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I am looking for a copy paste implementation of Canny Edge Detection in the processing language. I have zero idea about Image processing and very little clue about Processing, though I understand java pretty well.

Can some processing expert tell me if there is a way of implementing this http://www.tomgibara.com/computer-vision/CannyEdgeDetector.java in processing?

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It will be a major work to port the code, but it is possible to access and modify the pixels in Processing: processing.org/learning/topics/edgedetection.html (courtesy Google) –  rwong Apr 29 '11 at 5:27
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1 Answer 1

up vote 10 down vote accepted

I think if you treat processing in lights of Java then some of the problems could be solved very easily. What it means is that you can use Java classes as such.

For the demo I am using the implementation which you have shared.

>>Original Image

enter image description here

>>Changed Image

enter image description here

>>Code

import java.awt.image.BufferedImage;
import java.util.Arrays;

PImage orig;
PImage changed;

void setup() {
  orig = loadImage("c:/temp/image.png");
  size(250, 166);

  CannyEdgeDetector detector = new CannyEdgeDetector();

  detector.setLowThreshold(0.5f);
  detector.setHighThreshold(1f);

   detector.setSourceImage((java.awt.image.BufferedImage)orig.getImage());
   detector.process();
   BufferedImage edges = detector.getEdgesImage();
   changed = new PImage(edges);
  noLoop();
}

void draw() 
{
  //image(orig, 0,0, width, height);

  image(changed, 0,0, width, height);
}

// The code below is taken from "http://www.tomgibara.com/computer-vision/CannyEdgeDetector.java" 
// I have stripped the comments for conciseness

public class CannyEdgeDetector {

    // statics

    private final static float GAUSSIAN_CUT_OFF = 0.005f;
    private final static float MAGNITUDE_SCALE = 100F;
    private final static float MAGNITUDE_LIMIT = 1000F;
    private final static int MAGNITUDE_MAX = (int) (MAGNITUDE_SCALE * MAGNITUDE_LIMIT);

    // fields

    private int height;
    private int width;
    private int picsize;
    private int[] data;
    private int[] magnitude;
    private BufferedImage sourceImage;
    private BufferedImage edgesImage;

    private float gaussianKernelRadius;
    private float lowThreshold;
    private float highThreshold;
    private int gaussianKernelWidth;
    private boolean contrastNormalized;

    private float[] xConv;
    private float[] yConv;
    private float[] xGradient;
    private float[] yGradient;

    // constructors

    /**
     * Constructs a new detector with default parameters.
     */

    public CannyEdgeDetector() {
        lowThreshold = 2.5f;
        highThreshold = 7.5f;
        gaussianKernelRadius = 2f;
        gaussianKernelWidth = 16;
        contrastNormalized = false;
    }



    public BufferedImage getSourceImage() {
        return sourceImage;
    }


    public void setSourceImage(BufferedImage image) {
        sourceImage = image;
    }


    public BufferedImage getEdgesImage() {
        return edgesImage;
    }


    public void setEdgesImage(BufferedImage edgesImage) {
        this.edgesImage = edgesImage;
    }


    public float getLowThreshold() {
        return lowThreshold;
    }


    public void setLowThreshold(float threshold) {
        if (threshold < 0) throw new IllegalArgumentException();
        lowThreshold = threshold;
    }

    public float getHighThreshold() {
        return highThreshold;
    }


    public void setHighThreshold(float threshold) {
        if (threshold < 0) throw new IllegalArgumentException();
        highThreshold = threshold;
    }

    public int getGaussianKernelWidth() {
        return gaussianKernelWidth;
    }

    public void setGaussianKernelWidth(int gaussianKernelWidth) {
        if (gaussianKernelWidth < 2) throw new IllegalArgumentException();
        this.gaussianKernelWidth = gaussianKernelWidth;
    }

    public float getGaussianKernelRadius() {
        return gaussianKernelRadius;
    }

    public void setGaussianKernelRadius(float gaussianKernelRadius) {
        if (gaussianKernelRadius < 0.1f) throw new IllegalArgumentException();
        this.gaussianKernelRadius = gaussianKernelRadius;
    }

    public boolean isContrastNormalized() {
        return contrastNormalized;
    }

    public void setContrastNormalized(boolean contrastNormalized) {
        this.contrastNormalized = contrastNormalized;
    }

    // methods

    public void process() {
        width = sourceImage.getWidth();
        height = sourceImage.getHeight();
        picsize = width * height;
        initArrays();
        readLuminance();
        if (contrastNormalized) normalizeContrast();
        computeGradients(gaussianKernelRadius, gaussianKernelWidth);
        int low = Math.round(lowThreshold * MAGNITUDE_SCALE);
        int high = Math.round( highThreshold * MAGNITUDE_SCALE);
        performHysteresis(low, high);
        thresholdEdges();
        writeEdges(data);
    }

