Beginning in Android 3.0 (API level 11), the Android 2D rendering pipeline supports hardware
acceleration, meaning that all drawing operations that are performed on a View
's canvas use the GPU. Because of the increased resources required to enable
hardware acceleration, your app will consume more RAM.
Hardware acceleration is enabled by default if your Target API level is >=14, but can also
be explicitly enabled. If your application uses only standard views and Drawable
s, turning it on globally should not cause any adverse drawing
effects. However, because hardware acceleration is not supported for all of the 2D drawing
operations, turning it on might affect some of your custom views or drawing calls. Problems
usually manifest themselves as invisible elements, exceptions, or wrongly rendered pixels. To
remedy this, Android gives you the option to enable or disable hardware acceleration at multiple
levels. See Controlling Hardware Acceleration.
If your application performs custom drawing, test your application on actual hardware devices with hardware acceleration turned on to find any problems. The Unsupported drawing operations section describes known issues with hardware acceleration and how to work around them.
Controlling Hardware Acceleration
You can control hardware acceleration at the following levels:
- Application
- Activity
- Window
- View
Application level
In your Android manifest file, add the following attribute to the
<application>
tag to enable hardware acceleration for your entire
application:
<application android:hardwareAccelerated="true" ...>
Activity level
If your application does not behave properly with hardware acceleration turned on globally, you
can control it for individual activities as well. To enable or disable hardware acceleration at
the activity level, you can use the android:hardwareAccelerated
attribute for
the
<activity>
element. The following example enables hardware acceleration for
the entire application but disables it for one activity:
<application android:hardwareAccelerated="true"> <activity ... /> <activity android:hardwareAccelerated="false" /> </application>
Window level
If you need even more fine-grained control, you can enable hardware acceleration for a given window with the following code:
getWindow().setFlags( WindowManager.LayoutParams.FLAG_HARDWARE_ACCELERATED, WindowManager.LayoutParams.FLAG_HARDWARE_ACCELERATED);
Note: You currently cannot disable hardware acceleration at the window level.
View level
You can disable hardware acceleration for an individual view at runtime with the following code:
myView.setLayerType(View.LAYER_TYPE_SOFTWARE, null);
Note: You currently cannot enable hardware acceleration at the view level. View layers have other functions besides disabling hardware acceleration. See View layers for more information about their uses.
Determining if a View is Hardware Accelerated
It is sometimes useful for an application to know whether it is currently hardware accelerated, especially for things such as custom views. This is particularly useful if your application does a lot of custom drawing and not all operations are properly supported by the new rendering pipeline.
There are two different ways to check whether the application is hardware accelerated:
View.isHardwareAccelerated()
returnstrue
if theView
is attached to a hardware accelerated window.Canvas.isHardwareAccelerated()
returnstrue
if theCanvas
is hardware accelerated
If you must do this check in your drawing code, use Canvas.isHardwareAccelerated()
instead of View.isHardwareAccelerated()
when possible. When a view
is attached to a hardware accelerated window, it can still be drawn using a non-hardware
accelerated Canvas. This happens, for instance, when drawing a view into a bitmap for caching
purposes.
Android Drawing Models
When hardware acceleration is enabled, the Android framework utilizes a new drawing model that utilizes display lists to render your application to the screen. To fully understand display lists and how they might affect your application, it is useful to understand how Android draws views without hardware acceleration as well. The following sections describe the software-based and hardware-accelerated drawing models.
