docs/html/training/custom-views/making-interactive.jd - platform/frameworks/base - Git at Google

 page.title=Making the View Interactive
 parent.title=Creating Custom Views
 parent.link=index.html

 trainingnavtop=true
 previous.title=Custom Drawing
 previous.link=custom-drawing.html
 next.title=Optmizing the View
 next.link=optimizing-view.html

 @jd:body

 <div id="tb-wrapper">
     <div id="tb">

         <h2>This lesson teaches you to</h2>
         <ol>
             <li><a href="#inputgesture">Handle Input Gestures</a></li>
             <li><a href="#motion">Create Physically Plausible Motion</a></li>
             <li><a href="#makesmooth">Make Your Transitions Smooth</a></li>
         </ol>

         <h2>You should also read</h2>
         <ul>
             <li><a href="{@docRoot}guide/topics/ui/ui-events.html">Input Events</a></li>
             <li><a href="{@docRoot}guide/topics/graphics/prop-animation.html">Property Animation</a>
             </li>
         </ul>
 <h2>Try it out</h2>
 <div class="download-box">
 <a href="{@docRoot}shareables/training/CustomView.zip"
 class="button">Download the sample</a>
 <p class="filename">CustomView.zip</p>
 </div>
     </div>
 </div>

 <p>Drawing a UI is only one part of creating a custom view. You also need to make your view respond
 to user input in a
 way that closely resembles the real-world action you're mimicking. Objects should always act in the
 same way that real
 objects do. For example, images should not immediately pop out of existence and reappear somewhere
 else, because objects
 in the real world don't do that. Instead, images should move from one place to another.</p>

 <p>Users also sense subtle behavior or feel in an interface, and react best to subtleties that
 mimic the real world.
 For example, when users fling a UI object, they should sense friction at the beginning that delays
 the motion, and then
 at the end sense momentum that carries the motion beyond the fling.</p>

 <p>This lesson demonstrates how to use features of the Android framework to add these real-world
 behaviors to your
 custom view.

 <h2 id="inputgesture">Handle Input Gestures</h2>

 <p>Like many other UI frameworks, Android supports an input event model. User actions are turned
     into events that
     trigger callbacks, and you can override the callbacks to customize how your application responds
     to the user. The
     most common input event in the Android system is <em>touch</em>, which triggers {@link
     android.view.View#onTouchEvent(android.view.MotionEvent)}. Override this method to handle the
     event:</p>

 <pre>
    &#64Override
    public boolean onTouchEvent(MotionEvent event) {
     return super.onTouchEvent(event);
    }
 </pre>

 <p>Touch events by themselves are not particularly useful. Modern touch UIs define interactions in
     terms of gestures
     such as tapping, pulling, pushing, flinging, and zooming. To convert raw touch events into
     gestures, Android
     provides {@link android.view.GestureDetector}.</p>

 <p>Construct a {@link android.view.GestureDetector} by passing in an instance of a class that
     implements {@link
     android.view.GestureDetector.OnGestureListener}. If you only want to process a few gestures, you
     can extend {@link
     android.view.GestureDetector.SimpleOnGestureListener} instead of implementing the {@link
     android.view.GestureDetector.OnGestureListener}
     interface. For instance, this code creates a class that extends {@link
     android.view.GestureDetector.SimpleOnGestureListener} and overrides {@link
     android.view.GestureDetector.SimpleOnGestureListener#onDown}.</p>

 <pre>
 class mListener extends GestureDetector.SimpleOnGestureListener {
    &#64;Override
    public boolean onDown(MotionEvent e) {
        return true;
    }
 }
 mDetector = new GestureDetector(PieChart.this.getContext(), new mListener());
 </pre>

 <p>Whether or not you use {@link
     android.view.GestureDetector.SimpleOnGestureListener}, you must always implement an
     {@link android.view.GestureDetector.OnGestureListener#onDown onDown()} method that
     returns {@code true}. This step is necessary because all gestures begin with an
     {@link android.view.GestureDetector.OnGestureListener#onDown onDown()} message. If
     you return {@code
     false} from {@link android.view.GestureDetector.OnGestureListener#onDown onDown()}, as
     {@link android.view.GestureDetector.SimpleOnGestureListener} does, the system assumes that
     you want to ignore the
     rest of the gesture, and the other methods of
     {@link android.view.GestureDetector.OnGestureListener} never get called. The
     only time you should
     return {@code false} from {@link android.view.GestureDetector.OnGestureListener#onDown onDown()}
     is if you truly want to ignore an entire gesture.