    // private utility methods

    private void initArrays() {
        if (data == null || picsize != data.length) {
            data = new int[picsize];
            magnitude = new int[picsize];

            xConv = new float[picsize];
            yConv = new float[picsize];
            xGradient = new float[picsize];
            yGradient = new float[picsize];
        }
    }
    private void computeGradients(float kernelRadius, int kernelWidth) {

        //generate the gaussian convolution masks
        float kernel[] = new float[kernelWidth];
        float diffKernel[] = new float[kernelWidth];
        int kwidth;
        for (kwidth = 0; kwidth < kernelWidth; kwidth++) {
            float g1 = gaussian(kwidth, kernelRadius);
            if (g1 <= GAUSSIAN_CUT_OFF && kwidth >= 2) break;
            float g2 = gaussian(kwidth - 0.5f, kernelRadius);
            float g3 = gaussian(kwidth + 0.5f, kernelRadius);
            kernel[kwidth] = (g1 + g2 + g3) / 3f / (2f * (float) Math.PI * kernelRadius * kernelRadius);
            diffKernel[kwidth] = g3 - g2;
        }

        int initX = kwidth - 1;
        int maxX = width - (kwidth - 1);
        int initY = width * (kwidth - 1);
        int maxY = width * (height - (kwidth - 1));

        //perform convolution in x and y directions
        for (int x = initX; x < maxX; x++) {
            for (int y = initY; y < maxY; y += width) {
                int index = x + y;
                float sumX = data[index] * kernel[0];
                float sumY = sumX;
                int xOffset = 1;
                int yOffset = width;
                for(; xOffset < kwidth ;) {
                    sumY += kernel[xOffset] * (data[index - yOffset] + data[index + yOffset]);
                    sumX += kernel[xOffset] * (data[index - xOffset] + data[index + xOffset]);
                    yOffset += width;
                    xOffset++;
                }

                yConv[index] = sumY;
                xConv[index] = sumX;
            }

        }

        for (int x = initX; x < maxX; x++) {
            for (int y = initY; y < maxY; y += width) {
                float sum = 0f;
                int index = x + y;
                for (int i = 1; i < kwidth; i++)
                    sum += diffKernel[i] * (yConv[index - i] - yConv[index + i]);

                xGradient[index] = sum;
            }

        }

        for (int x = kwidth; x < width - kwidth; x++) {
            for (int y = initY; y < maxY; y += width) {
                float sum = 0.0f;
                int index = x + y;
                int yOffset = width;
                for (int i = 1; i < kwidth; i++) {
                    sum += diffKernel[i] * (xConv[index - yOffset] - xConv[index + yOffset]);
                    yOffset += width;
                }

                yGradient[index] = sum;
            }

        }

        initX = kwidth;
        maxX = width - kwidth;
        initY = width * kwidth;
        maxY = width * (height - kwidth);
        for (int x = initX; x < maxX; x++) {
            for (int y = initY; y < maxY; y += width) {
                int index = x + y;
                int indexN = index - width;
                int indexS = index + width;
                int indexW = index - 1;
                int indexE = index + 1;
                int indexNW = indexN - 1;
                int indexNE = indexN + 1;
                int indexSW = indexS - 1;
                int indexSE = indexS + 1;

                float xGrad = xGradient[index];
                float yGrad = yGradient[index];
                float gradMag = hypot(xGrad, yGrad);

                //perform non-maximal supression
                float nMag = hypot(xGradient[indexN], yGradient[indexN]);
                float sMag = hypot(xGradient[indexS], yGradient[indexS]);
                float wMag = hypot(xGradient[indexW], yGradient[indexW]);
                float eMag = hypot(xGradient[indexE], yGradient[indexE]);
                float neMag = hypot(xGradient[indexNE], yGradient[indexNE]);
                float seMag = hypot(xGradient[indexSE], yGradient[indexSE]);
                float swMag = hypot(xGradient[indexSW], yGradient[indexSW]);
                float nwMag = hypot(xGradient[indexNW], yGradient[indexNW]);
                float tmp;

                if (xGrad * yGrad <= (float) 0 /*(1)*/
                    ? Math.abs(xGrad) >= Math.abs(yGrad) /*(2)*/
                        ? (tmp = Math.abs(xGrad * gradMag)) >= Math.abs(yGrad * neMag - (xGrad + yGrad) * eMag) /*(3)*/
                            && tmp > Math.abs(yGrad * swMag - (xGrad + yGrad) * wMag) /*(4)*/
                        : (tmp = Math.abs(yGrad * gradMag)) >= Math.abs(xGrad * neMag - (yGrad + xGrad) * nMag) /*(3)*/
                            && tmp > Math.abs(xGrad * swMag - (yGrad + xGrad) * sMag) /*(4)*/
                    : Math.abs(xGrad) >= Math.abs(yGrad) /*(2)*/
                        ? (tmp = Math.abs(xGrad * gradMag)) >= Math.abs(yGrad * seMag + (xGrad - yGrad) * eMag) /*(3)*/
                            && tmp > Math.abs(yGrad * nwMag + (xGrad - yGrad) * wMag) /*(4)*/
                        : (tmp = Math.abs(yGrad * gradMag)) >= Math.abs(xGrad * seMag + (yGrad - xGrad) * sMag) /*(3)*/
                            && tmp > Math.abs(xGrad * nwMag + (yGrad - xGrad) * nMag) /*(4)*/
                    ) {
                    magnitude[index] = gradMag >= MAGNITUDE_LIMIT ? MAGNITUDE_MAX : (int) (MAGNITUDE_SCALE * gradMag);
                    //NOTE: The orientation of the edge is not employed by this
                    //implementation. It is a simple matter to compute it at
                    //this point as: Math.atan2(yGrad, xGrad);
                } else {
                    magnitude[index] = 0;
                }
            }
        }
    }

