Saving and Restoring Activity State in Android Studio
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If the previous few chapters have achieved their objective, it should now be a little clearer as to the importance of saving and restoring the state of a user interface at particular points in the lifetime of an activity.
In this chapter, we will extend the example application created in Android Activity State Changes - An Android Studio Example to demonstrate the steps involved in saving and restoring state when an activity is destroyed and recreated by the runtime system.
A key component of saving and restoring dynamic state involves the use of the Android SDK Bundle class, a topic that will also be covered in this chapter.
Saving Dynamic State
An activity, as we have already learned, is given the opportunity to save dynamic state information via a call from the runtime system to the activity’s implementation of the onSaveInstanceState() method. Passed through as an argument to the method is a reference to a Bundle object into which the method will need to store any dynamic data that needs to be saved. The Bundle object is then stored by the runtime system on behalf of the activity and subsequently passed through as an argument to the activity’s onCreate() and onRestoreInstanceState() methods if and when they are called. The data can then be retrieved from the Bundle object within these methods and used to restore the state of the activity.
Default Saving of User Interface State
In the previous chapter, the diagnostic output from the StateChange example application showed that an activity goes through a number of state changes when the device on which it is running is rotated sufficiently to trigger an orientation change.
Launch the StateChange application once again, this time entering some text into the EditText field prior to performing the device rotation. Having rotated the device, the following state change sequence should appear in the LogCat window:
onPause onSaveInstanceState onStop onDestroy onCreate onStart onRestoreInstanceState onResume
Clearly this has resulted in the activity being destroyed and re-created. A review of the user interface of the running application, however, should show that the text entered into the EditText field has been preserved. Given that the activity was destroyed and recreated, and that we did not add any specific code to make sure the text was saved and restored, this behavior requires some explanation.
In actual fact most of the view widgets included with the Android SDK already implement the behavior necessary to automatically save and restore state when an activity is restarted. The only requirement to enable this behavior is for the onSaveInstanceState() and onRestoreInstanceState() override methods in the activity to include calls to the equivalent methods of the super class:
@Override protected void onSaveInstanceState(Bundle outState) { super.onSaveInstanceState(outState); } @Override protected void onRestoreInstanceState(Bundle savedInstanceState) { super.onRestoreInstanceState(savedInstanceState); }
The automatic saving of state for a user interface view can be disabled in the XML layout file by setting the android:saveEnabled property to false. For the purposes of an example, we will disable the automatic state saving mechanism for the EditText view in the user interface layout and then add code to the application to manually save and restore the state of the view.
To configure the EditText view such that state will not be saved and restored in the event that the activity is restarted, edit the activity_state_change.xml file so that the entry for the view reads as follows (note that the XML can be edited directly by clicking on the Text tab on the bottom edge of the Designer panel):
<EditText android:layout_width="wrap_content" android:layout_height="wrap_content" android:id="@+id/editText" android:saveEnabled="false" android:inputType="text" android:layout_centerVertical="true" android:layout_centerHorizontal="true" android:width="200dp" />
After making the change, run the application, enter text and rotate the device to verify that the text is no longer saved and restored before proceeding.
The Bundle Class
For situations where state needs to be saved beyond the default functionality provided by the user interface view components, the Bundle class provides a container for storing data using a key-value pair mechanism. The keys take the form of string values, whilst the values associated with those keys can be in the form of a primitive value or any object that implements the Android Parcelable interface. A wide range of classes already implements the Parcelable interface. Custom classes may be made “parcelable” by implementing the set of methods defined in the Parcelable interface (details of which can be found in the Android documentation at http://developer.android.com/reference/android/os/Parcelable.html).
The Bundle class also contains a set of methods that can be used to get and set key-value pairs for a variety of data types including both primitive types (including Boolean, char, double and float values) and objects (such as Strings and CharSequences).
For the purposes of this example, and having disabled the automatic saving of text for the EditText view, we need to make sure that the text entered into the EditText field by the user is saved into the Bundle object and subsequently restored. This will serve as a demonstration of how to manually save and restore state within an Android application and will be achieved using the putCharSequence() and getCharSequence() methods of the Bundle class respectively.