Software-based drawing model
In the software drawing model, views are drawn with the following two steps:
- Invalidate the hierarchy
- Draw the hierarchy
Whenever an application needs to update a part of its UI, it invokes invalidate()
(or one of its variants) on any view that has changed
content. The invalidation messages are propagated all the way up the view hierarchy to compute
the regions of the screen that need to be redrawn (the dirty region). The Android system then
draws any view in the hierarchy that intersects with the dirty region. Unfortunately, there are
two drawbacks to this drawing model:
- First, this model requires execution of a lot of code on every draw pass. For example, if
your application calls
invalidate()
on a button and that button sits on top of another view, the Android system redraws the view even though it hasn't changed. - The second issue is that the drawing model can hide bugs in your application. Since the
Android system redraws views when they intersect the dirty region, a view whose content you
changed might be redrawn even though
invalidate()
was not called on it. When this happens, you are relying on another view being invalidated to obtain the proper behavior. This behavior can change every time you modify your application. Because of this, you should always callinvalidate()
on your custom views whenever you modify data or state that affects the view’s drawing code.
Note: Android views automatically call invalidate()
when their properties change, such as the background
color or the text in a TextView
.
Hardware accelerated drawing model
The Android system still uses invalidate()
and draw()
to request screen updates and to render views, but handles the
actual drawing differently. Instead of executing the drawing commands immediately, the Android
system records them inside display lists, which contain the output of the view hierarchy’s
drawing code. Another optimization is that the Android system only needs to record and update
display lists for views marked dirty by an invalidate()
call. Views that have not been invalidated can be redrawn simply by re-issuing the previously
recorded display list. The new drawing model contains three stages:
- Invalidate the hierarchy
- Record and update display lists
- Draw the display lists
With this model, you cannot rely on a view intersecting the dirty region to have its draw()
method executed. To ensure that the Android system records a
view’s display list, you must call invalidate()
. Forgetting
to do so causes a view to look the same even after it has been changed.
Using display lists also benefits animation performance because setting specific properties,
such as alpha or rotation, does not require invalidating the targeted view (it is done
automatically). This optimization also applies to views with display lists (any view when your
application is hardware accelerated.) For example, assume there is a LinearLayout
that contains a ListView
above a Button
. The display list for the LinearLayout
looks like
this:
- DrawDisplayList(ListView)
- DrawDisplayList(Button)
Assume now that you want to change the ListView
's opacity. After
invoking setAlpha(0.5f)
on the ListView
, the display list now
contains this:
- SaveLayerAlpha(0.5)
- DrawDisplayList(ListView)
- Restore
- DrawDisplayList(Button)
The complex drawing code of ListView
was not executed. Instead, the
system only updated the display list of the much simpler LinearLayout
. In
an application without hardware acceleration enabled, the drawing code of both the list and its
parent are executed again.
Unsupported Drawing Operations
When hardware accelerated, the 2D rendering pipeline supports the most commonly used Canvas
drawing operations as well as many less-used operations. All of the
drawing operations that are used to render applications that ship with Android, default widgets
and layouts, and common advanced visual effects such as reflections and tiled textures are
supported.
The following table describes the support level of various operations across API levels:
First supported API level | ||||
Canvas | ||||
drawBitmapMesh() (colors array) | 18 | |||
drawPicture() | ✗ | |||
drawPosText() | 16 | |||
drawTextOnPath() | 16 | |||
drawVertices() | ✗ | |||
setDrawFilter() | 16 | |||
clipPath() | 18 | |||
clipRegion() | 18 | |||
clipRect(Region.Op.XOR) | 18 | |||
clipRect(Region.Op.Difference) | 18 | |||
clipRect(Region.Op.ReverseDifference) | 18 | |||
clipRect() with rotation/perspective | 18 | |||
drawArc() | 21 | |||
drawRoundRect() | 21 | |||
saveLayer() with RectF dimensions | 21 | |||
saveLayer() with float dimensions | 21 | |||
saveLayerAlpha() with RectF dimensions | 21 | |||
