/** * @param inputImg * @return Mat */ public static Mat watershed(Mat inputImg) { Mat target = new Mat(inputImg.rows(), inputImg.cols(), CvType.CV_8UC3); Imgproc.cvtColor(inputImg, target, Imgproc.COLOR_BGR2RGB); // Conversion to 8UC1 grayscale image Mat grayScale = new Mat(inputImg.rows(), inputImg.cols(), CvType.CV_32SC1); Imgproc.cvtColor(inputImg, grayScale, Imgproc.COLOR_BGR2GRAY); // constructing a 3x3 kernel for morphological opening Mat openingKernel = Mat.ones(9, 9, CvType.CV_8U); // яскравість // target.convertTo(target, -1, 10d * 12 / 100, 0); // Imgproc.dilate(target, target, new Mat(), new Point(-1, -1), 1); Size s = new Size(27, 27); Imgproc.GaussianBlur(target, target, s, 1.7); Imgproc.morphologyEx(target, target, Imgproc.MORPH_OPEN, openingKernel); // dilation operation for extracting the background // Imgproc.dilate(target, target, openingKernel); // Imgproc.erode(target, target, new Mat(), new Point(-1, -1), 1); Mat seeds = new Mat(target.rows(), target.cols(), CvType.CV_32SC1); for (int i = 0; i < 10; i++) { seeds.put(((int) Math.random()) % target.rows(), ((int) Math.random()) % target.cols(), i); } Imgproc.watershed(target, seeds); // Imgproc.threshold(target,target, 50, 155, Imgproc.THRESH_BINARY ); return target; }
private Mat rotateImage(Mat src, double angle) { Point center = new Point(src.cols() / 2, src.rows() / 2); double scale = 1.0; Mat rotateMat = Imgproc.getRotationMatrix2D(center, angle, scale); Mat dst = new Mat(); Size frameSize = new Size(src.rows(), src.cols()); // adjust dst center point double m[] = new double[6]; rotateMat.get(0, 0, m); m[2] += (frameSize.width - src.cols()) / 2; m[5] += (frameSize.height - src.rows()) / 2; rotateMat.put(0, 0, m); Imgproc.warpAffine( src, dst, rotateMat, frameSize, Imgproc.INTER_LINEAR, Imgproc.BORDER_CONSTANT, Scalar.all(0)); return dst; }
public static boolean checkAngleL(Mat binary) { int leftPointX = -1; double pixel[]; for (int i = 0; i < binary.cols(); i++) { pixel = binary.get(0, i); if (pixel[0] != 0.0) { leftPointX = i; } } int rightPointY = -1; for (int i = 0; i < binary.rows(); i++) { pixel = binary.get(i, binary.cols() - 1); if (pixel[0] != 0.0) { rightPointY = i; break; } } double opposite = rightPointY; double adjacent = binary.cols() - 1 - leftPointX; double angle = Math.atan2(opposite, adjacent) * (180 / Math.PI); if (angle >= 50.0 & angle < 70.0) { return true; // angle indicates L } else { return false; // angle indicates not L } }
public static void main(String[] args) { try { System.loadLibrary(Core.NATIVE_LIBRARY_NAME); File input = new File("traffic_signal.jpg"); BufferedImage image = ImageIO.read(input); byte[] data = ((DataBufferByte) image.getRaster().getDataBuffer()).getData(); Mat mat = new Mat(image.getHeight(), image.getWidth(), CvType.CV_8UC3); mat.put(0, 0, data); Mat mat1 = new Mat(image.getHeight(), image.getWidth(), CvType.CV_8UC1); Imgproc.cvtColor(mat, mat1, Imgproc.COLOR_RGB2GRAY); byte[] data1 = new byte[mat1.rows() * mat1.cols() * (int) (mat1.elemSize())]; mat1.get(0, 0, data1); BufferedImage image1 = new BufferedImage(mat1.cols(), mat1.rows(), BufferedImage.TYPE_BYTE_GRAY); image1.getRaster().setDataElements(0, 0, mat1.cols(), mat1.rows(), data1); File ouptut = new File("output\\grayscale_" + new Date().getTime() + ".jpg"); ImageIO.write(image1, "jpg", ouptut); } catch (Exception e) { System.out.println("Error: " + e.getMessage()); } }
