Difference between revisions of "Example Android Gradient"

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(Added Android preview example)
 
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* Camera Preview
* Camera Preview
* Image Gradient
* Image Gradient
Related Tutorial:
* [[Android_support| Android Support]]


Related Examples:
Related Examples:

Revision as of 17:03, 16 February 2013

Demonstration of to capture and process a video stream in real-time using BoofCV on an Android device. On Android video streams are accessed inside a camera preview, which require several hoops to be jumped through for it to work well. What this example does is capture the image in NV21 format, convert it into an ImageUInt8, compute the image gradient, visualize the gradient in a Bitmap image, and display the results. Note that the example below is not entirely self contained, see the complete project for additional files.

Example File: VideoActivity.java

Complete Project: Android Project

Concepts:

  • Android
  • Camera Preview
  • Image Gradient

Related Tutorial:

Related Examples:

Example Code

/**
 * Demonstration of how to process a video stream on an Android device using BoofCV.  Most of the code below
 * is deals with handling Android and all of its quirks.  Video streams can be accessed in Android by processing
 * a camera preview.  Data from a camera preview comes in an NV21 image format, which needs to be converted.
 * After it has been converted it needs to be processed and then displayed.  Note that several locks are required
 * to avoid the three threads (GUI, camera preview, and processing) from interfering with each other.
 *
 * @author Peter Abeles
 */
public class VideoActivity extends Activity implements Camera.PreviewCallback {

	// camera and display objects
	private Camera mCamera;
	private Visualization mDraw;
	private CameraPreview mPreview;

	// computes the image gradient
	private ImageGradient<ImageUInt8,ImageSInt16> gradient = FactoryDerivative.three(ImageUInt8.class, ImageSInt16.class);

	// Two images are needed to store the converted preview image to prevent a thread conflict from occurring
	private ImageUInt8 gray1,gray2;
	private ImageSInt16 derivX,derivY;

	// Android image data used for displaying the results
	private Bitmap output;
	// temporary storage that's needed when converting from BoofCV to Android image data types
	private byte[] storage;

	// Thread where image data is processed
	private ThreadProcess thread;

	// Object used for synchronizing gray images
	private final Object lockGray = new Object();
	// Object used for synchronizing output image
	private final Object lockOutput = new Object();

	@Override
	public void onCreate(Bundle savedInstanceState) {
		super.onCreate(savedInstanceState);

		requestWindowFeature(Window.FEATURE_NO_TITLE);
		setContentView(R.layout.video);

		// Used to visualize the results
		mDraw = new Visualization(this);

		// Create our Preview view and set it as the content of our activity.
		mPreview = new CameraPreview(this,this,true);

		FrameLayout preview = (FrameLayout) findViewById(R.id.camera_preview);

		preview.addView(mPreview);
		preview.addView(mDraw);
	}

	@Override
	protected void onResume() {
		super.onResume();

		if( mCamera != null )
			throw new RuntimeException("Bug, camera should not be initialized already");

		setUpAndConfigureCamera();
	}

	@Override
	protected void onPause() {
		super.onPause();

		// stop the camera preview and all processing
		if (mCamera != null){
			mPreview.setCamera(null);
			mCamera.setPreviewCallback(null);
			mCamera.stopPreview();
			mCamera.release();
			mCamera = null;

			thread.stopThread();
			thread = null;
		}
	}

	/**
	 * Sets up the camera if it is not already setup.
	 */
	private void setUpAndConfigureCamera() {
		// Open and configure the camera
		mCamera = Camera.open();

		Camera.Parameters param = mCamera.getParameters();

		// Select the preview size closest to 320x240
		// Smaller images are recommended because some computer vision operations are very expensive
		List<Camera.Size> sizes = param.getSupportedPreviewSizes();
		Camera.Size s = sizes.get(closest(sizes,320,240));
		param.setPreviewSize(s.width,s.height);
		mCamera.setParameters(param);