    private float hypot(float x, float y) {
        return (float) Math.hypot(x, y);
    }

    private float gaussian(float x, float sigma) {
        return (float) Math.exp(-(x * x) / (2f * sigma * sigma));
    }

    private void performHysteresis(int low, int high) {

        Arrays.fill(data, 0);

        int offset = 0;
        for (int y = 0; y < height; y++) {
            for (int x = 0; x < width; x++) {
                if (data[offset] == 0 && magnitude[offset] >= high) {
                    follow(x, y, offset, low);
                }
                offset++;
            }
        }
    }

    private void follow(int x1, int y1, int i1, int threshold) {
        int x0 = x1 == 0 ? x1 : x1 - 1;
        int x2 = x1 == width - 1 ? x1 : x1 + 1;
        int y0 = y1 == 0 ? y1 : y1 - 1;
        int y2 = y1 == height -1 ? y1 : y1 + 1;

        data[i1] = magnitude[i1];
        for (int x = x0; x <= x2; x++) {
            for (int y = y0; y <= y2; y++) {
                int i2 = x + y * width;
                if ((y != y1 || x != x1)
                    && data[i2] == 0 
                    && magnitude[i2] >= threshold) {
                    follow(x, y, i2, threshold);
                    return;
                }
            }
        }
    }

    private void thresholdEdges() {
        for (int i = 0; i < picsize; i++) {
            data[i] = data[i] > 0 ? -1 : 0xff000000;
        }
    }

    private int luminance(float r, float g, float b) {
        return Math.round(0.299f * r + 0.587f * g + 0.114f * b);
    }

    private void readLuminance() {
        int type = sourceImage.getType();
        if (type == BufferedImage.TYPE_INT_RGB || type == BufferedImage.TYPE_INT_ARGB) {
            int[] pixels = (int[]) sourceImage.getData().getDataElements(0, 0, width, height, null);
            for (int i = 0; i < picsize; i++) {
                int p = pixels[i];
                int r = (p & 0xff0000) >> 16;
                int g = (p & 0xff00) >> 8;
                int b = p & 0xff;
                data[i] = luminance(r, g, b);
            }
        } else if (type == BufferedImage.TYPE_BYTE_GRAY) {
            byte[] pixels = (byte[]) sourceImage.getData().getDataElements(0, 0, width, height, null);
            for (int i = 0; i < picsize; i++) {
                data[i] = (pixels[i] & 0xff);
            }
        } else if (type == BufferedImage.TYPE_USHORT_GRAY) {
            short[] pixels = (short[]) sourceImage.getData().getDataElements(0, 0, width, height, null);
            for (int i = 0; i < picsize; i++) {
                data[i] = (pixels[i] & 0xffff) / 256;
            }
        } else if (type == BufferedImage.TYPE_3BYTE_BGR) {
            byte[] pixels = (byte[]) sourceImage.getData().getDataElements(0, 0, width, height, null);
            int offset = 0;
            for (int i = 0; i < picsize; i++) {
                int b = pixels[offset++] & 0xff;
                int g = pixels[offset++] & 0xff;
                int r = pixels[offset++] & 0xff;
                data[i] = luminance(r, g, b);
            }
        } else {
            throw new IllegalArgumentException("Unsupported image type: " + type);
        }
    }

    private void normalizeContrast() {
        int[] histogram = new int[256];
        for (int i = 0; i < data.length; i++) {
            histogram[data[i]]++;
        }
        int[] remap = new int[256];
        int sum = 0;
        int j = 0;
        for (int i = 0; i < histogram.length; i++) {
            sum += histogram[i];
            int target = sum*255/picsize;
            for (int k = j+1; k <=target; k++) {
                remap[k] = i;
            }
            j = target;
        }

        for (int i = 0; i < data.length; i++) {
            data[i] = remap[data[i]];
        }
    }

    private void writeEdges(int pixels[]) {
        if (edgesImage == null) {
            edgesImage = new BufferedImage(width, height, BufferedImage.TYPE_INT_ARGB);
        }
        edgesImage.getWritableTile(0, 0).setDataElements(0, 0, width, height, pixels);
    }

}
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Awesome thanks!! But I used a different edge detection (since this was too slow in java. I thought processing code (if I can write it) would be horrendous. But this is great!! –  Rewolverine May 17 '11 at 2:14
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