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I am looking for ways to create fisheye lens effect, looked at documentations for openCV, it looks like it contains Camera Calibration functions for radial distortions like fisheye. Is it possible to simulate fisheye distortion by openCV?

If it is possible to do it by openCV, comparing to openGL, which one will generate better results? Thanks.

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4 Answers 4

up vote 10 down vote accepted

I created this app using opencv. Is this the effect you are referring to? I basically coded the formula shown on wikipedia's "Distortion(optics)" I can show the code if needed

Update: OK, so below is the actual code written in c++ using opencv (not documented so feel free to ask for explanations): The program recieves as input the following parameter: |input image| |output image| |K which controlls amount of distortion (typically try values around 0.001)| |x coordinate of center of distortion| |y coordinate of center of distortion|

So the crux of the program is the double for loop which iterates pixel by pixel on the result image and looks for the matching pixel in the input image using the formula for radial distortion (this is the way image warping is generally done - perhaps counter intuitively by back-projection from output to input). There are some subtleties which have to do with the scale of the output image (in this program the resulting image is the same size as the input), and I won't get into it unless you want to get into more details.enjoy.

    #include <cv.h>
    #include <highgui.h>
    #include <math.h>
    #include <unistd.h>
    #include <getopt.h>
    #include <iostream>


    void sampleImage(const IplImage* arr, float idx0, float idx1, CvScalar& res)
    {
      if(idx0<0 || idx1<0 || idx0>(cvGetSize(arr).height-1) || idx1>(cvGetSize(arr).width-1)){
        res.val[0]=0;
        res.val[1]=0;
        res.val[2]=0;
        res.val[3]=0;
        return;
      }
      float idx0_fl=floor(idx0);
      float idx0_cl=ceil(idx0);
      float idx1_fl=floor(idx1);
      float idx1_cl=ceil(idx1);

      CvScalar s1=cvGet2D(arr,(int)idx0_fl,(int)idx1_fl);
      CvScalar s2=cvGet2D(arr,(int)idx0_fl,(int)idx1_cl);
      CvScalar s3=cvGet2D(arr,(int)idx0_cl,(int)idx1_cl);
      CvScalar s4=cvGet2D(arr,(int)idx0_cl,(int)idx1_fl);
      float x = idx0 - idx0_fl;
      float y = idx1 - idx1_fl;
      res.val[0]= s1.val[0]*(1-x)*(1-y) + s2.val[0]*(1-x)*y + s3.val[0]*x*y + s4.val[0]*x*(1-y);
      res.val[1]= s1.val[1]*(1-x)*(1-y) + s2.val[1]*(1-x)*y + s3.val[1]*x*y + s4.val[1]*x*(1-y);
      res.val[2]= s1.val[2]*(1-x)*(1-y) + s2.val[2]*(1-x)*y + s3.val[2]*x*y + s4.val[2]*x*(1-y);
      res.val[3]= s1.val[3]*(1-x)*(1-y) + s2.val[3]*(1-x)*y + s3.val[3]*x*y + s4.val[3]*x*(1-y);
    }

    float xscale;
    float yscale;
    float xshift;
    float yshift;

    float getRadialX(float x,float y,float cx,float cy,float k){
      x = (x*xscale+xshift);
      y = (y*yscale+yshift);
      float res = x+((x-cx)*k*((x-cx)*(x-cx)+(y-cy)*(y-cy)));
      return res;
    }

    float getRadialY(float x,float y,float cx,float cy,float k){
      x = (x*xscale+xshift);
      y = (y*yscale+yshift);
      float res = y+((y-cy)*k*((x-cx)*(x-cx)+(y-cy)*(y-cy)));
      return res;
    }

    float thresh = 1;
    float calc_shift(float x1,float x2,float cx,float k){
      float x3 = x1+(x2-x1)*0.5;
      float res1 = x1+((x1-cx)*k*((x1-cx)*(x1-cx)));
      float res3 = x3+((x3-cx)*k*((x3-cx)*(x3-cx)));

