New Layout Widgets: Space and GridLayout

[This post is by Philip Milne, who is part of the Android framework team. — Tim Bray]

Ice Cream Sandwich (ICS) sports two new widgets that have been designed to support the richer user interfaces made possible by larger displays: Space and GridLayout.

The most commonly used class for layout in Android is LinearLayout, which allows its children to be aligned in the usual ways: along either the horizontal or vertical axes. It’s often possible to take a complicated layout and break it down into a set of nested linear layouts and, provided this nesting doesn’t get too deep, this is still a good choice for many simple layouts.

A number of posts and articles (e.g. Android Layout Tricks #1, Flattening The Stack) have highlighted drawbacks of nested layouts; which fall into three basic categories:

• Inability to control alignment along both axes simultaneously




• Performance problems in hierarchies that are too deep




• Unsuitability for design tools that support free-form editing

A simple example of the first problem is the following form:

As the font and the text of the “Email address” label change, we want the label to remain aligned with the baseline of the component to its right, and aligned with the right edge of the label below it. It’s not possible to do this with nested LinearLayouts because the label needs to be aligned with other components both horizontally and vertically.

These problems aren’t new to Android, or UI toolkits in general, but we’ve used them to drive our work in enriching platform support for flatter hierarchies.

GridLayout

To provide better support for layouts like these we have added a new layout to the Android framework: GridLayout, which can be used to solve the above problems by dividing the container’s real estate into rows and columns:

Now the “Email address” label can belong both to a row that is baseline-aligned, and a column that is right-aligned.

GridLayout uses a grid of infinitely-thin lines to separate its drawing area into: rows, columns, and cells. It supports both row and column spanning, which together allow a widget to occupy a rectangular range of cells that are next to each other. We’ll use the words row, column, and cell in the text below as shorthand for row group, column group and cell group respectively, where groups have one or more contiguous elements.

Similarities with LinearLayout

Wherever possible, GridLayout uses the same conventions as LinearLayout for all its XML API — so it should be easy to start using GridLayout if you’ve already used LinearLayout. In fact, the APIs are so similar that changing a tag name from LinearLayout to GridLayout in an XML file that uses LinearLayout will often produce a similar UI without requiring any other changes. When it doesn’t, you’ll still generally end up with a good starting point for a two-dimensional layout.

Getting Started

Two examples in the samples area of the Android 4.0 SDK show typical use of the programmatic and XML APIs respectively:

• samples/ApiDemos/src/com/example/android/apis/view/GridLayout0.java




• samples/ApiDemos/res/layout/grid_layout_1.xml

[Both examples produce the same UI.]

Here’s a slightly simpler version of the above XML layout.

<?xml version="1.0" encoding="utf-8"?>
<GridLayout
        xmlns:android="http://schemas.android.com/apk/res/android"

        android:layout_width="match_parent"
        android:layout_height="match_parent"

        android:useDefaultMargins="true"
        android:alignmentMode="alignBounds"
        android:columnOrderPreserved="false"

        android:columnCount="4"
        >

    <TextView
            android:text="Email setup"
            android:textSize="32dip"

            android:layout_columnSpan="4"
            android:layout_gravity="center_horizontal"
            />

    <TextView
            android:text="You can configure email in just a few steps:"
            android:textSize="16dip"

            android:layout_columnSpan="4"
            android:layout_gravity="left"
            />

    <TextView
            android:text="Email address:"

            android:layout_gravity="right"
            />

    <EditText
            android:ems="10"
            />

    <TextView
            android:text="Password:"

            android:layout_column="0"
            android:layout_gravity="right"
            />

    <EditText
            android:ems="8"
            />

    <Space
            android:layout_row="4"
            android:layout_column="0"
            android:layout_columnSpan="3"
            android:layout_gravity="fill"
            />

    <Button
            android:text="Next"

            android:layout_row="5"
            android:layout_column="3"
            />
</GridLayout>

The first difference you’ll notice in these examples is the absence of the WRAP_CONTENT and MATCH_PARENT constants that normally adorn Android layout resources. You don’t normally need to use these with GridLayout, for reasons that are described in the API doc for GridLayout.LayoutParams.

