the image that image matrix is allowed to translate
* for each sensor reading.
*
* @param maximumJump the new maximum jump
*/
public void setMaximumJump(float maximumJump)
{
mMaximumJump = maximumJump;
}
/**
* Sets the image view's translation coordinates. These values must be between -1 and 1,
* representing the transaction percentage from the center.
*
* @param x the horizontal translation
* @param y the vertical translation
*/
private void setTranslate(float x, float y)
{
if (Math.abs(x) > 1 || Math.abs(y) > 1)
{
throw new IllegalArgumentException("Parallax effect cannot translate more than 100% of its off-screen size");
}
float xScale, yScale;
if (mScaledIntensities)
{
// Set both scales to their offset values
xScale = mXOffset;
yScale = mYOffset;
}
else
{
// Set both scales to the max offset (should be negative, so smaller
absolute value)
xScale = Math.max(mXOffset, mYOffset);
yScale = Math.max(mXOffset, mYOffset);
}
// Make sure below maximum jump limit
if (mMaximumJump > 0)
{
// Limit x jump
if (x - mXTranslation / xScale > mMaximumJump)
{
x = mXTranslation / xScale + mMaximumJump;
}
else if (x - mXTranslation / xScale < -mMaximumJump)
{
x = mXTranslation / xScale - mMaximumJump;
}
// Limit y jump
if (y - mYTranslation / yScale > mMaximumJump)
{
y = mYTranslation / yScale + mMaximumJump;
}
else if (y - mYTranslation / yScale < -mMaximumJump)
{
y = mYTranslation / yScale - mMaximumJump;
}
}
mXTranslation = x * xScale;
mYTranslation = y * yScale;
configureMatrix();
}
/**
* Configures the ImageView's imageMatrix to allow for movement of the
* source image.
*/
private void configureMatrix()
{
if (getDrawable() == null || getWidth() == 0 || getHeight() == 0)
{
return;
}
int dWidth = getDrawable().getIntrinsicWidth();
int dHeight = getDrawable().getIntrinsicHeight();
int vWidth = getWidth();
int vHeight = getHeight();
float scale;
float dx, dy;
if (dWidth * vHeight > vWidth * dHeight)
{
scale = (float) vHeight / (float) dHeight;
mXOffset = (vWidth - dWidth * scale * mParallaxIntensity) * 0.5f;
mYOffset = (vHeight - dHeight * scale * mParallaxIntensity) * 0.5f;
}
else
{
scale = (float) vWidth / (float) dWidth;
mXOffset = (vWidth - dWidth * scale * mParallaxIntensity) * 0.5f;
mYOffset = (vHeight - dHeight * scale * mParallaxIntensity) * 0.5f;
}
dx = mXOffset + mXTranslation;
dy = mYOffset + mYTranslation;
mTranslationMatrix.set(getImageMatrix());
mTranslationMatrix.setScale(mParallaxIntensity * scale, mParallaxIntensity * scale);
mTranslationMatrix.postTranslate(dx, dy);
setImageMatrix(mTranslationMatrix);
}
}
SensorInterpreter
class SensorInterpreter
{
private static final String TAG = SensorInterpreter.class.getName();
/**
* The standardized tilt vector corresponding to yaw, pitch, and roll deltas from target matrix.
*/
private float[] mTiltVector = new float[3];
/**
* Whether the SensorInterpreter has set a target to calculate tilt offset from.
*/
private boolean mTargeted = false;
/**
* The target rotation matrix to calculate tilt offset from.
*/
private float[] mTargetMatrix = new float[16];
/**
* Rotation matrices used during calculation.
*/
private float[] mRotationMatrix = new float[16];
private float[] mOrientedRotationMatrix = new float[16];
/**
* Holds a shortened version of the rotation vector for compatibility purposes.
*/
private float[] mTruncatedRotationVector;
/**
* The sensitivity the parallax effect has towards tilting.
*/
private float mTiltSensitivity = 2.0f;
/**
* Converts sensor data in a {@link SensorEvent} to yaw, pitch, and roll.