saveLayerAlpha() with float dimensions | 21 | |||
Paint | ||||
setAntiAlias() (for text) | 18 | |||
setAntiAlias() (for lines) | 16 | |||
setFilterBitmap() | 17 | |||
setLinearText() | ✗ | |||
setMaskFilter() | ✗ | |||
setPathEffect() (for lines) | ✗ | |||
setRasterizer() | ✗ | |||
setShadowLayer() (other than text) | ✗ | |||
setStrokeCap() (for lines) | 18 | |||
setStrokeCap() (for points) | 19 | |||
setSubpixelText() | ✗ | |||
getFontFeatureSettings() | 21 | |||
isElegantTextHeight() | 21 | |||
isElegantTextHeight() | 21 | |||
setFontFeatureSettings() | 21 | |||
setLetterSpacing() | 21 | |||
Xfermode | ||||
AvoidXfermode | ✗ | |||
PixelXorXfermode | ✗ | |||
PorterDuff.Mode.DARKEN (framebuffer) | ✗ | |||
PorterDuff.Mode.LIGHTEN (framebuffer) | ✗ | |||
PorterDuff.Mode.OVERLAY (framebuffer) | ✗ | |||
Shader | ||||
ComposeShader inside ComposeShader | ✗ | |||
Same type shaders inside ComposeShader | ✗ | |||
Local matrix on ComposeShader | 18 |
Canvas Scaling
The hardware accelerated 2D rendering pipeline was built first to support unscaled drawing, with some drawing operations degrading quality significantly at higher scale values. These operations are implemented as textures drawn at scale 1.0, transformed by the GPU. In API level <17, using these operations will result in scaling artifacts increasing with scale.
The following table shows when implementation was changed to correctly handle large scales:Drawing operation to be scaled | First supported API level |
drawText() | 18 |
drawPosText() | ✗ |
drawTextOnPath() | ✗ |
Simple Shapes* | 17 |
Complex Shapes* | ✗ |
drawPath() | ✗ |
Shadow layer | ✗ |
Note: 'Simple' shapes are drawRect()
,
drawCircle()
, drawOval()
, drawRoundRect()
, and
drawArc()
(with useCenter=false) commands issued with a Paint that doesn't have a
PathEffect, and doesn't contain non-default joins (via setStrokeJoin()
/
setStrokeMiter()
). Other instances of those draw commands fall under 'Complex,' in
the above chart.
If your application is affected by any of these missing features or limitations, you can turn
off hardware acceleration for just the affected portion of your application by calling setLayerType(View.LAYER_TYPE_SOFTWARE, null)
. This way, you can
still take advantage of hardware acceleration everywhere else. See Controlling Hardware Acceleration for more information on how to enable
and disable hardware acceleration at different levels in your application.
View Layers
In all versions of Android, views have had the ability to render into off-screen buffers,
either by using a view's drawing cache, or by using Canvas.saveLayer()
. Off-screen buffers, or layers, have several uses. You can use them to get
better performance when animating complex views or to apply composition effects. For instance,
you can implement fade effects using Canvas.saveLayer()
to temporarily render a view
into a layer and then composite it back on screen with an opacity factor.
Beginning in Android 3.0 (API level 11), you have more control on how and when to use layers
with the View.setLayerType()
method. This API takes two
parameters: the type of layer you want to use and an optional Paint
object that describes how the layer should be composited. You can use the Paint
parameter to apply color filters, special blending modes, or opacity to a
layer. A view can use one of three layer types:
LAYER_TYPE_NONE
: The view is rendered normally and is not backed by an off-screen buffer. This is the default behavior.LAYER_TYPE_HARDWARE
: The view is rendered in hardware into a hardware texture if the application is hardware accelerated. If the application is not hardware accelerated, this layer type behaves the same asLAYER_TYPE_SOFTWARE
.LAYER_TYPE_SOFTWARE
: The view is rendered in software into a bitmap.
The type of layer you use depends on your goal:
- Performance: Use a hardware layer type to render a view into a hardware
texture. Once a view is rendered into a layer, its drawing code does not have to be executed
until the view calls
invalidate()
. Some animations, such as alpha animations, can then be applied directly onto the layer, which is very efficient for the GPU to do. - Visual effects: Use a hardware or software layer type and a
Paint
to apply special visual treatments to a view. For instance, you can draw a view in black and white using aColorMatrixColorFilter
. - Compatibility: Use a software layer type to force a view to be rendered in software. If a view that is hardware accelerated (for instance, if your whole application is hardware acclerated), is having rendering problems, this is an easy way to work around limitations of the hardware rendering pipeline.