     Once you've implemented {@link android.view.GestureDetector.OnGestureListener}
     and created an instance of {@link android.view.GestureDetector}, you can use
     your {@link android.view.GestureDetector} to interpret the touch events you receive in {@link
     android.view.GestureDetector#onTouchEvent onTouchEvent()}.</p>

 <pre>
 &#64;Override
 public boolean onTouchEvent(MotionEvent event) {
    boolean result = mDetector.onTouchEvent(event);
    if (!result) {
        if (event.getAction() == MotionEvent.ACTION_UP) {
            stopScrolling();
            result = true;
        }
    }
    return result;
 }
 </pre>

 <p>When you pass {@link android.view.GestureDetector#onTouchEvent onTouchEvent()} a touch event that
     it doesn't
     recognize as part of a gesture, it returns {@code false}. You can then run your own custom
     gesture-detection
     code.</p>

 <h2 id="motion">Create Physically Plausible Motion</h2>

 <p>Gestures are a powerful way to control touchscreen devices, but they can be counterintuitive and
     difficult to
     remember unless they produce physically plausible results. A good example of this is the <em>fling</em>
     gesture, where the
     user quickly moves a finger across the screen and then lifts it. This gesture makes sense if the UI
     responds by moving
     quickly in the direction of the fling, then slowing down, as if the user had pushed on a
     flywheel and set it
     spinning.</p>

 <p>However, simulating the feel of a flywheel isn't trivial. A lot of physics and math are required
     to get a flywheel
     model working correctly. Fortunately, Android provides helper classes to simulate this and other
     behaviors. The
     {@link android.widget.Scroller} class is the basis for handling flywheel-style <em>fling</em>
     gestures.</p>

 <p>To start a fling, call {@link android.widget.Scroller#fling fling()} with the starting velocity
     and the minimum and
     maximum x and y values of the fling. For the velocity value, you can use the value computed for
     you by {@link android.view.GestureDetector}.</p>

 <pre>
 &#64;Override
 public boolean onFling(MotionEvent e1, MotionEvent e2, float velocityX, float velocityY) {
    mScroller.fling(currentX, currentY, velocityX / SCALE, velocityY / SCALE, minX, minY, maxX, maxY);
    postInvalidate();
 }
 </pre>

 <p class="note"><strong>Note:</strong> Although the velocity calculated by
     {@link android.view.GestureDetector} is physically accurate,
     many developers feel
     that using this value makes the fling animation too fast. It's common to divide the x and y
     velocity by a factor of
     4 to 8.</p>

 <p>The call to {@link android.widget.Scroller#fling fling()} sets up the physics model for the fling
     gesture.
     Afterwards, you need to update the {@link android.widget.Scroller Scroller} by calling {@link
     android.widget.Scroller#computeScrollOffset Scroller.computeScrollOffset()} at regular
     intervals. {@link
     android.widget.Scroller#computeScrollOffset computeScrollOffset()} updates the {@link
     android.widget.Scroller
     Scroller} object's internal state by reading the current time and using the physics model to calculate
     the x and y position
     at that time. Call {@link android.widget.Scroller#getCurrX} and {@link
     android.widget.Scroller#getCurrY} to
     retrieve these values.</p>

 <p>Most views pass the {@link android.widget.Scroller Scroller} object's x and y position directly to
     {@link
     android.view.View#scrollTo scrollTo()}. The PieChart example is a little different: it
     uses the current scroll
     y position to set the rotational angle of the chart.</p>

