docs/html/training/custom-views/optimizing-view.jd - platform/frameworks/base - Git at Google

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

 trainingnavtop=true
 previous.title=Making the View Interactive
 previous.link=making-interactive.html

 @jd:body

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

         <h2>This lesson teaches you to</h2>
         <ol>
             <li><a href="#less">Do Less, Less Frequently</a></li>
             <li><a href="#accelerate">Use Hardware Acceleration</a></li>
         </ol>

         <h2>You should also read</h2>
         <ul>
             <li><a href="{@docRoot}guide/topics/graphics/hardware-accel.html">
                 Hardware Acceleration
             </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>Now that you have a well-designed view that responds to gestures and transitions between states,
 you need to ensure
 that the view runs fast. To avoid a UI that feels sluggish or stutters during playback, you must
 ensure that your
 animations consistently run at 60 frames per second.</p>

 <h2 id="less">Do Less, Less Frequently</h2>

 <p>To speed up your view, eliminate unnecessary code from routines that are called frequently. Start
 by working on
 {@link android.view.View#onDraw onDraw()}, which will give you the biggest payback. In particular
 you should eliminate
 allocations in {@link android.view.View#onDraw onDraw()}, because allocations may lead to a garbage
 collection that
 would cause a stutter. Allocate objects during initialization, or between animations. Never make an
 allocation while an
 animation is running.</p>

 <p>In addition to making {@link android.view.View#onDraw onDraw()} leaner, you should also make sure
 it's called as
 infrequently as possible. Most calls to {@link android.view.View#onDraw onDraw()} are the result of
 a call to {@link
 android.view.View#invalidate() invalidate()}, so eliminate unnecessary calls to {@link
 android.view.View#invalidate()
 invalidate()}. When possible, call the four-parameter variant of {@link
 android.view.View#invalidate() invalidate()}
 rather than the version that takes no parameters. The no-parameter variant invalidates the entire
 view, while the
 four-parameter variant invalidates only a specified portion of the view. This approach allows draw calls to
 be more efficient and
 can eliminate unnecessary invalidation of views that fall outside the invalid rectangle.</p>

 <p>Another very expensive operation is traversing layouts. Any time a view calls {@link
 android.view.View#requestLayout()
 requestLayout()}, the Android UI system needs to traverse the entire view hierarchy to find out how
 big each view needs
 to be. If it finds conflicting measurements, it may need to traverse the hierarchy multiple times.
 UI designers
 sometimes create deep hierarchies of nested {@link android.view.ViewGroup ViewGroup} objects in
 order to get the UI to
 behave properly. These deep view hierarchies cause performance problems. Make your view hierarchies
 as shallow as
 possible.</p>

 <p>If you have a complex UI, you should consider writing a custom {@link android.view.ViewGroup
 ViewGroup} to perform
 its layout. Unlike the built-in views, your custom view can make application-specific assumptions
 about the size and
 shape of its children, and thus avoid traversing its children to calculate measurements. The
 PieChart example shows how
 to extend {@link android.view.ViewGroup ViewGroup} as part of a custom view. PieChart has child
 views, but it never
 measures them. Instead, it sets their sizes directly according to its own custom layout
 algorithm.</p>

 <h2 id="accelerate">Use Hardware Acceleration</h2>

 <p>As of Android 3.0, the Android 2D graphics system can be accelerated by the GPU (Graphics
 Processing Unit) hardware
 found in most newer Android devices. GPU hardware acceleration can result in a tremendous
 performance increase for many
 applications, but it isn't the right choice for every application. The Android framework
 gives you the ability to finely control which parts of your application are or are not
 hardware accelerated.</p>

 <p>See <a href="{@docRoot}guide/topics/graphics/hardware-accel.html">Hardware Acceleration</a>
         in the Android Developers Guide for directions on how to enable acceleration at the
         application, activity, or window level. Notice  that in addition to the directions in
         the developer guide, you must also set your application's target API to 11 or higher by
         specifying {@code &lt;uses-sdk
         android:targetSdkVersion="11"/&gt;} in your {@code AndroidManifest.xml} file.</p>

 <p>Once you've enabled hardware acceleration, you may or may not see a performance increase.
 Mobile GPUs are very good at certain tasks, such as scaling, rotating, and translating
 bitmapped images. They are not particularly good at other tasks, such as drawing lines or curves. To
 get the most out of GPU acceleration, you should maximize the number of operations that the GPU is
 good at, and minimize the number of operations that the GPU isn't good at.</p>