/** * Rotate a Mat by the specified degree * * @param src The source Mat * @param angle The angle by which to rotate by * @return The rotated Mat */ public static Mat rotate(Mat src, double angle) { int len = src.cols() > src.rows() ? src.cols() : src.rows(); Point pt = new Point(len / 2.0, len / 2.0); Mat r = Imgproc.getRotationMatrix2D(pt, angle, 1.0); Mat dst = new Mat(); Imgproc.warpAffine(src, dst, r, new Size(len, len)); return dst; }
public static Image convertMatToImage(Mat m) { int type = BufferedImage.TYPE_BYTE_GRAY; if (m.channels() > 1) { type = BufferedImage.TYPE_3BYTE_BGR; } int bufferSize = m.channels() * m.cols() * m.rows(); byte[] b = new byte[bufferSize]; m.get(0, 0, b); BufferedImage image = new BufferedImage(m.cols(), m.rows(), type); final byte[] targetPixels = ((DataBufferByte) image.getRaster().getDataBuffer()).getData(); System.arraycopy(b, 0, targetPixels, 0, b.length); return image; }
public SaliencyResult saliencyalgorithmInterface(ImageObj imgobj, String method) { // TODO Auto-generated method stub float min = Float.MAX_VALUE; float max = Float.MIN_VALUE; String imgpath = imgobj.getSourcePath(); int k_num = imgobj.getK_num(); SaliencyResult result = new SaliencyResult(); Mat img = Highgui.imread(imgpath, Highgui.CV_LOAD_IMAGE_GRAYSCALE); Mat saliencyMap = new Mat(); saliencyMap.create(img.rows(), img.cols(), CvType.CV_16U); int HistGram[] = new int[256]; int Gray[] = new int[img.cols() * img.rows()]; int Dist[] = new int[256]; float DistMap[] = new float[img.rows() * img.cols()]; for (int row = 0; row < img.rows(); row++) { int CurIndex = row * img.cols(); for (int col = 0; col < img.cols(); col++) { HistGram[(int) (img.get(row, col)[0])]++; Gray[CurIndex] = (int) (img.get(row, col)[0]); CurIndex++; } } for (int Y = 0; Y < 256; Y++) { int Value = 0; for (int X = 0; X < 256; X++) Value += Math.abs(Y - X) * HistGram[X]; Dist[Y] = Value; } for (int row = 0; row < img.rows(); row++) { int CurIndex = row * img.cols(); for (int col = 0; col < img.cols(); col++) { DistMap[CurIndex] = Dist[Gray[CurIndex]]; if (DistMap[CurIndex] < min) min = DistMap[CurIndex]; if (DistMap[CurIndex] > max) max = DistMap[CurIndex]; CurIndex++; } } for (int row = 0; row < img.rows(); row++) { int CurIndex = row * img.cols(); for (int col = 0; col < img.cols(); col++) { saliencyMap.put(row, col, partTwo((DistMap[CurIndex] - min) / (max - min) * 255)); CurIndex++; } } new findMarkUtil(); int nums[] = null; if (method == "kmeans") { nums = findMarkUtil.findMarkUtil_kmeans(saliencyMap, k_num, 255, 0, 5); } else if (method == "random") { nums = findMarkUtil.findMarkUtil_random(saliencyMap, k_num, 255); } result.setK_num(k_num); result.setSource(imgpath); result.setResult(nums); result.setSaliency(saliencyMap); return result; }