Row and Column Indices

The second thing you may notice in the XML resources is that widgets don’t always explicitly define which cells they are to be placed in. Each widget’s layout parameters have row and column indices that together define where the widget should be placed but when either or both of these values are not specified, GridLayout supplies default values rather than throwing an exception.

Automatic Index Allocation

As children are added to a GridLayout, it maintains a cursor position and a “high-water mark” that it uses to place widgets in cells that don’t yet have anything in them.

When GridLayout’s orientation property is horizontal and a columnCount has been set (to 8 in this example) the high-water mark (shown above in red) is maintained as a separate height value for each column. When indices need to be created, GridLayout first determines the size of the cell group (by looking at the rowSpan and columnSpan parameters of the new widget) and then, starting at the cursor, goes through the available locations from: left to right, top to bottom, so as to find the row and column indices of the first location that’s free.

When GridLayout’s orientation is vertical, all of the same principles apply, except that the roles of the horizontal and vertical axes are exchanged.

If you want multiple views to be placed in the same cell, you have to define the indices explicitly, as the default allocation procedure above is designed to place widgets in separate cells.

Sizes, Margins and Alignment/Gravity

In GridLayout, specifying sizes and margins is done just as with a LinearLayout. Alignment/gravity also works just like gravity in LinearLayout and uses the same constants: left, top, right, bottom, center_horizontal, center_vertical, center, fill_horizontal, fill_vertical and fill.

Flexibility

Unlike most grids in other toolkits, GridLayout does not associate data with rows or columns. Instead, everything to do with alignment and flexibility is associated with the components themselves. GridLayout departs from the norm here to provide a more general system that allows subtle relationships between ancestors in deeply nested layouts to be accommodated in a single layout configuration.

The flexibility of columns is inferred from the gravity of the components inside the column. If every component defines a gravity, the column is taken as flexible, otherwise the column is considered inflexible. Full details are in GridLayout’s API docs.

Emulating Features from other Layouts

GridLayout does not incorporate all of the features of every layout in the Android platform but it has a rich enough feature set that idiomatic use of other layouts can normally be emulated from inside a single GridLayout.

Although LinearLayout can be considered a special case of a GridLayout, for the degenerate case when a set of views are aligned in a single row or column, LinearLayout is the better choice when this is all that is required as it clarifies the purpose of the container and may have some (relatively small) performance advantages.

TableLayout configurations are normally straightforward to accommodate, as GridLayout supports both row and column spanning. TableRows can be removed, as they are not required by GridLayout. For the same UI, a GridLayout will generally be faster and take less memory than than a TableLayout.

Simple RelativeLayout configurations can be written as grids simply by grouping the views that are related to each other into rows and columns. Unlike conventional grids, GridLayout uses a constraints solver to do the heavy lifting of the layout operation. By using GridLayout’s rowOrderPreserved and columnOrderPreserved properties it’s possible to free GridLayout from the confines of traditional grid systems and support the majority of RelativeLayout configurations — even ones that require grid lines to pass over each other as children change size.

Simple FrameLayout configurations can be accommodated within the cells of a GridLayout because a single cell can contain multiple views. To switch between two views, place them both in the same cell and use the visibility constant GONE to switch from one to the other from code. As with the LinearLayout case above, if all you need is the functionality described above, FrameLayout is the better choice and may have some small performance advantages.

One key feature that GridLayout lacks is the ability to distribute excess space between rows or columns in specified proportions — a feature that LinearLayout provides by supporting the principle of weight. This omission and possible ways around it are discussed in GridLayout’s API docs.

The Phases of the Layout Operation

It’s useful to distinguish the allocation phase for cell indices discussed above from the layout operation itself. Normally the phase that allocates indices happens once, if at all, when a UI is initialized. The index-allocation phase only applies when indices have been left unspecified, and is responsible for ensuring that all views have a defined set of cells in which they are to be placed at layout time.