 <p>In the PieChart example, for instance, drawing the pie is relatively expensive. Redrawing the pie
 each time it's
 rotated causes the UI to feel sluggish. The solution is to place the pie chart into a child
 {@link android.view.View} and set that
 {@link android.view.View}'s
 <a href="{@docRoot}reference/android/view/View.html#setLayerType(int, android.graphics.Paint)">
     layer type</a> to {@link android.view.View#LAYER_TYPE_HARDWARE}, so that the GPU can cache it as
 a static
 image. The sample
 defines the child view as an inner class of {@code PieChart}, which minimizes the amount of code
 changes that are needed
 to implement this solution.</p>

 <pre>
    private class PieView extends View {

        public PieView(Context context) {
            super(context);
            if (!isInEditMode()) {
                setLayerType(View.LAYER_TYPE_HARDWARE, null);
            }
        }

        &#64;Override
        protected void onDraw(Canvas canvas) {
            super.onDraw(canvas);

            for (Item it : mData) {
                mPiePaint.setShader(it.mShader);
                canvas.drawArc(mBounds,
                        360 - it.mEndAngle,
                        it.mEndAngle - it.mStartAngle,
                        true, mPiePaint);
            }
        }

        &#64;Override
        protected void onSizeChanged(int w, int h, int oldw, int oldh) {
            mBounds = new RectF(0, 0, w, h);
        }

        RectF mBounds;
    }
 </pre>

 <p>After this code change, {@code PieChart.PieView.onDraw()} is called only when the view is first
 shown. During the rest
 of the application's lifetime, the pie chart is cached as an image, and redrawn at different
 rotation angles by the GPU.
 GPU hardware is particularly good at this sort of thing, and the performance difference is
 immediately noticeable.</p>

 <p>There is a tradeoff, though. Caching images as hardware layers consumes video memory, which is a
 limited resource.
 For this reason, the final version of {@code PieChart.PieView} only sets its layer type to
 {@link android.view.View#LAYER_TYPE_HARDWARE}
 while the user is actively scrolling. At all other times, it sets its layer type to
 {@link android.view.View#LAYER_TYPE_NONE}, which
 allows the GPU to stop caching the image.</p>

 <p>Finally, don't forget to profile your code. Techniques that improve performance on one view
 might negatively affect performance on another.</p>
	page.title=Optimizing the View
	parent.title=Creating Custom Views
	parent.link=index.html

	trainingnavtop=true
	previous.title=Making the View Interactive
	previous.link=making-interactive.html

	@jd:body

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

	<h2>This lesson teaches you to</h2>
	<ol>
	<li><a href="#less">Do Less, Less Frequently</a></li>
	<li><a href="#accelerate">Use Hardware Acceleration</a></li>
	</ol>

	<h2>You should also read</h2>
	<ul>
	<li><a href="{@docRoot}guide/topics/graphics/hardware-accel.html">
	Hardware Acceleration
	</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>Now that you have a well-designed view that responds to gestures and transitions between states,
	you need to ensure
	that the view runs fast. To avoid a UI that feels sluggish or stutters during playback, you must
	ensure that your
	animations consistently run at 60 frames per second.</p>

	<h2 id="less">Do Less, Less Frequently</h2>

	<p>To speed up your view, eliminate unnecessary code from routines that are called frequently. Start
	by working on
	{@link android.view.View#onDraw onDraw()}, which will give you the biggest payback. In particular
	you should eliminate
	allocations in {@link android.view.View#onDraw onDraw()}, because allocations may lead to a garbage
	collection that
	would cause a stutter. Allocate objects during initialization, or between animations. Never make an
	allocation while an
	animation is running.</p>

	<p>In addition to making {@link android.view.View#onDraw onDraw()} leaner, you should also make sure
	it's called as
	infrequently as possible. Most calls to {@link android.view.View#onDraw onDraw()} are the result of
	a call to {@link
	android.view.View#invalidate() invalidate()}, so eliminate unnecessary calls to {@link
	android.view.View#invalidate()
	invalidate()}. When possible, call the four-parameter variant of {@link
	android.view.View#invalidate() invalidate()}
	rather than the version that takes no parameters. The no-parameter variant invalidates the entire
	view, while the
	four-parameter variant invalidates only a specified portion of the view. This approach allows draw calls to
	be more efficient and
	can eliminate unnecessary invalidation of views that fall outside the invalid rectangle.</p>

