This lesson teaches you to
You should also read
- Input Events API Guide
- Sensors Overview
- Making the View Interactive
- Design Guide for Gestures
- Design Guide for Touch Feedback
Try it out
InteractiveChart.zip
In Android, scrolling is typically achieved by using the
ScrollView
class. Any standard layout that might extend beyond the bounds of its container should be
nested in a
ScrollView
to provide a scrollable view that's
managed by the framework. Implementing a custom scroller should only be
necessary for special scenarios. This lesson describes such a scenario: displaying
a scrolling effect in response to touch gestures using
scrollers
.
You can use scrollers (
Scroller
or
OverScroller
) to collect the data you need to produce a
scrolling animation in response to a touch event. They are similar, but
OverScroller
includes methods for indicating to users that they've reached the content edges
after a pan or fling gesture. The
InteractiveChart
sample
uses the
EdgeEffect
class
(actually the
EdgeEffectCompat
class)
to display a "glow" effect when users reach the content edges.
Note:
We recommend that you
use
OverScroller
rather than
Scroller
for scrolling animations.
OverScroller
provides the best backward
compatibility with older devices.
Also note that you generally only need to use scrollers
when implementing scrolling yourself.
ScrollView
and
HorizontalScrollView
do all of this for you if you nest your
layout within them.
A scroller is used to animate scrolling over time, using platform-standard scrolling physics (friction, velocity, etc.). The scroller itself doesn't actually draw anything. Scrollers track scroll offsets for you over time, but they don't automatically apply those positions to your view. It's your responsibility to get and apply new coordinates at a rate that will make the scrolling animation look smooth.
Understand Scrolling Terminology
"Scrolling" is a word that can take on different meanings in Android, depending on the context.
Scrolling
is the general process of moving the viewport (that is, the 'window'
of content you're looking at). When scrolling is in both the x and y axes, it's called
panning
. The sample application provided with this class,
InteractiveChart
, illustrates
two different types of scrolling, dragging and flinging:
-
Dragging
is the type of scrolling that occurs when a user drags her
finger across the touch screen. Simple dragging is often implemented by overriding
onScroll()
inGestureDetector.OnGestureListener
. For more discussion of dragging, see Dragging and Scaling . -
Flinging
is the type of scrolling that occurs when a user
drags and lifts her finger quickly. After the user lifts her finger, you generally
want to keep scrolling (moving the viewport), but decelerate until the viewport stops moving.
Flinging can be implemented by overriding
onFling()
inGestureDetector.OnGestureListener
, and by using a scroller object. This is the use case that is the topic of this lesson.
It's common to use scroller objects
in conjunction with a fling gesture, but they
can be used in pretty much any context where you want the UI to display
scrolling in response to a touch event. For example, you could override
onTouchEvent()
to process touch
events directly, and produce a scrolling effect or a "snapping to page" animation
in response to those touch events.
Implement Touch-Based Scrolling
This section describes how to use a scroller.
The snippet shown below comes from the
InteractiveChart
sample
provided with this class.
It uses a
GestureDetector
, and overrides the
GestureDetector.SimpleOnGestureListener
method
onFling()
.
It uses
OverScroller
to track the fling gesture.
If the user reaches the content edges
after the fling gesture, the app displays a "glow" effect.
Note:
The
InteractiveChart
sample app displays a
chart that you can zoom, pan, scroll, and so on. In the following snippet,
mContentRect
represents the rectangle coordinates within the view that the chart
will be drawn into. At any given time, a subset of the total chart domain and range are drawn
into this rectangular area.
mCurrentViewport
represents the portion of the chart that is currently
visible in the screen. Because pixel offsets are generally treated as integers,
mContentRect
is of the type
Rect
. Because the
graph domain and range are decimal/float values,
mCurrentViewport
is of
the type
RectF
.
The first part of the snippet shows the implementation of
onFling()
:
// The current viewport. This rectangle represents the currently visible // chart domain and range. The viewport is the part of the app that the // user manipulates via touch gestures. private RectF mCurrentViewport = new RectF(AXIS_X_MIN, AXIS_Y_MIN, AXIS_X_MAX, AXIS_Y_MAX); // The current destination rectangle (in pixel coordinates) into which the // chart data should be drawn. private Rect mContentRect; private OverScroller mScroller; private RectF mScrollerStartViewport; ... private final GestureDetector.SimpleOnGestureListener mGestureListener = new GestureDetector.SimpleOnGestureListener() { @Override public boolean onDown(MotionEvent e) { // Initiates the decay phase of any active edge effects. releaseEdgeEffects(); mScrollerStartViewport.set(mCurrentViewport); // Aborts any active scroll animations and invalidates. mScroller.forceFinished(true); ViewCompat.postInvalidateOnAnimation(InteractiveLineGraphView.this); return true; } ... @Override public boolean onFling(MotionEvent e1, MotionEvent e2, float velocityX, float velocityY) { fling((int) -velocityX, (int) -velocityY); return true; } }; private void fling(int velocityX, int velocityY) { // Initiates the decay phase of any active edge effects. releaseEdgeEffects(); // Flings use math in pixels (as opposed to math based on the viewport). Point surfaceSize = computeScrollSurfaceSize(); mScrollerStartViewport.set(mCurrentViewport); int startX = (int) (surfaceSize.x * (mScrollerStartViewport.left - AXIS_X_MIN) / ( AXIS_X_MAX - AXIS_X_MIN)); int startY = (int) (surfaceSize.y * (AXIS_Y_MAX - mScrollerStartViewport.bottom) / ( AXIS_Y_MAX - AXIS_Y_MIN)); // Before flinging, aborts the current animation. mScroller.forceFinished(true); // Begins the animation mScroller.fling( // Current scroll position startX, startY, velocityX, velocityY, /* * Minimum and maximum scroll positions. The minimum scroll * position is generally zero and the maximum scroll position * is generally the content size less the screen size. So if the * content width is 1000 pixels and the screen width is 200 * pixels, the maximum scroll offset should be 800 pixels. */ 0, surfaceSize.x - mContentRect.width(), 0, surfaceSize.y - mContentRect.height(), // The edges of the content. This comes into play when using // the EdgeEffect class to draw "glow" overlays. mContentRect.width() / 2, mContentRect.height() / 2); // Invalidates to trigger computeScroll() ViewCompat.postInvalidateOnAnimation(this); }
When
onFling()
calls
postInvalidateOnAnimation()
,
it triggers
computeScroll()
to update the values for x and y.