/** Capture images and run color processing through here */ public void capture() { VideoCapture camera = new VideoCapture(); camera.set(12, -20); // change contrast, might not be necessary // CaptureImage image = new CaptureImage(); camera.open(0); // Useless if (!camera.isOpened()) { System.out.println("Camera Error"); // Determine whether to use System.exit(0) or return } else { System.out.println("Camera OK"); } boolean success = camera.read(capturedFrame); if (success) { try { processWithContours(capturedFrame, processedFrame); } catch (Exception e) { System.out.println(e); } // image.processFrame(capturedFrame, processedFrame); // processedFrame should be CV_8UC3 // image.findCaptured(processedFrame); // image.determineKings(capturedFrame); int bufferSize = processedFrame.channels() * processedFrame.cols() * processedFrame.rows(); byte[] b = new byte[bufferSize]; processedFrame.get(0, 0, b); // get all the pixels // This might need to be BufferedImage.TYPE_INT_ARGB img = new BufferedImage( processedFrame.cols(), processedFrame.rows(), BufferedImage.TYPE_INT_RGB); int width = (int) camera.get(Highgui.CV_CAP_PROP_FRAME_WIDTH); int height = (int) camera.get(Highgui.CV_CAP_PROP_FRAME_HEIGHT); // img.getRaster().setDataElements(0, 0, width, height, b); byte[] a = new byte[bufferSize]; System.arraycopy(b, 0, a, 0, bufferSize); Highgui.imwrite("camera.jpg", processedFrame); System.out.println("Success"); } else System.out.println("Unable to capture image"); camera.release(); }
private double match_eye(Rect area, Mat mTemplate, int type) { Point matchLoc; Mat mROI = mGray.submat(area); int result_cols = mGray.cols() - mTemplate.cols() + 1; int result_rows = mGray.rows() - mTemplate.rows() + 1; if (mTemplate.cols() == 0 || mTemplate.rows() == 0) { return 0.0; } mResult = new Mat(result_cols, result_rows, CvType.CV_32FC1); switch (type) { case TM_SQDIFF: Imgproc.matchTemplate(mROI, mTemplate, mResult, Imgproc.TM_SQDIFF); break; case TM_SQDIFF_NORMED: Imgproc.matchTemplate(mROI, mTemplate, mResult, Imgproc.TM_SQDIFF_NORMED); break; case TM_CCOEFF: Imgproc.matchTemplate(mROI, mTemplate, mResult, Imgproc.TM_CCOEFF); break; case TM_CCOEFF_NORMED: Imgproc.matchTemplate(mROI, mTemplate, mResult, Imgproc.TM_CCOEFF_NORMED); break; case TM_CCORR: Imgproc.matchTemplate(mROI, mTemplate, mResult, Imgproc.TM_CCORR); break; case TM_CCORR_NORMED: Imgproc.matchTemplate(mROI, mTemplate, mResult, Imgproc.TM_CCORR_NORMED); break; } Core.MinMaxLocResult mmres = Core.minMaxLoc(mResult); if (type == TM_SQDIFF || type == TM_SQDIFF_NORMED) { matchLoc = mmres.minLoc; } else { matchLoc = mmres.maxLoc; } Point matchLoc_tx = new Point(matchLoc.x + area.x, matchLoc.y + area.y); Point matchLoc_ty = new Point(matchLoc.x + mTemplate.cols() + area.x, matchLoc.y + mTemplate.rows() + area.y); Core.rectangle(mRgba, matchLoc_tx, matchLoc_ty, new Scalar(255, 255, 0, 255)); if (type == TM_SQDIFF || type == TM_SQDIFF_NORMED) { return mmres.maxVal; } else { return mmres.minVal; } }
public void copyMat(Mat src, Mat dest) { int srcRows = src.rows(); int srcCols = src.cols(); int destRows = dest.rows(); int destCols = dest.cols(); for (int i = 0; i < srcRows; i++) { for (int j = 0; j < srcCols; j++) { double bit = src.get(i, j)[0]; dest.put(i, j, bit); System.out.println(bit); } } }