The layout operation happens after this and is recalculated each time a view changes size. GridLayout measures the size of each child during the layout operation so it can calcuate the heights and widths of the rows and columns in the grid. The layout phase completes by using gravity to place each of the components in its cell.

Although index allocation normally only happens once, GridLayout is technically a dynamic layout, meaning that if you change its orientation property or add or remove children after components have been laid out, GridLayout will repeat the above procedure to reallocate indices in a way that is right for the new configuration.

From a performance standpoint, it is worth knowing that the GridLayout implementation has been optimized for the common case, when initialization happens once and layout happens frequently. As a result, the initialization step sets up internal data structures so that the layout operation can complete quickly and without allocating memory. Put another way, changes either to GridLayout’s orientation or the number of children it has are much more expensive than an ordinary layout operation.

Conclusion

GridLayout’s feature set incorporates much of the functionality of the Android framework’s existing general-purpose layouts: LinearLayout, FrameLayout, TableLayout and RelativeLayout. As such, it provides a way to replace many deeply nested view hierarchies with a single highly optimized layout implementation.

If you are starting a UI from scratch and are not familiar with Android layouts, use a GridLayout — it supports most of the features of the other layouts and has a simpler and more general API than either TableLayout or RelativeLayout.

We anticipate that the combination of FrameLayout, LinearLayout and GridLayout together will provide a feature set that’s rich enough to allow most layout problems to be solved without writing layout code by hand. It’s worth spending some time deciding which of these layouts is right for the top of your tree; a good choice will minimize the need for intermediate containers and result in a user interface that is faster and uses less memory.

New Tools For Managing Screen Sizes

[This post is by Dianne Hackborn and a supporting cast of thousands; Dianne’s fingerprints can be found all over the Android Application Framework — Tim Bray]

Android 3.2 includes new tools for supporting devices with a wide range of screen sizes. One important result is better support for a new size of screen; what is typically called a “7-inch” tablet. This release also offers several new APIs to simplify developers’ work in adjusting to different screen sizes.

This a long post. We start by discussing the why and how of Android “dp” arithmetic, and the finer points of the screen-size buckets. If you know all that stuff, you can skip down to “Introducing Numeric Selectors” to read about what’s new. We also provide our recommendations for how you can do layout selection in apps targeted at Android 3.2 and higher in a way that should allow you to support the maximum number of device geometries with the minimum amount of effort.

Of course, the official write-up on Supporting Multiple Screens is also required reading for people working in this space.

Understanding Screen Densities and the “dp”

Resolution is the actual number of pixels available in the display, density is how many pixels appear within a constant area of the display, and size is the amount of physical space available for displaying your interface. These are interrelated: increase the resolution and density together, and size stays about the same. This is why the 320x480 screen on a G1 and 480x800 screen on a Droid are both the same screen size: the 480x800 screen has more pixels, but it is also higher density.

To remove the size/density calculations from the picture, the Android framework works wherever possible in terms of "dp" units, which are corrected for density. In medium-density ("mdpi") screens, which correspond to the original Android phones, physical pixels are identical to dp's; the devices’ dimensions are 320x480 in either scale. A more recent phone might have physical-pixel dimensions of 480x800 but be a high-density device. The conversion factor from hdpi to mdpi in this case is 1.5, so for a developer's purposes, the device is 320x533 in dp's.

Screen-size Buckets

Android has included support for three screen-size “buckets” since 1.6, based on these “dp” units: “normal” is currently the most popular device format (originally 320x480, more recently higher-density 480x800); “small” is for smaller screens, and “large” is for “substantially larger” screens. Devices that fall in the “large” bucket include the Dell Streak and original 7” Samsung Galaxy Tab. Android 2.3 introduced a new bucket size “xlarge”, in preparation for the approximately-10” tablets (such as the Motorola Xoom) that Android 3.0 was designed to support.

The definitions are:

• xlarge screens are at least 960dp x 720dp.