 <pre>
 if (!mScroller.isFinished()) {
     mScroller.computeScrollOffset();
     setPieRotation(mScroller.getCurrY());
 }
 </pre>

 <p>The {@link android.widget.Scroller Scroller} class computes scroll positions for you, but it does
     not automatically
     apply those positions to your view. It's your responsibility to make sure you get and apply new
     coordinates often
     enough to make the scrolling animation look smooth. There are two ways to do this:</p>

 <ul>
     <li>Call {@link android.view.View#postInvalidate() postInvalidate()} after calling
         {@link android.widget.Scroller#fling(int, int, int, int, int, int, int, int) fling()},
         in order to
         force a redraw. This
         technique requires that you compute scroll offsets in {@link android.view.View#onDraw onDraw()}
         and call {@link android.view.View#postInvalidate() postInvalidate()} every
         time the scroll offset changes.
     </li>
     <li>Set up a {@link android.animation.ValueAnimator} to animate for the duration of the fling,
         and add a listener to process animation updates
         by calling {@link android.animation.ValueAnimator#addUpdateListener addUpdateListener()}.
     </li>
 </ul>

 <p>The PieChart example uses the second approach. This technique is slightly more complex to set up, but
     it works more
     closely with the animation system and doesn't require potentially unnecessary view
     invalidation. The drawback is that {@link android.animation.ValueAnimator}
     is not available prior to API level 11, so this technique cannot be used
 on devices running Android versions lower than 3.0.</p>

 <p class="note"><strong>Note:</strong> {@link android.animation.ValueAnimator} isn't available
         prior to API level 11, but you can still use it in applications that
 target lower API levels. You just need to make sure to check the current API level
 at runtime, and omit the calls to the view animation system if the current level is less than 11.</p>

 <pre>
        mScroller = new Scroller(getContext(), null, true);
        mScrollAnimator = ValueAnimator.ofFloat(0,1);
        mScrollAnimator.addUpdateListener(new ValueAnimator.AnimatorUpdateListener() {
            &#64;Override
            public void onAnimationUpdate(ValueAnimator valueAnimator) {
                if (!mScroller.isFinished()) {
                    mScroller.computeScrollOffset();
                    setPieRotation(mScroller.getCurrY());
                } else {
                    mScrollAnimator.cancel();
                    onScrollFinished();
                }
            }
        });
 </pre>

 <h2 id="makesmooth">Make Your Transitions Smooth</h2>

 <p>Users expect a modern UI to transition smoothly between states. UI elements fade in and out
     instead of appearing and
     disappearing. Motions begin and end smoothly instead of starting and stopping abruptly. The
     Android <a
             href="{@docRoot}guide/topics/graphics/prop-animation.html">property animation
         framework</a>, introduced in
     Android 3.0, makes smooth transitions easy.</p>

 <p>To use the animation system, whenever a property changes that will affect your view's appearance,
     do not change the
     property directly. Instead, use {@link android.animation.ValueAnimator} to make the change. In
     the following
     example, modifying the
     currently selected pie slice in PieChart causes the entire chart to rotate so that the selection
     pointer is centered
     in the selected slice. {@link android.animation.ValueAnimator} changes the rotation over a
     period of several
     hundred milliseconds,
     rather than immediately setting the new rotation value.</p>

 <pre>
 mAutoCenterAnimator = ObjectAnimator.ofInt(PieChart.this, "PieRotation", 0);
 mAutoCenterAnimator.setIntValues(targetAngle);
 mAutoCenterAnimator.setDuration(AUTOCENTER_ANIM_DURATION);
 mAutoCenterAnimator.start();
 </pre>

 <p>If the value you want to change is one of the base {@link android.view.View} properties, doing
     the animation
     is even easier,
     because Views have a built-in {@link android.view.ViewPropertyAnimator} that is optimized for
     simultaneous animation
     of multiple properties. For example:</p>