public void processFrame(CameraEvents.Frame frameEvent) { if (service.getActivityMode() != ActivityEvent.Mode.WARP) return; if (mode == Mode.SAMPLEWARPPLANE || mode == Mode.SAMPLEWARPGLASS) { synchronized (this) { if (!isSetup) setupMatrices(); if (captureSample) { captureSample = false; Log.d(TAG, "Warp: Capturing Sample"); Mat frame = frameEvent.getCameraFrame().getRGB(); byte[] frameJPEG = frameEvent.getCameraFrame().getJPEG(); if (sampleBGR == null || sampleBGR.height() != frame.height() || sampleBGR.width() != frame.width()) sampleBGR = new Mat(frame.rows(), frame.cols(), CvType.CV_8UC3); Imgproc.cvtColor(frame, sampleBGR, Imgproc.COLOR_RGB2BGR); useSample = true; // TODO: Specialize it for this group/device com.dappervision.wearscript.Utils.eventBusPost( new SendEvent("warpsample", "", ValueFactory.createRawValue(frameJPEG))); } } } if (busy) return; synchronized (this) { busy = true; if (!isSetup) setupMatrices(); if (mode == Mode.CAM2GLASS) { Mat inputBGR; Mat frame = frameEvent.getCameraFrame().getRGB(); if (frameBGR == null || frameBGR.height() != frame.height() || frameBGR.width() != frame.width()) frameBGR = new Mat(frame.rows(), frame.cols(), CvType.CV_8UC3); Mat hSmallToGlassMat = getHSmallToGlassMat(frame.rows(), frame.cols()); if (hSmallToGlassMat == null) { Log.w(TAG, "Warp: Bad size"); busy = false; return; } Imgproc.cvtColor(frame, frameBGR, Imgproc.COLOR_RGB2BGR); inputBGR = frameBGR; Imgproc.warpPerspective( inputBGR, frameWarp, hSmallToGlassMat, new Size(frameWarp.width(), frameWarp.height())); drawFrame(frameWarp); } busy = false; } }
/** * Order the detected bands into band 1, band 2 and the multiplier. The farthest band from the * center of the resistor Mat will always be band 1. * * <p>Band contours are created from top left to bottom right of the image. Therefore unless * resistor is perfectly horizontal, the middle band will always be 2nd, and the order just needs * to be flipped if necessary */ public void orderBands() { // Calculate the center of the resistor image. Point resistorImageCenter = new Point(resistorMat.cols() / 2, resistorMat.rows() / 2); double farthestDist = 0; int band1Idx = 0; // find the band farthest from the center. for (int i = 0; i < bands.size(); i++) { ColourBand cb = bands.get(i); double dist = euclidDist(resistorImageCenter, cb.center); if (dist > farthestDist) { farthestDist = dist; band1Idx = i; } } // assume bands are already in the correct order band1Idx == 0 orderedBands = bands; // if bands are in reverse order, reverse the array to get the ordered bands if (band1Idx == 2) { java.util.Collections.reverse(orderedBands); } }
/** * Helper function to convert a Mat into a BufferedImage. Taken from * http://answers.opencv.org/question/10344/opencv-java-load-image-to-gui Author: 'Lucky Luke' * * @param matrix Mat of type CV_8UC3 or CV_8UC1 * @return BufferedImage of type TYPE_3BYTE_BGR or TYPE_BYTE_GRAY */ private static BufferedImage matToBufferedImage(Mat matrix) { int cols = matrix.cols(); int rows = matrix.rows(); int elemSize = (int) matrix.elemSize(); byte[] data = new byte[cols * rows * elemSize]; int type; matrix.get(0, 0, data); switch (matrix.channels()) { case 1: type = BufferedImage.TYPE_BYTE_GRAY; break; case 3: type = BufferedImage.TYPE_3BYTE_BGR; // bgr to rgb byte b; for (int i = 0; i < data.length; i = i + 3) { b = data[i]; data[i] = data[i + 2]; data[i + 2] = b; } break; default: return null; } BufferedImage image = new BufferedImage(cols, rows, type); image.getRaster().setDataElements(0, 0, cols, rows, data); return image; }