• large screens are at least 640dp x 480dp.




• normal screens are at least 470dp x 320dp.




• small screens are at least 426dp x 320dp. (Android does not currently support screens smaller than this.)

Here are some more examples of how this works with real screens:

• A QVGA screen is 320x240 ldpi. Converting to mdpi (a 4/3 scaling factor) gives us 426dp x 320dp; this matches the minimum size above for the small screen bucket.




• The Xoom is a typical 10” tablet with a 1280x800 mdpi screen. This places it into the xlarge screen bucket.




• The Dell Streak is a 800x480 mdpi screen. This places it into the bottom of the large size bucket.




• A typical 7” tablet has a 1024x600 mdpi screen. This also counts as a large screen.




• The original Samsung Galaxy Tab is an interesting case. Physically it is a 1024x600 7” screen and thus classified as “large”. However the device configures its screen as hdpi, which means after applying the appropriate ⅔ scaling factor the actual space on the screen is 682dp x 400dp. This actually moves it out of the “large” bucket and into a “normal” screen size. The Tab actually reports that it is “large”; this was a mistake in the framework’s computation of the size for that device that we made. Today no devices should ship like this.

Issues With Buckets

Based on developers’ experience so far, we’re not convinced that this limited set of screen-size buckets gives developers everything they need in adapting to the increasing variety of Android-device shapes and sizes. The primary problem is that the borders between the buckets may not always correspond to either devices available to consumers or to the particular needs of apps.

The “normal” and “xlarge” screen sizes should be fairly straightforward as a target: “normal” screens generally require single panes of information that the user moves between, while “xlarge” screens can comfortably hold multi-pane UIs (even in portrait orientation, with some tightening of the space).

The “small” screen size is really an artifact of the original Android devices having 320x480 screens. 240x320 screens have a shorter aspect ratio, and applications that don’t take this into account can break on them. These days it is good practice to test user interfaces on a small screen to ensure there are no serious problems.

The “large” screen size has been challenging for developers — you will notice that it encompases everything from the Dell Streak to the original Galaxy Tab to 7" tablets in general. Different applications may also reasonably want to take different approaches to these two devices; it is also quite reasonable to want to have different behavior for landscape vs. portrait large devices because landscape has plenty of space for a multi-pane UI, while portrait may not.

Introducing Numeric Selectors

Android 3.2 introduces a new approach to screen sizes, with the goal of making developers' lives easier. We have defined a set of numbers describing device screen sizes, which you can use to select resources or otherwise adjust your UI. We believe that using these will not only reduce developers’ workloads, but future-proof their apps significantly.

The numbers describing the screen size are all in “dp” units (remember that your layout dimensions should also be in dp units so that the system can adjust for screen density). They are:

• width dp: the current width available for application layout in “dp” units; changes when the screen switches orientation between landscape and portrait.




• height dp: the current height available for application layout in “dp” units; also changes when the screen switches orientation.




• smallest width dp: the smallest width available for application layout in “dp” units; this is the smallest width dp that you will ever encounter in any rotation of the display.

Of these, smallest width dp is the most important. It replaces the old screen-size buckets with a continuous range of numbers giving the effective size. This number is based on width because that is fairly universally the driving factor in designing a layout. A UI will often scroll vertically, but have fairly hard constraints on the minimum space it needs horizontally; the available width is also the key factor in determining whether to use a phone-style one-pane layout or tablet-style multi-pane layout.

Typical numbers for screen width dp are:

• 320: a phone screen (240x320 ldpi, 320x480 mdpi, 480x800 hdpi, etc).




• 480: a tweener tablet like the Streak (480x800 mdpi).




• 600: a 7” tablet (600x1024).




• 720: a 10” tablet (720x1280, 800x1280, etc).

Using the New Selectors

When you are designing your UI, the main thing you probably care about is where you switch between a phone-style UI and a tablet-style multi-pane UI. The exact point of this switch will depend on your particular design — maybe you need a full 720dp width for your tablet layout, maybe 600dp is enough, or 480dp, or even some other number between those. Either pick a width and design to it; or after doing your design, find the smallest width it supports.