 <pre>
 animate().rotation(targetAngle).setDuration(ANIM_DURATION).start();
 </pre>
	page.title=Making the View Interactive
	parent.title=Creating Custom Views
	parent.link=index.html

	trainingnavtop=true
	previous.title=Custom Drawing
	previous.link=custom-drawing.html
	next.title=Optmizing the View
	next.link=optimizing-view.html

	@jd:body

	<div id="tb-wrapper">
	<div id="tb">

	<h2>This lesson teaches you to</h2>
	<ol>
	<li><a href="#inputgesture">Handle Input Gestures</a></li>
	<li><a href="#motion">Create Physically Plausible Motion</a></li>
	<li><a href="#makesmooth">Make Your Transitions Smooth</a></li>
	</ol>

	<h2>You should also read</h2>
	<ul>
	<li><a href="{@docRoot}guide/topics/ui/ui-events.html">Input Events</a></li>
	<li><a href="{@docRoot}guide/topics/graphics/prop-animation.html">Property Animation</a>
	</li>
	</ul>
	<h2>Try it out</h2>
	<div class="download-box">
	<a href="{@docRoot}shareables/training/CustomView.zip"
	class="button">Download the sample</a>
	<p class="filename">CustomView.zip</p>
	</div>
	</div>
	</div>

	<p>Drawing a UI is only one part of creating a custom view. You also need to make your view respond
	to user input in a
	way that closely resembles the real-world action you're mimicking. Objects should always act in the
	same way that real
	objects do. For example, images should not immediately pop out of existence and reappear somewhere
	else, because objects
	in the real world don't do that. Instead, images should move from one place to another.</p>

	<p>Users also sense subtle behavior or feel in an interface, and react best to subtleties that
	mimic the real world.
	For example, when users fling a UI object, they should sense friction at the beginning that delays
	the motion, and then
	at the end sense momentum that carries the motion beyond the fling.</p>

	<p>This lesson demonstrates how to use features of the Android framework to add these real-world
	behaviors to your
	custom view.

	<h2 id="inputgesture">Handle Input Gestures</h2>

	<p>Like many other UI frameworks, Android supports an input event model. User actions are turned
	into events that
	trigger callbacks, and you can override the callbacks to customize how your application responds
	to the user. The
	most common input event in the Android system is <em>touch</em>, which triggers {@link
	android.view.View#onTouchEvent(android.view.MotionEvent)}. Override this method to handle the
	event:</p>

	<pre>
	&#64Override
	public boolean onTouchEvent(MotionEvent event) {
	return super.onTouchEvent(event);
	}
	</pre>

	<p>Touch events by themselves are not particularly useful. Modern touch UIs define interactions in
	terms of gestures
	such as tapping, pulling, pushing, flinging, and zooming. To convert raw touch events into
	gestures, Android
	provides {@link android.view.GestureDetector}.</p>

	<p>Construct a {@link android.view.GestureDetector} by passing in an instance of a class that
	implements {@link
	android.view.GestureDetector.OnGestureListener}. If you only want to process a few gestures, you
	can extend {@link
	android.view.GestureDetector.SimpleOnGestureListener} instead of implementing the {@link
	android.view.GestureDetector.OnGestureListener}
	interface. For instance, this code creates a class that extends {@link
	android.view.GestureDetector.SimpleOnGestureListener} and overrides {@link
	android.view.GestureDetector.SimpleOnGestureListener#onDown}.</p>

	<pre>
	class mListener extends GestureDetector.SimpleOnGestureListener {
	@Override
	public boolean onDown(MotionEvent e) {
	return true;
	}
	}
	mDetector = new GestureDetector(PieChart.this.getContext(), new mListener());
	</pre>

	<p>Whether or not you use {@link
	android.view.GestureDetector.SimpleOnGestureListener}, you must always implement an
	{@link android.view.GestureDetector.OnGestureListener#onDown onDown()} method that
	returns {@code true}. This step is necessary because all gestures begin with an
	{@link android.view.GestureDetector.OnGestureListener#onDown onDown()} message. If
	you return {@code
	false} from {@link android.view.GestureDetector.OnGestureListener#onDown onDown()}, as
	{@link android.view.GestureDetector.SimpleOnGestureListener} does, the system assumes that
	you want to ignore the
	rest of the gesture, and the other methods of
	{@link android.view.GestureDetector.OnGestureListener} never get called. The
	only time you should
	return {@code false} from {@link android.view.GestureDetector.OnGestureListener#onDown onDown()}
	is if you truly want to ignore an entire gesture.