private void displayMarkersDebug(Mat imgMat, Scalar contourColor, Scalar codesColor) { ArrayList<MatOfPoint> components = new ArrayList<MatOfPoint>(); Mat hierarchy = new Mat(); DtouchMarker marker = new DtouchMarker(); boolean markerFound = findMarkers(imgMat, marker, components, hierarchy); if (markerFound) { String code = codeArrayToString(marker.getCode()); Point codeLocation = new Point(imgMat.cols() / 4, imgMat.rows() / 8); Core.putText(mRgba, code, codeLocation, Core.FONT_HERSHEY_COMPLEX, 1, codesColor, 3); Imgproc.drawContours( mRgba, components, marker.getComponentIndex(), contourColor, 3, 8, hierarchy, 2, new Point(0, 0)); } if (components != null) components.clear(); if (hierarchy != null) hierarchy.release(); components = null; hierarchy = null; }
/** * Returns square area for image segment. * * @param imgMat Source image from which to compute image segment. * @return square area which contains image segment. */ private Rect calculateImageSegmentArea(Mat imgMat) { int width = imgMat.cols(); int height = imgMat.rows(); double aspectRatio = (double) width / (double) height; int imgWidth = width / 2; int imgHeight = height / 2; // Size of width and height varies of input image can vary. Make the image segment width and // height equal in order to make // the image segment square. // if width is more than the height. if (aspectRatio > 1) { // if total height is greater than imgWidth. if (height > imgWidth) imgHeight = imgWidth; } else if (aspectRatio < 1) { // height is more than the width. // if total width is greater than the imgHeight. if (width > imgHeight) imgWidth = imgHeight; } // find the centre position in the source image. int x = (width - imgWidth) / 2; int y = (height - imgHeight) / 2; return new Rect(x, y, imgWidth, imgHeight); }
public static void main(String[] args) { try { System.loadLibrary(Core.NATIVE_LIBRARY_NAME); Mat source = Imgcodecs.imread("test_image.jpg", 0); Mat destination = new Mat(source.rows(), source.cols(), source.type()); Imgproc.GaussianBlur(source, source, new Size(45, 45), 0); Imgproc.adaptiveThreshold( source, source, 255, Imgproc.ADAPTIVE_THRESH_MEAN_C, Imgproc.THRESH_BINARY, 75, 10); Core.bitwise_not(source, source); // Line detection Mat img2 = null; Imgproc.cvtColor(source, img2, Imgproc.COLOR_GRAY2RGB); Mat img3 = null; Imgproc.cvtColor(source, img3, Imgproc.COLOR_GRAY2RGB); MatOfInt4 lines = new MatOfInt4(); // Imgproc.HoughLines(img, lines, rho, theta, threshold); // Write to File Imgcodecs.imwrite("gaussian.jpg", source); System.out.println("Success!"); } catch (Exception e) { System.out.println("Error has occurred: " + e.getMessage()); } }
@Override public void OnKeypointsFoundForOther(Mat image) { Bitmap disp = Bitmap.createBitmap( image.cols(), image.rows(), Bitmap.Config.ARGB_8888); // Android uses ARGB_8888 Utils.matToBitmap(image, disp); mImageAdapter.setOtherKeyPointImage(disp); }
public static Mat findCardNumber(String path) { Mat mat = Highgui.imread(path); int x = 0; int y = (int) (mat.height() * ((double) 30 / 54)); int width = mat.cols(); int height = (int) (mat.height() * ((double) 7 / 54)); return mat.submat(new Rect(x, y, width, height)); }
