The issue has been fixed starting from API level 11. Now there exists an interface: DatabaseErrorHandler which you can implement to define your own onCorruption() method. At the opening of your database you can pass this DatabaseErrorHandler as a parameter to the constructor of SQLiteOpenHelper.
e.g.
public class MyDbErrorHandler implements DatabaseErrorHandler {
@Override
onCorruption(SQLiteDatabase db) {
// Back up the db or do some other stuff
}
}
SQLiteOpenHelper dbHelper = new SQLiteOpenHelper(context, "MyDbName", null, 1,
new MyDbErrorHandler());
SQLiteDatabase db = dbHelper.getWritableDatabase();
For Systems with an API level below 11 and for those who dont want to use this approach there are several alternatives.
1. Android data backup
Android offers a backup service which automatically copys the application data to a remote 'cloud' storage. If a database gets corrupted or the application is reinstalled after factory reset. The application data can be restored from the remote data.
For further information see: http://developer.android.com/guide/topics/data/backup.html
2. JDBC (sqldroid)
One approach could be implementing your own database connector, either native JDBC or with the sqldroid library. It is officially not supported by google and you cannot be sure whether it will be still available in future Android versions.
3. Berkley DB Java Edition
An interesting approach, also with a look to performance handling large data amounts, is the Berkley DB Java Edition.
Here is a tutorial how to use it in Android: http://download.oracle.com/docs/cd/E17277_02/html/HOWTO-Android.html
4. Customizing the android libraries
Another more risky approach is to implement your own database class by copying or extending the SQLiteDatabase.java from the android source and reimplement or override the critical parts which are:
public static SQLiteDatabase openDatabase(String path, CursorFactory factory, int flags) {
SQLiteDatabase sqliteDatabase = null;
try {
// Open the database.
sqliteDatabase = new SQLiteDatabase(path, factory, flags);
if (SQLiteDebug.DEBUG_SQL_STATEMENTS) {
sqliteDatabase.enableSqlTracing(path);
}
if (SQLiteDebug.DEBUG_SQL_TIME) {
sqliteDatabase.enableSqlProfiling(path);
}
} catch (SQLiteDatabaseCorruptException e) {
// Try to recover from this, if we can.
// TODO: should we do this for other open failures?
Log.e(TAG, "Deleting and re-creating corrupt database " + path, e);
EventLog.writeEvent(EVENT_DB_CORRUPT, path);
if (!path.equalsIgnoreCase(":memory")) {
// delete is only for non-memory database files
new File(path).delete();
}
sqliteDatabase = new SQLiteDatabase(path, factory, flags);
}
ActiveDatabases.getInstance().mActiveDatabases.add(
new WeakReference<SQLiteDatabase>(sqliteDatabase));
return sqliteDatabase;
}
and:
/* package */ void onCorruption() {
Log.e(TAG, "Removing corrupt database: " + mPath);
EventLog.writeEvent(EVENT_DB_CORRUPT, mPath);
try {
// Close the database (if we can), which will cause subsequent operations to fail.
close();
} finally {
// Delete the corrupt file. Don't re-create it now -- that would just confuse people
// -- but the next time someone tries to open it, they can set it up from scratch.
if (!mPath.equalsIgnoreCase(":memory")) {
// delete is only for non-memory database files
new File(mPath).delete();
}
}
}
The dangerous part about that is, that you also would have to reimplement the helper classes that access the SQLiteDatabase such as SQLiteOpenHelper
. Since the SQLiteDatabase
class uses factory methods you could face unexpected side effects.