		// declare image data
		gray1 = new ImageUInt8(s.width,s.height);
		gray2 = new ImageUInt8(s.width,s.height);
		derivX = new ImageSInt16(s.width,s.height);
		derivY = new ImageSInt16(s.width,s.height);
		output = Bitmap.createBitmap(s.width,s.height,Bitmap.Config.ARGB_8888 );
		storage = ConvertBitmap.declareStorage(output, storage);

		// start image processing thread
		thread = new ThreadProcess();
		thread.start();

		// Create an instance of Camera
		mPreview.setCamera(mCamera);
	}

	/**
	 * Goes through the size list and selects the one which is the closest specified size
	 */
	public static int closest( List<Camera.Size> sizes , int width , int height ) {
		int best = -1;
		int bestScore = Integer.MAX_VALUE;

		for( int i = 0; i < sizes.size(); i++ ) {
			Camera.Size s = sizes.get(i);

			int dx = s.width-width;
			int dy = s.height-height;

			int score = dx*dx + dy*dy;
			if( score < bestScore ) {
				best = i;
				bestScore = score;
			}
		}

		return best;
	}

	/**
	 * Called each time a new image arrives in the data stream.
	 */
	@Override
	public void onPreviewFrame(byte[] bytes, Camera camera) {

		// convert from NV21 format into gray scale
		synchronized (lockGray) {
			ConvertNV21.nv21ToGray(bytes,gray1.width,gray1.height,gray1);
		}

		// Can only do trivial amounts of image processing inside this function or else bad stuff happens.
		// To work around this issue most of the processing has been pushed onto a thread and the call below
		// tells the thread to wake up and process another image
		thread.interrupt();
	}

	/**
	 * Draws on top of the video stream for visualizing computer vision results
	 */
	private class Visualization extends SurfaceView {

		Activity activity;

		public Visualization(Activity context ) {
			super(context);
			this.activity = context;

			// This call is necessary, or else the
			// draw method will not be called.
			setWillNotDraw(false);
		}

		@Override
		protected void onDraw(Canvas canvas){

			synchronized ( lockOutput ) {
				int w = canvas.getWidth();
				int h = canvas.getHeight();

				// fill the window and center it
				double scaleX = w/(double)output.getWidth();
				double scaleY = h/(double)output.getHeight();

				double scale = Math.min(scaleX,scaleY);
				double tranX = (w-scale*output.getWidth())/2;
				double tranY = (h-scale*output.getHeight())/2;

				canvas.translate((float)tranX,(float)tranY);
				canvas.scale((float)scale,(float)scale);

				// draw the image
				canvas.drawBitmap(output,0,0,null);
			}
		}
	}

	/**
	 * External thread used to do more time consuming image processing
	 */
	private class ThreadProcess extends Thread {

		// true if a request has been made to stop the thread
		volatile boolean stopRequested = false;
		// true if the thread is running and can process more data
		volatile boolean running = true;

		/**
		 * Blocks until the thread has stopped
		 */
		public void stopThread() {
			stopRequested = true;
			while( running ) {
				thread.interrupt();
				Thread.yield();
			}
		}

		@Override
		public void run() {

			while( !stopRequested ) {

				// Sleep until it has been told to wake up
				synchronized ( Thread.currentThread() ) {
					try {
						wait();
					} catch (InterruptedException ignored) {}
				}

				// process the most recently converted image by swapping image buffered
				synchronized (lockGray) {
					ImageUInt8 tmp = gray1;
					gray1 = gray2;
					gray2 = tmp;
				}

				// process the image and compute its gradient
				gradient.process(gray2,derivX,derivY);

				// render the output in a synthetic color image
				synchronized ( lockOutput ) {
					VisualizeImageData.colorizeGradient(derivX,derivY,-1,output,storage);
				}
				mDraw.postInvalidate();
			}
			running = false;
		}
	}
}