      //  std::cerr<<"x1: "<<x1<<" - "<<res1<<" x3: "<<x3<<" - "<<res3<<std::endl;

      if(res1>-thresh and res1 < thresh)
        return x1;
      if(res3<0){
        return calc_shift(x3,x2,cx,k);
      }
      else{
        return calc_shift(x1,x3,cx,k);
      }
    }

    int main(int argc, char** argv)
    {
      IplImage* src = cvLoadImage( argv[1], 1 );
      IplImage* dst = cvCreateImage(cvGetSize(src),src->depth,src->nChannels);
      IplImage* dst2 = cvCreateImage(cvGetSize(src),src->depth,src->nChannels);
      float K=atof(argv[3]);
      float centerX=atoi(argv[4]);
      float centerY=atoi(argv[5]);
      int width = cvGetSize(src).width;
      int height = cvGetSize(src).height;

      xshift = calc_shift(0,centerX-1,centerX,K);
      float newcenterX = width-centerX;
      float xshift_2 = calc_shift(0,newcenterX-1,newcenterX,K);

      yshift = calc_shift(0,centerY-1,centerY,K);
      float newcenterY = height-centerY;
      float yshift_2 = calc_shift(0,newcenterY-1,newcenterY,K);
      //  scale = (centerX-xshift)/centerX;
      xscale = (width-xshift-xshift_2)/width;
      yscale = (height-yshift-yshift_2)/height;

      std::cerr<<xshift<<" "<<yshift<<" "<<xscale<<" "<<yscale<<std::endl;
      std::cerr<<cvGetSize(src).height<<std::endl;
      std::cerr<<cvGetSize(src).width<<std::endl;

      for(int j=0;j<cvGetSize(dst).height;j++){
        for(int i=0;i<cvGetSize(dst).width;i++){
          CvScalar s;
          float x = getRadialX((float)i,(float)j,centerX,centerY,K);
          float y = getRadialY((float)i,(float)j,centerX,centerY,K);
          sampleImage(src,y,x,s);
          cvSet2D(dst,j,i,s);

        }
      }
    #if 0
      cvNamedWindow( "Source1", 1 );
      cvShowImage( "Source1", dst);
      cvWaitKey(0);
    #endif

      cvSaveImage(argv[2],dst,0);

    #if 0
      for(int j=0;j<cvGetSize(src).height;j++){
        for(int i=0;i<cvGetSize(src).width;i++){
          CvScalar s;
          sampleImage(src,j+0.25,i+0.25,s);
          cvSet2D(dst,j,i,s);
        }
      }

      cvNamedWindow( "Source1", 1 );
      cvShowImage( "Source1", src);
      cvWaitKey(0);

    #endif  

}
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Yes! Barrel distortion on Wiki's "Distortion(optics)" page is exactly what I am looking for! I would like to know how to map an image around fisheye lenses with openCV. Can you show your code here? Or show me some hints? Thank you. Regards –  claris Dec 21 '09 at 8:40
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Thanks to the above 2 for this code. I've modified the above transcribed code in Java to use Bitmaps instead of BufferedImage. This enables the code to run on Android(which doesn't support AWT). I've also made the effect just manipulate the pixels in a circle rather than the whole Bitmap, this gives a fisheye "lens" effect. Hopes this helps any Android developers.

import android.graphics.Bitmap;
import android.util.Log;

class Filters{
    float xscale;
    float yscale;
    float xshift;
    float yshift;
    int [] s;
    private String TAG = "Filters";
    public Filters(){

        Log.e(TAG, "***********inside constructor");
    }

    public Bitmap barrel (Bitmap input, float k){
        Log.e(TAG, "***********inside barrel method ");
        float centerX=input.getWidth()/2; //center of distortion
        float centerY=input.getHeight()/2;

        int width = input.getWidth(); //image bounds
        int height = input.getHeight();

        Bitmap dst = Bitmap.createBitmap(width, height,input.getConfig() ); //output pic
        Log.e(TAG, "***********dst bitmap created ");
          xshift = calc_shift(0,centerX-1,centerX,k);
          float newcenterX = width-centerX;
          float xshift_2 = calc_shift(0,newcenterX-1,newcenterX,k);

          yshift = calc_shift(0,centerY-1,centerY,k);
          float newcenterY = height-centerY;
          float yshift_2 = calc_shift(0,newcenterY-1,newcenterY,k);

          xscale = (width-xshift-xshift_2)/width;
          yscale = (height-yshift-yshift_2)/height;
          Log.e(TAG, "***********about to loop through bm");
          /*for(int j=0;j<dst.getHeight();j++){
              for(int i=0;i<dst.getWidth();i++){
                float x = getRadialX((float)i,(float)j,centerX,centerY,k);
                float y = getRadialY((float)i,(float)j,centerX,centerY,k);
                sampleImage(input,x,y);
                int color = ((s[1]&0x0ff)<<16)|((s[2]&0x0ff)<<8)|(s[3]&0x0ff);
    //            System.out.print(i+" "+j+" \\");

                dst.setPixel(i, j, color);

