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DisplayingBitmaps.zip
This lesson brings together everything from previous lessons, showing you how to load multiple
bitmaps into
ViewPager
and
GridView
components using a background thread and bitmap cache, while dealing with concurrency and
configuration changes.
Load Bitmaps into a ViewPager Implementation
The
swipe view pattern
is an excellent
way to navigate the detail view of an image gallery. You can implement this pattern using a
ViewPager
component backed by a
PagerAdapter
. However, a more suitable backing adapter is the subclass
FragmentStatePagerAdapter
which automatically destroys and saves
state of the
Fragments
in the
ViewPager
as they disappear off-screen, keeping memory usage down.
Note:
If you have a smaller number of images and are confident they
all fit within the application memory limit, then using a regular
PagerAdapter
or
FragmentPagerAdapter
might
be more appropriate.
Here’s an implementation of a
ViewPager
with
ImageView
children. The main activity holds the
ViewPager
and the adapter:
public class ImageDetailActivity extends FragmentActivity { public static final String EXTRA_IMAGE = "extra_image"; private ImagePagerAdapter mAdapter; private ViewPager mPager; // A static dataset to back the ViewPager adapter public final static Integer[] imageResIds = new Integer[] { R.drawable.sample_image_1, R.drawable.sample_image_2, R.drawable.sample_image_3, R.drawable.sample_image_4, R.drawable.sample_image_5, R.drawable.sample_image_6, R.drawable.sample_image_7, R.drawable.sample_image_8, R.drawable.sample_image_9}; @Override public void onCreate(Bundle savedInstanceState) { super.onCreate(savedInstanceState); setContentView(R.layout.image_detail_pager); // Contains just a ViewPager mAdapter = new ImagePagerAdapter(getSupportFragmentManager(), imageResIds.length); mPager = (ViewPager) findViewById(R.id.pager); mPager.setAdapter(mAdapter); } public static class ImagePagerAdapter extends FragmentStatePagerAdapter { private final int mSize; public ImagePagerAdapter(FragmentManager fm, int size) { super(fm); mSize = size; } @Override public int getCount() { return mSize; } @Override public Fragment getItem(int position) { return ImageDetailFragment.newInstance(position); } } }
Here is an implementation of the details
Fragment
which holds the
ImageView
children. This might seem like a perfectly reasonable approach, but can
you see the drawbacks of this implementation? How could it be improved?
public class ImageDetailFragment extends Fragment { private static final String IMAGE_DATA_EXTRA = "resId"; private int mImageNum; private ImageView mImageView; static ImageDetailFragment newInstance(int imageNum) { final ImageDetailFragment f = new ImageDetailFragment(); final Bundle args = new Bundle(); args.putInt(IMAGE_DATA_EXTRA, imageNum); f.setArguments(args); return f; } // Empty constructor, required as per Fragment docs public ImageDetailFragment() {} @Override public void onCreate(Bundle savedInstanceState) { super.onCreate(savedInstanceState); mImageNum = getArguments() != null ? getArguments().getInt(IMAGE_DATA_EXTRA) : -1; } @Override public View onCreateView(LayoutInflater inflater, ViewGroup container, Bundle savedInstanceState) { // image_detail_fragment.xml contains just an ImageView final View v = inflater.inflate(R.layout.image_detail_fragment, container, false); mImageView = (ImageView) v.findViewById(R.id.imageView); return v; } @Override public void onActivityCreated(Bundle savedInstanceState) { super.onActivityCreated(savedInstanceState); final int resId = ImageDetailActivity.imageResIds[mImageNum]; mImageView.setImageResource(resId); // Load image into ImageView } }
Hopefully you noticed the issue: the images are being read from resources on the UI thread,
which can lead to an application hanging and being force closed. Using an
AsyncTask
as described in the
Processing Bitmaps
Off the UI Thread
lesson, it’s straightforward to move image loading and processing to a
background thread:
public class ImageDetailActivity extends FragmentActivity {
...
public void loadBitmap(int resId, ImageView imageView) {
mImageView.setImageResource(R.drawable.image_placeholder);
BitmapWorkerTask task = new BitmapWorkerTask(mImageView);
task.execute(resId);
}
... // include
BitmapWorkerTask
class
}
public class ImageDetailFragment extends Fragment {
...
@Override
public void onActivityCreated(Bundle savedInstanceState) {
super.onActivityCreated(savedInstanceState);
if (ImageDetailActivity.class.isInstance(getActivity())) {
final int resId = ImageDetailActivity.imageResIds[mImageNum];
// Call out to ImageDetailActivity to load the bitmap in a background thread
((ImageDetailActivity) getActivity()).loadBitmap(resId, mImageView);
}
}
}
Any additional processing (such as resizing or fetching images from the network) can take place
in the
BitmapWorkerTask
without affecting
responsiveness of the main UI. If the background thread is doing more than just loading an image
directly from disk, it can also be beneficial to add a memory and/or disk cache as described in the
lesson
Caching Bitmaps
. Here's the additional
modifications for a memory cache:
public class ImageDetailActivity extends FragmentActivity { ... private LruCache<String, Bitmap> mMemoryCache; @Override public void onCreate(Bundle savedInstanceState) { ... // initialize LruCache as per Use a Memory Cache section } public void loadBitmap(int resId, ImageView imageView) { final String imageKey = String.valueOf(resId); final Bitmap bitmap = mMemoryCache.get(imageKey); if (bitmap != null) { mImageView.setImageBitmap(bitmap); } else { mImageView.setImageResource(R.drawable.image_placeholder); BitmapWorkerTask task = new BitmapWorkerTask(mImageView); task.execute(resId); } } ... // include updated BitmapWorkerTask from Use a Memory Cache section }
Putting all these pieces together gives you a responsive
ViewPager
implementation with minimal image loading latency and the ability
to do as much or as little background processing on your images as needed.