*
* @param context the context of the
* @param event the event to interpret
*
* @return an interpreted vector of yaw, pitch, and roll delta values
*/
@SuppressWarnings("SuspiciousNameCombination")
public float[] interpretSensorEvent(@NonNull Context context, @Nullable SensorEvent event)
{
if (event == null)
{
return null;
}
// Retrieves the RotationVector from SensorEvent
float[] rotationVector = getRotationVectorFromSensorEvent(event);
// Set target rotation if none has been set
if (!mTargeted)
{
setTargetVector(rotationVector);
return null;
}
// Get rotation matrix from event's values
SensorManager.getRotationMatrixFromVector(mRotationMatrix, rotationVector);
// Acquire rotation of screen
final int rotation = ((WindowManager) context.getSystemService(Context.WINDOW_SERVICE)).getDefaultDisplay().getRotation();
// Calculate angle differential between target and current orientation
if (rotation == Surface.ROTATION_0)
{
SensorManager.getAngleChange(mTiltVector, mRotationMatrix, mTargetMatrix);
}
else
{
// Adjust axes on screen orientation by remapping coordinates
switch (rotation)
{
case Surface.ROTATION_90:
SensorManager.remapCoordinateSystem(mRotationMatrix, AXIS_Y, AXIS_MINUS_X, mOrientedRotationMatrix);
break;
case Surface.ROTATION_180:
SensorManager.remapCoordinateSystem(mRotationMatrix, AXIS_MINUS_X, AXIS_MINUS_Y, mOrientedRotationMatrix);
break;
case Surface.ROTATION_270:
SensorManager.remapCoordinateSystem(mRotationMatrix, AXIS_MINUS_Y, AXIS_X, mOrientedRotationMatrix);
break;
}
SensorManager.getAngleChange(mTiltVector, mOrientedRotationMatrix, mTargetMatrix);
}
// Perform value scaling and clamping on value array
for (int i = 0 ; i < mTiltVector.length ; i++)
{
// Map domain of tilt vector from radian (-PI, PI) to fraction (-1, 1)
mTiltVector[i] /= Math.PI;
// Adjust for tilt sensitivity
mTiltVector[i] *= mTiltSensitivity;
// Clamp values to image bounds
if (mTiltVector[i] > 1)
{
mTiltVector[i] = 1f;
}
else if (mTiltVector[i] < -1)
{
mTiltVector[i] = -1f;
}
}
return mTiltVector;
}
/**
* Pulls out the rotation vector from a {@link SensorEvent}, with a maximum length
* vector of four elements to avoid potential compatibility issues.
*
* @param event the sensor event
*
* @return the events rotation vector, potentially truncated
*/
@NonNull
@VisibleForTesting
float[] getRotationVectorFromSensorEvent(@NonNull SensorEvent event)
{
if (event.values.length > 4)
{
// On some Samsung devices SensorManager.getRotationMatrixFromVector
// appears to throw an exception if rotation vector has length > 4.
// For the purposes of this class the first 4 values of the
// rotation vector are sufficient (see crbug.com/335298 for details).
if (mTruncatedRotationVector == null)
{
mTruncatedRotationVector = new float[4];
}
System.arraycopy(event.values, 0, mTruncatedRotationVector, 0, 4);
return mTruncatedRotationVector;
}
else
{
return event.values;
}
}
/**
* Sets the target direction used for angle deltas to determine tilt.
*
* @param values a rotation vector (presumably from a ROTATION_VECTOR sensor)
*/
protected void setTargetVector(float[] values)
{
SensorManager.getRotationMatrixFromVector(mTargetMatrix, values);
mTargeted = true;
}
/**
* Resets the state of the SensorInterpreter, removing any target direction used for angle
* deltas to determine tilt.
*/
public void reset()
{
mTargeted = false;
}
/**
* Determines the tilt sensitivity of the SensorInterpreter.
*
* @return the tilt sensitivity
*/
public float getTiltSensitivity()
{
return mTiltSensitivity;
}
/**
* Sets the new sensitivity that the SensorInterpreter will scale tilt calculations by. If this
* sensitivity is above 1, the interpreter will have to clamp percentages to 100% and -100% at
* the tilt extremes.
*
* @param tiltSensitivity the new tilt sensitivity
*/
public void setTiltSensitivity(float tiltSensitivity)
{
if (tiltSensitivity <= 0)
{
throw new IllegalArgumentException("Tilt sensitivity must be positive");
}
mTiltSensitivity = tiltSensitivity;
}
}
И потом в коде
mScreenBackground.setImageResource(iRes);
и там где вам нужно (например в onResume()
) вызываем mScreenBackground.registerSensorManager();
и не забываем отписаться (например в onStop()
)