Now you can select your layout resources for phones vs. tablets using the number you want. For example, if 600dp is the smallest width for your tablet UI, you can do this:

res/layout/main_activity.xml           # For phones
res/layout-sw600dp/main_activity.xml   # For tablets

For the rare case where you want to further customize your UI, for example for 7” vs. 10” tablets, you can define additional smallest widths:

res/layout/main_activity.xml           # For phones
res/layout-sw600dp/main_activity.xml   # For 7” tablets
res/layout-sw720dp/main_activity.xml   # For 10” tablets

Android will pick the resource that is closest to the device’s “smallest width,” without being larger; so for a hypothetical 700dp x 1200dp tablet, it would pick layout-sw600dp.

If you want to get fancier, you can make a layout that can change when the user switches orientation to the one that best fits in the current available width. This can be of particular use for 7” tablets, where a multi-pane layout is a very tight fit in portrait::

res/layout/main_activity.xml          # Single-pane
res/layout-w600dp/main_activity.xml   # Multi-pane when enough width

Or the previous three-layout example could use this to switch to the full UI whenever there is enough width:

res/layout/main_activity.xml                 # For phones
res/layout-sw600dp/main_activity.xml         # Tablets
res/layout-sw600dp-w720dp/main_activity.xml  # Large width

In the setup above, we will always use the phone layout for devices whose smallest width is less than 600dp; for devices whose smallest width is at least 600dp, we will switch between the tablet and large width layouts depending on the current available width.

You can also mix in other resource qualifiers:

res/layout/main_activity.xml                 # For phones
res/layout-sw600dp/main_activity.xml         # Tablets
res/layout-sw600dp-port/main_activity.xml    # Tablets when portrait

Selector Precedence

While it is safest to specify multiple configurations like this to avoid potential ambiguity, you can also take advantage of some subtleties of resource matching. For example, the order that resource qualifiers must be specified in the directory name (documented in Providing Resources) is also the order of their “importance.” Earlier ones are more important than later ones. You can take advantage of this to, for example, easily have a landscape orientation specialization for your default layout:

res/layout/main_activity.xml                 # For phones
res/layout-land/main_activity.xml            # For phones when landscape
res/layout-sw600dp/main_activity.xml         # Tablets

In this case when running on a tablet that is using landscape orientation, the last layout will be used because the “swNNNdp” qualifier is a better match than “port”.

Combinations and Versions

One final thing we need to address is specifying layouts that work on both Android 3.2 and up as well as previous versions of the platform.

Previous versions of the platform will ignore any resources using the new resource qualifiers. This, then, is one approach that will work:

res/layout/main_activity.xml           # For phones
res/layout-xlarge/main_activity.xml    # For pre-3.2 tablets
res/layout-sw600dp/main_activity.xml   # For 3.2 and up tablets

This does require, however, that you have two copies of your tablet layout. One way to avoid this is by defining the tablet layout once as a distinct resource, and then making new versions of the original layout resource that point to it. So the layout resources we would have are:

res/layout/main_activity.xml           # For phones
res/layout/main_activity_tablet.xml    # For tablets

To have the original layout point to the tablet version, you put <item> specifications in the appropriate values directories. That is these two files:

res/values-xlarge/layout.xml
res/values-sw600dp/layout.xml

Both would contain the following XML defining the desired resource:

<?xml version="1.0" encoding="utf-8"?>
<resources>
    <item type="layout" name="main_activty">
            @layout/main_activity_tablet
    </item>
</resources>

Of course, you can always simply select the resource to use in code. That is, define two or more resources like “layout/main_activity” and “layout/main_activity_tablet,” and select the one to use in your code based on information in the Configuration object or elsewhere. For example:

public class MyActivity extends Activity {
    @Override protected void onCreate(Bundle savedInstanceState) {
        super.onCreate();

        Configuration config = getResources().getConfiguration();
        if (config.smallestScreenWidthDp >= 600) {
            setContentView(R.layout.main_activity_tablet);
        } else {
            setContentView(R.layout.main_activity);
        }
    }
}

Conclusion

We strongly recommend that developers start using the new layout selectors for apps targeted at Android release 3.2 or higher, as we will be doing for Google apps. We think they will make your layout choices easier to express and manage.