Load Bitmaps into a GridView Implementation
The
grid list building block
is
useful for showing image data sets and can be implemented using a
GridView
component in which many images can be on-screen at any one time and many more need to be ready to
appear if the user scrolls up or down. When implementing this type of control, you must ensure the
UI remains fluid, memory usage remains under control and concurrency is handled correctly (due to
the way
GridView
recycles its children views).
To start with, here is a standard
GridView
implementation with
ImageView
children placed inside a
Fragment
. Again, this might
seem like a perfectly reasonable approach, but what would make it better?
public class ImageGridFragment extends Fragment implements AdapterView.OnItemClickListener { private ImageAdapter mAdapter; // A static dataset to back the GridView adapter public final static Integer[] imageResIds = new Integer[] { R.drawable.sample_image_1, R.drawable.sample_image_2, R.drawable.sample_image_3, R.drawable.sample_image_4, R.drawable.sample_image_5, R.drawable.sample_image_6, R.drawable.sample_image_7, R.drawable.sample_image_8, R.drawable.sample_image_9}; // Empty constructor as per Fragment docs public ImageGridFragment() {} @Override public void onCreate(Bundle savedInstanceState) { super.onCreate(savedInstanceState); mAdapter = new ImageAdapter(getActivity()); } @Override public View onCreateView( LayoutInflater inflater, ViewGroup container, Bundle savedInstanceState) { final View v = inflater.inflate(R.layout.image_grid_fragment, container, false); final GridView mGridView = (GridView) v.findViewById(R.id.gridView); mGridView.setAdapter(mAdapter); mGridView.setOnItemClickListener(this); return v; } @Override public void onItemClick(AdapterView<?> parent, View v, int position, long id) { final Intent i = new Intent(getActivity(), ImageDetailActivity.class); i.putExtra(ImageDetailActivity.EXTRA_IMAGE, position); startActivity(i); } private class ImageAdapter extends BaseAdapter { private final Context mContext; public ImageAdapter(Context context) { super(); mContext = context; } @Override public int getCount() { return imageResIds.length; } @Override public Object getItem(int position) { return imageResIds[position]; } @Override public long getItemId(int position) { return position; } @Override public View getView(int position, View convertView, ViewGroup container) { ImageView imageView; if (convertView == null) { // if it's not recycled, initialize some attributes imageView = new ImageView(mContext); imageView.setScaleType(ImageView.ScaleType.CENTER_CROP); imageView.setLayoutParams(new GridView.LayoutParams( LayoutParams.MATCH_PARENT, LayoutParams.MATCH_PARENT)); } else { imageView = (ImageView) convertView; } imageView.setImageResource(imageResIds[position]); // Load image into ImageView return imageView; } } }
Once again, the problem with this implementation is that the image is being set in the UI thread. While this may work for small, simple images (due to system resource loading and caching), if any additional processing needs to be done, your UI grinds to a halt.
The same asynchronous processing and caching methods from the previous section can be implemented
here. However, you also need to wary of concurrency issues as the
GridView
recycles its children views. To handle this, use the techniques discussed in the
Processing Bitmaps Off the UI Thread
lesson. Here is the
updated
solution:
public class ImageGridFragment extends Fragment implements AdapterView.OnItemClickListener {
...
private class ImageAdapter extends BaseAdapter {
...
@Override
public View getView(int position, View convertView, ViewGroup container) {
...
loadBitmap(imageResIds[position], imageView)
return imageView;
}
}
public void loadBitmap(int resId, ImageView imageView) {
if (cancelPotentialWork(resId, imageView)) {
final BitmapWorkerTask task = new BitmapWorkerTask(imageView);
final AsyncDrawable asyncDrawable =
new AsyncDrawable(getResources(), mPlaceHolderBitmap, task);
imageView.setImageDrawable(asyncDrawable);
task.execute(resId);
}
}
static class AsyncDrawable extends BitmapDrawable {
private final WeakReference<BitmapWorkerTask> bitmapWorkerTaskReference;
public AsyncDrawable(Resources res, Bitmap bitmap,
BitmapWorkerTask bitmapWorkerTask) {
super(res, bitmap);
bitmapWorkerTaskReference =
new WeakReference<BitmapWorkerTask>(bitmapWorkerTask);
}
public BitmapWorkerTask getBitmapWorkerTask() {
return bitmapWorkerTaskReference.get();
}
}
public static boolean cancelPotentialWork(int data, ImageView imageView) {
final BitmapWorkerTask bitmapWorkerTask = getBitmapWorkerTask(imageView);
if (bitmapWorkerTask != null) {
final int bitmapData = bitmapWorkerTask.data;
if (bitmapData != data) {
// Cancel previous task
bitmapWorkerTask.cancel(true);
} else {
// The same work is already in progress
return false;
}
}
// No task associated with the ImageView, or an existing task was cancelled
return true;
}
private static BitmapWorkerTask getBitmapWorkerTask(ImageView imageView) {
if (imageView != null) {
final Drawable drawable = imageView.getDrawable();
if (drawable instanceof AsyncDrawable) {
final AsyncDrawable asyncDrawable = (AsyncDrawable) drawable;
return asyncDrawable.getBitmapWorkerTask();
}
}
return null;
}
... // include updated
BitmapWorkerTask
class
Note:
The same code can easily be adapted to work with
ListView
as well.
This implementation allows for flexibility in how the images are processed and loaded without impeding the smoothness of the UI. In the background task you can load images from the network or resize large digital camera photos and the images appear as the tasks finish processing.
For a full example of this and other concepts discussed in this lesson, please see the included sample application.