	Once you've implemented {@link android.view.GestureDetector.OnGestureListener}
	and created an instance of {@link android.view.GestureDetector}, you can use
	your {@link android.view.GestureDetector} to interpret the touch events you receive in {@link
	android.view.GestureDetector#onTouchEvent onTouchEvent()}.</p>

	<pre>
	@Override
	public boolean onTouchEvent(MotionEvent event) {
	boolean result = mDetector.onTouchEvent(event);
	if (!result) {
	if (event.getAction() == MotionEvent.ACTION_UP) {
	stopScrolling();
	result = true;
	}
	}
	return result;
	}
	</pre>

	<p>When you pass {@link android.view.GestureDetector#onTouchEvent onTouchEvent()} a touch event that
	it doesn't
	recognize as part of a gesture, it returns {@code false}. You can then run your own custom
	gesture-detection
	code.</p>

	<h2 id="motion">Create Physically Plausible Motion</h2>

	<p>Gestures are a powerful way to control touchscreen devices, but they can be counterintuitive and
	difficult to
	remember unless they produce physically plausible results. A good example of this is the <em>fling</em>
	gesture, where the
	user quickly moves a finger across the screen and then lifts it. This gesture makes sense if the UI
	responds by moving
	quickly in the direction of the fling, then slowing down, as if the user had pushed on a
	flywheel and set it
	spinning.</p>

	<p>However, simulating the feel of a flywheel isn't trivial. A lot of physics and math are required
	to get a flywheel
	model working correctly. Fortunately, Android provides helper classes to simulate this and other
	behaviors. The
	{@link android.widget.Scroller} class is the basis for handling flywheel-style <em>fling</em>
	gestures.</p>

	<p>To start a fling, call {@link android.widget.Scroller#fling fling()} with the starting velocity
	and the minimum and
	maximum x and y values of the fling. For the velocity value, you can use the value computed for
	you by {@link android.view.GestureDetector}.</p>

	<pre>
	@Override
	public boolean onFling(MotionEvent e1, MotionEvent e2, float velocityX, float velocityY) {
	mScroller.fling(currentX, currentY, velocityX / SCALE, velocityY / SCALE, minX, minY, maxX, maxY);
	postInvalidate();
	}
	</pre>

	<p class="note"><strong>Note:</strong> Although the velocity calculated by
	{@link android.view.GestureDetector} is physically accurate,
	many developers feel
	that using this value makes the fling animation too fast. It's common to divide the x and y
	velocity by a factor of
	4 to 8.</p>

	<p>The call to {@link android.widget.Scroller#fling fling()} sets up the physics model for the fling
	gesture.
	Afterwards, you need to update the {@link android.widget.Scroller Scroller} by calling {@link
	android.widget.Scroller#computeScrollOffset Scroller.computeScrollOffset()} at regular
	intervals. {@link
	android.widget.Scroller#computeScrollOffset computeScrollOffset()} updates the {@link
	android.widget.Scroller
	Scroller} object's internal state by reading the current time and using the physics model to calculate
	the x and y position
	at that time. Call {@link android.widget.Scroller#getCurrX} and {@link
	android.widget.Scroller#getCurrY} to
	retrieve these values.</p>

	<p>Most views pass the {@link android.widget.Scroller Scroller} object's x and y position directly to
	{@link
	android.view.View#scrollTo scrollTo()}. The PieChart example is a little different: it
	uses the current scroll
	y position to set the rotational angle of the chart.</p>