Furthermore, we can see a remarkably wide variety of Android-device form factors coming down the pipe. This is a good thing, and will expand the market for your work. These new layout selectors are specifically designed to make it straightforward for you to make your apps run well in a future hardware ecosystem which is full of variety (and surprises).

New Mode for Apps on Large Screens

[This post is by Scott Main, lead tech writer for developer.android.com. — Tim Bray]

Android tablets are becoming more popular, and we're pleased to note that the vast majority of apps resize to the larger screens just fine. To keep the few apps that don't resize well from frustrating users with awkward-looking apps on their tablets, Android 3.2 introduces a screen compatibility mode that makes these apps more usable on tablets. If your app is one of the many that do resize well, however, you should update your app as soon as possible to disable screen compatibility mode so that users experience your app the way you intend.

Beginning with Android 3.2, any app that does not target Android 3.0 (set either android:minSdkVersion or android:targetSdkVersion to “11” or higher) or does not explicitly set android:xlargeScreens="true" in the <supports-screens> element will include a button in the system bar that, when touched, allows users to select between two viewing modes on large-screen devices.

“Stretch to fill screen” is normal layout resizing (using your app’s alternative resources for size and density) and “Zoom to fill screen” is the new screen compatibility mode.

When the user enables this screen compatibility mode, the system no longer resizes your layout to fit the screen. Instead, it runs your app in an emulated normal/mdpi screen (approximately 320dp x 480dp) and scales that up to fill the screen---imagine viewing your app at the size of a phone screen then zooming in about 200%. The effect is that everything is bigger, but also more pixelated, because the system does not resize your layout or use your alternative resources for the current device (the system uses all resources for a normal/mdpi device). Here’s a comparison of what it looks like (screen compatibility mode enabled on the right):

In cases where an app does not properly resize for larger screens, this screen compatibility mode can improve the app’s usability by emulating the app’s phone-style look, but zoomed in to fill the screen on a tablet.

However, most apps (even those that don’t specifically target Honeycomb) look just fine on tablets without screen compatibility mode, due to the use of alternative layouts for different screen sizes and the framework’s flexibility when resizing layouts. Unfortunately, if you haven’t said so in your manifest file, the system doesn’t know that your application properly supports large screens. Thus, if you’ve developed your app against any version lower than Android 3.0 and do not declare support for large screens in your manifest, the system is going to offer users the option to enable screen compatibility mode.

So, if your app is actually designed to resize for large screens, screen compatibility mode is probably an inferior user experience for your app and you should prevent users from using it. The easiest way to make sure that users cannot enable screen compatibility mode for your app is to declare support for xlarge screens in your manifest file’s <supports-screens> element. For example:

<manifest ... >
    <supports-screens android:xlargeScreens="true" />
    ...
</manifest>

That’s it! No more screen compatibility mode.

Note: If your app is specifically designed to support Android 3.0 and declares either android:minSdkVersion or android:targetSdkVersion with a value of “11” or greater, then your app is already in the clear and screen compatibility mode will not be offered to users, but adding this attribute certainly won’t hurt.

In conclusion, if your app has set the android:minSdkVersion and android:targetSdkVersion both with values less than “11” and you believe your app works well on large and xlarge screens (for example, you’ve tested on a Honeycomb tablet), you should make the above addition to your manifest file in order to disable the new screen compatibility mode.

If your app does not resize properly for large screens, then users might better enjoy your app using screen compatibility mode. However, please follow our guide to Supporting Multiple Screens so that you can also disable screen compatibility mode and provide a user experience that’s optimized for large-screen devices.