	<p>Another very expensive operation is traversing layouts. Any time a view calls {@link
	android.view.View#requestLayout()
	requestLayout()}, the Android UI system needs to traverse the entire view hierarchy to find out how
	big each view needs
	to be. If it finds conflicting measurements, it may need to traverse the hierarchy multiple times.
	UI designers
	sometimes create deep hierarchies of nested {@link android.view.ViewGroup ViewGroup} objects in
	order to get the UI to
	behave properly. These deep view hierarchies cause performance problems. Make your view hierarchies
	as shallow as
	possible.</p>

	<p>If you have a complex UI, you should consider writing a custom {@link android.view.ViewGroup
	ViewGroup} to perform
	its layout. Unlike the built-in views, your custom view can make application-specific assumptions
	about the size and
	shape of its children, and thus avoid traversing its children to calculate measurements. The
	PieChart example shows how
	to extend {@link android.view.ViewGroup ViewGroup} as part of a custom view. PieChart has child
	views, but it never
	measures them. Instead, it sets their sizes directly according to its own custom layout
	algorithm.</p>

	<h2 id="accelerate">Use Hardware Acceleration</h2>

	<p>As of Android 3.0, the Android 2D graphics system can be accelerated by the GPU (Graphics
	Processing Unit) hardware
	found in most newer Android devices. GPU hardware acceleration can result in a tremendous
	performance increase for many
	applications, but it isn't the right choice for every application. The Android framework
	gives you the ability to finely control which parts of your application are or are not
	hardware accelerated.</p>

	<p>See <a href="{@docRoot}guide/topics/graphics/hardware-accel.html">Hardware Acceleration</a>
	in the Android Developers Guide for directions on how to enable acceleration at the
	application, activity, or window level. Notice that in addition to the directions in
	the developer guide, you must also set your application's target API to 11 or higher by
	specifying {@code <uses-sdk
	android:targetSdkVersion="11"/>} in your {@code AndroidManifest.xml} file.</p>

	<p>Once you've enabled hardware acceleration, you may or may not see a performance increase.
	Mobile GPUs are very good at certain tasks, such as scaling, rotating, and translating
	bitmapped images. They are not particularly good at other tasks, such as drawing lines or curves. To
	get the most out of GPU acceleration, you should maximize the number of operations that the GPU is
	good at, and minimize the number of operations that the GPU isn't good at.</p>

	<p>In the PieChart example, for instance, drawing the pie is relatively expensive. Redrawing the pie
	each time it's
	rotated causes the UI to feel sluggish. The solution is to place the pie chart into a child
	{@link android.view.View} and set that
	{@link android.view.View}'s
	<a href="{@docRoot}reference/android/view/View.html#setLayerType(int, android.graphics.Paint)">
	layer type</a> to {@link android.view.View#LAYER_TYPE_HARDWARE}, so that the GPU can cache it as
	a static
	image. The sample
	defines the child view as an inner class of {@code PieChart}, which minimizes the amount of code
	changes that are needed
	to implement this solution.</p>

	<pre>
	private class PieView extends View {

	public PieView(Context context) {
	super(context);
	if (!isInEditMode()) {
	setLayerType(View.LAYER_TYPE_HARDWARE, null);
	}
	}

	@Override
	protected void onDraw(Canvas canvas) {
	super.onDraw(canvas);

	for (Item it : mData) {
	mPiePaint.setShader(it.mShader);
	canvas.drawArc(mBounds,
	360 - it.mEndAngle,
	it.mEndAngle - it.mStartAngle,
	true, mPiePaint);
	}
	}

	@Override
	protected void onSizeChanged(int w, int h, int oldw, int oldh) {
	mBounds = new RectF(0, 0, w, h);
	}

	RectF mBounds;
	}
	</pre>

	<p>After this code change, {@code PieChart.PieView.onDraw()} is called only when the view is first
	shown. During the rest
	of the application's lifetime, the pie chart is cached as an image, and redrawn at different
	rotation angles by the GPU.
	GPU hardware is particularly good at this sort of thing, and the performance difference is
	immediately noticeable.</p>

	<p>There is a tradeoff, though. Caching images as hardware layers consumes video memory, which is a
	limited resource.
	For this reason, the final version of {@code PieChart.PieView} only sets its layer type to
	{@link android.view.View#LAYER_TYPE_HARDWARE}
	while the user is actively scrolling. At all other times, it sets its layer type to
	{@link android.view.View#LAYER_TYPE_NONE}, which
	allows the GPU to stop caching the image.</p>

	<p>Finally, don't forget to profile your code. Techniques that improve performance on one view
	might negatively affect performance on another.</p>