This is typically be done when a view child is animating a scroll using a scroller object, as in this example.
Most views pass the scroller object's x and y position directly to
scrollTo()
.
The following implementation of
computeScroll()
takes a different approach—it calls
computeScrollOffset()
to get the current
location of x and y. When the criteria for displaying an overscroll "glow" edge effect are met
(the display is zoomed in, x or y is out of bounds, and the app isn't already showing an overscroll),
the code sets up the overscroll glow effect and calls
postInvalidateOnAnimation()
to trigger an invalidate on the view:
// Edge effect / overscroll tracking objects. private EdgeEffectCompat mEdgeEffectTop; private EdgeEffectCompat mEdgeEffectBottom; private EdgeEffectCompat mEdgeEffectLeft; private EdgeEffectCompat mEdgeEffectRight; private boolean mEdgeEffectTopActive; private boolean mEdgeEffectBottomActive; private boolean mEdgeEffectLeftActive; private boolean mEdgeEffectRightActive; @Override public void computeScroll() { super.computeScroll(); boolean needsInvalidate = false; // The scroller isn't finished, meaning a fling or programmatic pan // operation is currently active. if (mScroller.computeScrollOffset()) { Point surfaceSize = computeScrollSurfaceSize(); int currX = mScroller.getCurrX(); int currY = mScroller.getCurrY(); boolean canScrollX = (mCurrentViewport.left > AXIS_X_MIN || mCurrentViewport.right < AXIS_X_MAX); boolean canScrollY = (mCurrentViewport.top > AXIS_Y_MIN || mCurrentViewport.bottom < AXIS_Y_MAX); /* * If you are zoomed in and currX or currY is * outside of bounds and you're not already * showing overscroll, then render the overscroll * glow edge effect. */ if (canScrollX && currX < 0 && mEdgeEffectLeft.isFinished() && !mEdgeEffectLeftActive) { mEdgeEffectLeft.onAbsorb((int) OverScrollerCompat.getCurrVelocity(mScroller)); mEdgeEffectLeftActive = true; needsInvalidate = true; } else if (canScrollX && currX > (surfaceSize.x - mContentRect.width()) && mEdgeEffectRight.isFinished() && !mEdgeEffectRightActive) { mEdgeEffectRight.onAbsorb((int) OverScrollerCompat.getCurrVelocity(mScroller)); mEdgeEffectRightActive = true; needsInvalidate = true; } if (canScrollY && currY < 0 && mEdgeEffectTop.isFinished() && !mEdgeEffectTopActive) { mEdgeEffectTop.onAbsorb((int) OverScrollerCompat.getCurrVelocity(mScroller)); mEdgeEffectTopActive = true; needsInvalidate = true; } else if (canScrollY && currY > (surfaceSize.y - mContentRect.height()) && mEdgeEffectBottom.isFinished() && !mEdgeEffectBottomActive) { mEdgeEffectBottom.onAbsorb((int) OverScrollerCompat.getCurrVelocity(mScroller)); mEdgeEffectBottomActive = true; needsInvalidate = true; } ... }
Here is the section of the code that performs the actual zoom:
// Custom object that is functionally similar to Scroller Zoomer mZoomer; private PointF mZoomFocalPoint = new PointF(); ... // If a zoom is in progress (either programmatically or via double // touch), performs the zoom. if (mZoomer.computeZoom()) { float newWidth = (1f - mZoomer.getCurrZoom()) * mScrollerStartViewport.width(); float newHeight = (1f - mZoomer.getCurrZoom()) * mScrollerStartViewport.height(); float pointWithinViewportX = (mZoomFocalPoint.x - mScrollerStartViewport.left) / mScrollerStartViewport.width(); float pointWithinViewportY = (mZoomFocalPoint.y - mScrollerStartViewport.top) / mScrollerStartViewport.height(); mCurrentViewport.set( mZoomFocalPoint.x - newWidth * pointWithinViewportX, mZoomFocalPoint.y - newHeight * pointWithinViewportY, mZoomFocalPoint.x + newWidth * (1 - pointWithinViewportX), mZoomFocalPoint.y + newHeight * (1 - pointWithinViewportY)); constrainViewport(); needsInvalidate = true; } if (needsInvalidate) { ViewCompat.postInvalidateOnAnimation(this); }
This is the
computeScrollSurfaceSize()
method that's called in the above snippet. It
computes the current scrollable surface size, in pixels. For example, if the entire chart area is visible,
this is simply the current size of
mContentRect
. If the chart is zoomed in 200% in both directions,
the returned size will be twice as large horizontally and vertically.
private Point computeScrollSurfaceSize() { return new Point( (int) (mContentRect.width() * (AXIS_X_MAX - AXIS_X_MIN) / mCurrentViewport.width()), (int) (mContentRect.height() * (AXIS_Y_MAX - AXIS_Y_MIN) / mCurrentViewport.height())); }
For another example of scroller usage, see the
source code
for the
ViewPager
class. It scrolls in response to flings,
and uses scrolling to implement the "snapping to page" animation.