Saving the State
The first step in extending the StateChange application is to make sure that the text entered by the user is extracted from the EditText component within the onSaveInstanceState() method of the StateChangeActivity activity, and then saved as a key-value pair into the Bundle object.
In order to extract the text from the EditText object we first need to identify that object in the user interface. Clearly, this involves bridging the gap between the Java code for the activity (contained in the StateChangeActivity.java source code file) and the XML representation of the user interface (contained within the activity_state_change.xml resource file). In order to extract the text entered into the EditText component we need to gain access to that user interface object.
Each component within a user interface has associated with it a unique identifier. By default, the Designer tool constructs the ID for a newly added component from the object type. If more than one view of the same type is contained in the layout the type name is followed by a sequential number (though this can, and should, be changed to something more meaningful by the developer). As can be seen by checking the Component panel within the Android Studio main window when the activity_state_change.xml file is selected and the Designer tool displayed, the EditText component has been assigned the ID editText:
Figure 13-1
final EditText textBox = (EditText) findViewById(R.id.editText);
Having obtained a reference to the EditText object and assigned it to textBox, we can now obtain the text that it contains by calling the object’s getText() method, which, in turn, returns the current text in the form of a CharSequence object:
CharSequence userText = textBox.getText();
Finally, we can save the text using the Bundle object’s putCharSequence() method, passing through the key (this can be any string value but in this instance, we will declare it as “savedText”) and the userText object as arguments:
outState.putCharSequence("savedText", userText);
Bringing this all together gives us a modified onSaveInstanceState() method in the StateChangeActivity.java file that reads as follows (noting also the additional import directive for android.widget.EditText):
package com.ebookfrenzy.statechange; import android.support.v7.app.ActionBarActivity; import android.os.Bundle; import android.util.Log; import android.view.Menu; import android.view.MenuItem; import android.widget.EditText; public class StateChangeActivity extends ActionBarActivity { . . . protected void onSaveInstanceState(Bundle outState) { super.onSaveInstanceState(outState); Log.i(TAG, "onSaveInstanceState"); final EditText textBox = (EditText) findViewById(R.id.editText); CharSequence userText = textBox.getText(); outState.putCharSequence("savedText", userText); } . . .
Now that steps have been taken to save the state, the next phase is to ensure that it is restored when needed.
Restoring the State
The saved dynamic state can be restored in those lifecycle methods that are passed the Bundle object as an argument. This leaves the developer with the choice of using either onCreate() or onRestoreInstanceState(). The method to use will depend on the nature of the activity. In instances where state is best restored after the activity’s initialization tasks have been performed, the onRestoreInstanceState() method is generally more suitable. For the purposes of this example we will add code to the onRestoreInstanceState() method to extract the saved state from the Bundle using the “savedText” key. We can then display the text on the EditText component using the object’s setText() method:
@Override protected void onRestoreInstanceState(Bundle savedInstanceState) { super.onRestoreInstanceState(savedInstanceState); Log.i(TAG, "onRestoreInstanceState"); final EditText textBox = (EditText) findViewById(R.id.editText); CharSequence userText = savedInstanceState.getCharSequence("savedText"); textBox.setText(userText); }
Testing the Application
All that remains is once again to build and run the StateChange application. Once running and in the foreground, touch the EditText component and enter some text before rotating the device to another orientation. Whereas the text changes were previously lost, the new text is retained within the editText component thanks to the code we have added to the activity in this chapter.
Summary
The saving and restoration of dynamic state in an Android application is simply a matter of implementing the appropriate code in the appropriate lifecycle methods. For most user interface views, this is handled automatically by the Activity super class. In other instances, this typically consists of extracting values and settings within the onSaveInstanceState() method and saving the data as key-value pairs within the Bundle object passed through to the activity by the runtime system.
State can be restored in either the onCreate() or the onRestoreInstanceState() methods of the activity by extracting values from the Bundle object and updating the activity based on the stored values.
In this chapter, we have used these techniques to update the StateChange project so that the Activity retains changes through the destruction and subsequent recreation of an activity.
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Android Activity State Changes - An Android Studio Example | Understanding Android Views, View Groups and Layouts in Android Studio |