/**
 * After interest points have been detected in two images the next step is to associate the two
 * sets of images so that the relationship can be found. This is done by computing descriptors for
 * each detected feature and associating them together. In the code below abstracted interfaces are
 * used to allow different algorithms to be easily used. The cost of this abstraction is that detector/descriptor
 * specific information is thrown away, potentially slowing down or degrading performance.
 *
 * @author Peter Abeles
 */
public class ExampleAssociatePoints<T extends ImageGray<T>, TD extends TupleDesc<TD>> {

	// algorithm used to detect and describe interest points
	DetectDescribePoint<T, TD> detDesc;
	// Associated descriptions together by minimizing an error metric
	AssociateDescription<TD> associate;

	// location of interest points
	public List<Point2D_F64> pointsA;
	public List<Point2D_F64> pointsB;

	Class<T> imageType;

	public ExampleAssociatePoints( DetectDescribePoint<T, TD> detDesc,
								   AssociateDescription<TD> associate,
								   Class<T> imageType ) {
		this.detDesc = detDesc;
		this.associate = associate;
		this.imageType = imageType;
	}

	/**
	 * Detect and associate point features in the two images. Display the results.
	 */
	public void associate( BufferedImage imageA, BufferedImage imageB ) {
		T inputA = ConvertBufferedImage.convertFromSingle(imageA, null, imageType);
		T inputB = ConvertBufferedImage.convertFromSingle(imageB, null, imageType);

		// stores the location of detected interest points
		pointsA = new ArrayList<>();
		pointsB = new ArrayList<>();

		// stores the description of detected interest points
		DogArray<TD> descA = UtilFeature.createArray(detDesc, 100);
		DogArray<TD> descB = UtilFeature.createArray(detDesc, 100);

		// describe each image using interest points
		describeImage(inputA, pointsA, descA);
		describeImage(inputB, pointsB, descB);

		// Associate features between the two images
		associate.setSource(descA);
		associate.setDestination(descB);
		associate.associate();

		// display the results
		AssociationPanel panel = new AssociationPanel(20);
		panel.setAssociation(pointsA, pointsB, associate.getMatches());
		panel.setImages(imageA, imageB);

		ShowImages.showWindow(panel, "Associated Features", true);
	}

	/**
	 * Detects features inside the two images and computes descriptions at those points.
	 */
	private void describeImage( T input, List<Point2D_F64> points, DogArray<TD> descs ) {
		detDesc.detect(input);

		for (int i = 0; i < detDesc.getNumberOfFeatures(); i++) {
			points.add(detDesc.getLocation(i).copy());
			descs.grow().setTo(detDesc.getDescription(i));
		}
	}

	public static void main( String[] args ) {

		Class imageType = GrayF32.class;
//		Class imageType = GrayU8.class;

		// select which algorithms to use
		DetectDescribePoint detDesc = FactoryDetectDescribe.
				surfStable(new ConfigFastHessian(1, 2, 300, 1, 9, 4, 4), null, null, imageType);
//				sift(new ConfigCompleteSift(0,5,600));

		ScoreAssociation scorer = FactoryAssociation.defaultScore(detDesc.getDescriptionType());
		AssociateDescription associate = FactoryAssociation.greedy(new ConfigAssociateGreedy(true), scorer);

		// load and match images
		ExampleAssociatePoints app = new ExampleAssociatePoints(detDesc, associate, imageType);

		BufferedImage imageA = UtilImageIO.loadImageNotNull(UtilIO.pathExample("stitch/kayak_01.jpg"));
		BufferedImage imageB = UtilImageIO.loadImageNotNull(UtilIO.pathExample("stitch/kayak_03.jpg"));

		app.associate(imageA, imageB);
	}
}