	<pre>
	if (!mScroller.isFinished()) {
	mScroller.computeScrollOffset();
	setPieRotation(mScroller.getCurrY());
	}
	</pre>

	<p>The {@link android.widget.Scroller Scroller} class computes scroll positions for you, but it does
	not automatically
	apply those positions to your view. It's your responsibility to make sure you get and apply new
	coordinates often
	enough to make the scrolling animation look smooth. There are two ways to do this:</p>

	<ul>
	<li>Call {@link android.view.View#postInvalidate() postInvalidate()} after calling
	{@link android.widget.Scroller#fling(int, int, int, int, int, int, int, int) fling()},
	in order to
	force a redraw. This
	technique requires that you compute scroll offsets in {@link android.view.View#onDraw onDraw()}
	and call {@link android.view.View#postInvalidate() postInvalidate()} every
	time the scroll offset changes.
	</li>
	<li>Set up a {@link android.animation.ValueAnimator} to animate for the duration of the fling,
	and add a listener to process animation updates
	by calling {@link android.animation.ValueAnimator#addUpdateListener addUpdateListener()}.
	</li>
	</ul>

	<p>The PieChart example uses the second approach. This technique is slightly more complex to set up, but
	it works more
	closely with the animation system and doesn't require potentially unnecessary view
	invalidation. The drawback is that {@link android.animation.ValueAnimator}
	is not available prior to API level 11, so this technique cannot be used
	on devices running Android versions lower than 3.0.</p>

	<p class="note"><strong>Note:</strong> {@link android.animation.ValueAnimator} isn't available
	prior to API level 11, but you can still use it in applications that
	target lower API levels. You just need to make sure to check the current API level
	at runtime, and omit the calls to the view animation system if the current level is less than 11.</p>

	<pre>
	mScroller = new Scroller(getContext(), null, true);
	mScrollAnimator = ValueAnimator.ofFloat(0,1);
	mScrollAnimator.addUpdateListener(new ValueAnimator.AnimatorUpdateListener() {
	@Override
	public void onAnimationUpdate(ValueAnimator valueAnimator) {
	if (!mScroller.isFinished()) {
	mScroller.computeScrollOffset();
	setPieRotation(mScroller.getCurrY());
	} else {
	mScrollAnimator.cancel();
	onScrollFinished();
	}
	}
	});
	</pre>

	<h2 id="makesmooth">Make Your Transitions Smooth</h2>

	<p>Users expect a modern UI to transition smoothly between states. UI elements fade in and out
	instead of appearing and
	disappearing. Motions begin and end smoothly instead of starting and stopping abruptly. The
	Android <a
	href="{@docRoot}guide/topics/graphics/prop-animation.html">property animation
	framework</a>, introduced in
	Android 3.0, makes smooth transitions easy.</p>

	<p>To use the animation system, whenever a property changes that will affect your view's appearance,
	do not change the
	property directly. Instead, use {@link android.animation.ValueAnimator} to make the change. In
	the following
	example, modifying the
	currently selected pie slice in PieChart causes the entire chart to rotate so that the selection
	pointer is centered
	in the selected slice. {@link android.animation.ValueAnimator} changes the rotation over a
	period of several
	hundred milliseconds,
	rather than immediately setting the new rotation value.</p>

	<pre>
	mAutoCenterAnimator = ObjectAnimator.ofInt(PieChart.this, "PieRotation", 0);
	mAutoCenterAnimator.setIntValues(targetAngle);
	mAutoCenterAnimator.setDuration(AUTOCENTER_ANIM_DURATION);
	mAutoCenterAnimator.start();
	</pre>

	<p>If the value you want to change is one of the base {@link android.view.View} properties, doing
	the animation
	is even easier,
	because Views have a built-in {@link android.view.ViewPropertyAnimator} that is optimized for
	simultaneous animation
	of multiple properties. For example:</p>

	<pre>
	animate().rotation(targetAngle).setDuration(ANIM_DURATION).start();
	</pre>