private static void printMatI(Mat mat) { int[] data = new int[mat.channels()]; for (int r = 0; r < mat.rows(); r++) { for (int c = 0; c < mat.cols(); c++) { mat.get(r, c, data); log(lvl, "(%d, %d) %s", r, c, Arrays.toString(data)); } } }
public static BufferedImage bufferedImage(Mat m) { int type = BufferedImage.TYPE_BYTE_GRAY; if (m.channels() > 1) { type = BufferedImage.TYPE_3BYTE_BGR; } BufferedImage image = new BufferedImage(m.cols(), m.rows(), type); m.get( 0, 0, ((DataBufferByte) image.getRaster().getDataBuffer()).getData()); // get all the pixels return image; }
private void CreateAuxiliaryMats() { if (mGray.empty()) return; int rows = mGray.rows(); int cols = mGray.cols(); if (mZoomWindow == null) { mZoomWindow = mRgba.submat(rows / 2 + rows / 10, rows, cols / 2 + cols / 10, cols); mZoomWindow2 = mRgba.submat(0, rows / 2 - rows / 10, cols / 2 + cols / 10, cols); } }
private Mat buildROI(Mat src) { int offset = mZoomImg.getWidth(); int rows = src.rows(); int cols = src.cols(); Mat sub = src.submat( rows / 2 - offset / 2, rows / 2 + offset / 2, cols / 2 - offset / 2, cols / 2 + offset / 2); return sub; }
public void setSpherifiedImage(Bitmap bitmap) { spherifiedImage = new Mat(); spherifiedImage.create(bitmap.getHeight(), bitmap.getWidth(), CvType.CV_8UC3); Utils.bitmapToMat(bitmap, spherifiedImage); genImageSize = spherifiedImage.cols(); croppedImageSize = (int) (genImageSize * Math.sin(Math.PI / 4.0)); halfGenImageSize = genImageSize / 2; }
public static void draw_opticflow(Mat flow, Mat cflowmap, int step, Scalar color) { int i = 0, j = 0; for (int y = 0; y < cflowmap.rows(); y += step) { for (int x = 0; x < cflowmap.cols(); x += step) { double[] fxy = Sample1View.flow.get(50, 50); // for testing, getting change in values sa frames at point 50,50 // result : fxy ng.change ang value, however, kun i.add na ang 50, mura xag ma.zero?? i = (int) Math.round(fxy[0]); j = (int) (50.00 + fxy[1]); Core.putText( cflowmap, Double.toString(j), new Point(10, 100), 3 /* CV_FONT_HERSHEY_COMPLEX */, 2, new Scalar(255, 0, 0, 255), 3); // Core.line(cflowmap, new Point(x,y), new Point(i,j), new Scalar(0,0,255), 4); // Core.circle(cflowmap, new Point(i,j), 2, new Scalar(0,0,255), -1); // Core.circle(cflowmap, new Point(x,y), 2, color, -1); // System.out.print("fxy"+i+" "+j+"\n"); // Core.circle(cflowmap, new Point(cflowmap.width(), 50), 5, new Scalar(255,255,255), -1); if (i < (cflowmap.width() / 2) && i != 0.0) { Core.circle(cflowmap, new Point(i, j), 2, new Scalar(0, 0, 255), -1); Core.putText( cflowmap, "LEFT", new Point(10, 100), 3 /* CV_FONT_HERSHEY_COMPLEX */, 2, new Scalar(255, 255, 255, 255), 3); } else if (i > (cflowmap.width() / 2) && i != x) { Core.circle(cflowmap, new Point(i, j), 2, new Scalar(0, 0, 255), -1); Core.putText( cflowmap, "RIGHT", new Point(10, 100), 3 /* CV_FONT_HERSHEY_COMPLEX */, 2, new Scalar(255, 255, 255, 255), 3); } } } }
public Bitmap convertMatToBitmap(Mat seedsImage) { Bitmap bmp = null; Mat tmp = new Mat(seedsImage.height(), seedsImage.width(), CvType.CV_8U, new Scalar(4)); try { // Imgproc.cvtColor(seedsImage, tmp, Imgproc.COLOR_RGB2BGRA); Imgproc.cvtColor(seedsImage, tmp, Imgproc.COLOR_GRAY2RGBA, 4); bmp = Bitmap.createBitmap(tmp.cols(), tmp.rows(), Bitmap.Config.ARGB_8888); Utils.matToBitmap(tmp, bmp); } catch (CvException e) { Log.d("Exception", e.getMessage()); } return bmp; }