View layers and animations
Hardware layers can deliver faster and smoother animations when your application
is hardware accelerated. Running an animation at 60 frames per second is not always possible when
animating complex views that issue a lot of drawing operations. This can be alleviated by
using hardware layers to render the view to a hardware texture. The hardware texture can
then be used to animate the view, eliminating the need for the view to constantly redraw itself
when it is being animated. The view is not redrawn unless you change the view's
properties, which calls invalidate()
, or if you call invalidate()
manually. If you are running an animation in
your application and do not obtain the smooth results you want, consider enabling hardware layers on
your animated views.
When a view is backed by a hardware layer, some of its properties are handled by the way the layer is composited on screen. Setting these properties will be efficient because they do not require the view to be invalidated and redrawn. The following list of properties affect the way the layer is composited. Calling the setter for any of these properties results in optimal invalidation and no redrawing of the targeted view:
alpha
: Changes the layer's opacityx
,y
,translationX
,translationY
: Changes the layer's positionscaleX
,scaleY
: Changes the layer's sizerotation
,rotationX
,rotationY
: Changes the layer's orientation in 3D spacepivotX
,pivotY
: Changes the layer's transformations origin
These properties are the names used when animating a view with an ObjectAnimator
. If you want to access these properties, call the appropriate
setter or getter. For instance, to modify the alpha property, call setAlpha()
. The following code snippet shows the most efficient way
to rotate a viewiew in 3D around the Y-axis:
view.setLayerType(View.LAYER_TYPE_HARDWARE, null); ObjectAnimator.ofFloat(view, "rotationY", 180).start();
Because hardware layers consume video memory, it is highly recommended that you enable them only for the duration of the animation and then disable them after the animation is done. You can accomplish this using animation listeners:
View.setLayerType(View.LAYER_TYPE_HARDWARE, null); ObjectAnimator animator = ObjectAnimator.ofFloat(view, "rotationY", 180); animator.addListener(new AnimatorListenerAdapter() { @Override public void onAnimationEnd(Animator animation) { view.setLayerType(View.LAYER_TYPE_NONE, null); } }); animator.start();
For more information on property animation, see Property Animation.
Tips and Tricks
Switching to hardware accelerated 2D graphics can instantly increase performance, but you should still design your application to use the GPU effectively by following these recommendations:
- Reduce the number of views in your application
- The more views the system has to draw, the slower it will be. This applies to the software rendering pipeline as well. Reducing views is one of the easiest ways to optimize your UI.
- Avoid overdraw
- Do not draw too many layers on top of each other. Remove any views that are completely obscured by other opaque views on top of it. If you need to draw several layers blended on top of each other, consider merging them into a single layer. A good rule of thumb with current hardware is to not draw more than 2.5 times the number of pixels on screen per frame (transparent pixels in a bitmap count!).
- Don't create render objects in draw methods
- A common mistake is to create a new
Paint
or a newPath
every time a rendering method is invoked. This forces the garbage collector to run more often and also bypasses caches and optimizations in the hardware pipeline. - Don't modify shapes too often
- Complex shapes, paths, and circles for instance, are rendered using texture masks. Every time you create or modify a path, the hardware pipeline creates a new mask, which can be expensive.
- Don't modify bitmaps too often
- Every time you change the content of a bitmap, it is uploaded again as a GPU texture the next time you draw it.
- Use alpha with care
- When you make a view translucent using
setAlpha()
,AlphaAnimation
, orObjectAnimator
, it is rendered in an off-screen buffer which doubles the required fill-rate. When applying alpha on very large views, consider setting the view's layer type toLAYER_TYPE_HARDWARE
.