public void templateMatching() { System.loadLibrary(Core.NATIVE_LIBRARY_NAME); int match_method = 5; int max_Trackbar = 5; Mat data = Highgui.imread("images/training_data/1" + "/data (" + 1 + ").jpg"); Mat temp = Highgui.imread("images/template.jpg"); Mat img = data.clone(); int result_cols = img.cols() - temp.cols() + 1; int result_rows = img.rows() - temp.rows() + 1; Mat result = new Mat(result_rows, result_cols, CvType.CV_32FC1); Imgproc.matchTemplate(img, temp, result, match_method); Core.normalize(result, result, 0, 1, Core.NORM_MINMAX, -1, new Mat()); double minVal; double maxVal; Point minLoc; Point maxLoc; Point matchLoc; // minMaxLoc( result, &minVal, &maxVal, &minLoc, &maxLoc, Mat() ); Core.MinMaxLocResult res = Core.minMaxLoc(result); if (match_method == Imgproc.TM_SQDIFF || match_method == Imgproc.TM_SQDIFF_NORMED) { matchLoc = res.minLoc; } else { matchLoc = res.maxLoc; } // / Show me what you got Core.rectangle( img, matchLoc, new Point(matchLoc.x + temp.cols(), matchLoc.y + temp.rows()), new Scalar(0, 255, 0)); // Save the visualized detection. Highgui.imwrite("images/samp.jpg", img); }
public Mat onCameraFrame(CvCameraViewFrame inputFrame) { mRgba = inputFrame.rgba(); mGray = inputFrame.gray(); if (!detectionInProgress) { Mat image = new Mat(mGray.rows(), mGray.cols(), mGray.type()); mGray.copyTo(image); detectFaceOnFrame(image); } return mRgba; }
@Override public void OnHomographyStored(TransformInfo storage) { // Draw the key point matches and put in gallery Mat matches = storage.getMatchImage(); // Must convert to Bitmap from Mat Bitmap disp = Bitmap.createBitmap( matches.cols(), matches.rows(), Bitmap.Config.ARGB_8888); // Android uses ARGB_8888 Utils.matToBitmap(matches, disp); mImageAdapter.setPutativeImageWithLinesImage(disp); // Ready to show display reset text mExpandedImageText.setText(R.string.show_exp_image); boolean ready = mCVLibraryInitialized; transformButton.setEnabled(ready); }
private Bitmap displayDetectedMarker(VideoCapture capture, Mat markerImage) { // Get original image. capture.retrieve(mRgba, Highgui.CV_CAP_ANDROID_COLOR_FRAME_RGBA); displayRectOnImageSegment(mRgba, true); displayMarkerImage(mMarkerImage, mRgba); Bitmap bmp = Bitmap.createBitmap(mRgba.cols(), mRgba.rows(), Bitmap.Config.ARGB_8888); try { Utils.matToBitmap(mRgba, bmp); return bmp; } catch (Exception e) { Log.e("TWMarkerSurfaceView", "Utils.matToBitmap() throws an exception: " + e.getMessage()); bmp.recycle(); return null; } }
public Mat onCameraFrame(CvCameraViewFrame inputFrame) { mRgba = inputFrame.rgba(); if (mIsColorSelected) { abc = mDetector.process(mRgba); // hehe.setText(abc.toString()); List<MatOfPoint> contours = mDetector.getContours(); Log.e(TAG, "Contours count: " + contours.size()); Imgproc.drawContours(mRgba, contours, -1, CONTOUR_COLOR); Mat colorLabel = mRgba.submat(4, 68, 4, 68); colorLabel.setTo(mBlobColorRgba); Mat spectrumLabel = mRgba.submat(4, 4 + mSpectrum.rows(), 70, 70 + mSpectrum.cols()); mSpectrum.copyTo(spectrumLabel); } return mRgba; }