              }
            }*/

          int origPixel; // the pixel in orig image

          for(int j=0;j<dst.getHeight();j++){
              for(int i=0;i<dst.getWidth();i++){
                 origPixel= input.getPixel(i,j);
                float x = getRadialX((float)i,(float)j,centerX,centerY,k);
                float y = getRadialY((float)i,(float)j,centerX,centerY,k);
                sampleImage(input,x,y);
                int color = ((s[1]&0x0ff)<<16)|((s[2]&0x0ff)<<8)|(s[3]&0x0ff);
    //            System.out.print(i+" "+j+" \\");


// check whether a pixel is within the circle bounds of 150

                if( Math.sqrt( Math.pow(i - centerX, 2) + ( Math.pow(j - centerY, 2) ) ) <= 150 ){
                dst.setPixel(i, j, color);
                }else{
                    dst.setPixel(i,j,origPixel);
                }
              }
            }
        return dst;
    }

    void sampleImage(Bitmap arr, float idx0, float idx1)
    {
        s = new int [4];
      if(idx0<0 || idx1<0 || idx0>(arr.getHeight()-1) || idx1>(arr.getWidth()-1)){
        s[0]=0;
        s[1]=0;
        s[2]=0;
        s[3]=0;
        return;
      }

      float idx0_fl=(float) Math.floor(idx0);
      float idx0_cl=(float) Math.ceil(idx0);
      float idx1_fl=(float) Math.floor(idx1);
      float idx1_cl=(float) Math.ceil(idx1);

      int [] s1 = getARGB(arr,(int)idx0_fl,(int)idx1_fl);
      int [] s2 = getARGB(arr,(int)idx0_fl,(int)idx1_cl);
      int [] s3 = getARGB(arr,(int)idx0_cl,(int)idx1_cl);
      int [] s4 = getARGB(arr,(int)idx0_cl,(int)idx1_fl);

      float x = idx0 - idx0_fl;
      float y = idx1 - idx1_fl;

      s[0]= (int) (s1[0]*(1-x)*(1-y) + s2[0]*(1-x)*y + s3[0]*x*y + s4[0]*x*(1-y));
      s[1]= (int) (s1[1]*(1-x)*(1-y) + s2[1]*(1-x)*y + s3[1]*x*y + s4[1]*x*(1-y));
      s[2]= (int) (s1[2]*(1-x)*(1-y) + s2[2]*(1-x)*y + s3[2]*x*y + s4[2]*x*(1-y));
      s[3]= (int) (s1[3]*(1-x)*(1-y) + s2[3]*(1-x)*y + s3[3]*x*y + s4[3]*x*(1-y));
    }

    int [] getARGB(Bitmap buf,int x, int y){
        int rgb = buf.getPixel(y, x); // Returns by default ARGB.
        int [] scalar = new int[4];
        scalar[0] = (rgb >>> 24) & 0xFF;
        scalar[1] = (rgb >>> 16) & 0xFF;
        scalar[2] = (rgb >>> 8) & 0xFF;
        scalar[3] = (rgb >>> 0) & 0xFF;
        return scalar;
    }

    float getRadialX(float x,float y,float cx,float cy,float k){
      x = (x*xscale+xshift);
      y = (y*yscale+yshift);
      float res = x+((x-cx)*k*((x-cx)*(x-cx)+(y-cy)*(y-cy)));
      return res;
    }

    float getRadialY(float x,float y,float cx,float cy,float k){
      x = (x*xscale+xshift);
      y = (y*yscale+yshift);
      float res = y+((y-cy)*k*((x-cx)*(x-cx)+(y-cy)*(y-cy)));
      return res;
    }

    float thresh = 1;

    float calc_shift(float x1,float x2,float cx,float k){
      float x3 = (float)(x1+(x2-x1)*0.5);
      float res1 = x1+((x1-cx)*k*((x1-cx)*(x1-cx)));
      float res3 = x3+((x3-cx)*k*((x3-cx)*(x3-cx)));

      if(res1>-thresh && res1 < thresh)
        return x1;
      if(res3<0){
        return calc_shift(x3,x2,cx,k);
      }
      else{
        return calc_shift(x1,x3,cx,k);
      }
    }
}

.

import java.util.concurrent.Callable;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.FutureTask;

import android.graphics.Bitmap;
import android.graphics.drawable.BitmapDrawable;
import android.os.Debug;
import android.util.Log;

public class MultiRuntimeProcessorFilter {



    private static final String TAG = "mrpf";
    private int x = 0;
    private Bitmap input = null;
    private int radius;


    public void createBitmapSections(int nOp, int[] sections){

        int processors = nOp;
        int jMax = input.getHeight();
        int aSectionSize = (int) Math.ceil(jMax/processors);
        Log.e(TAG, "++++++++++ sections size = "+aSectionSize);


        int k = 0;
        for(int h=0; h<processors+1; h++){

                sections[h] = k;
                k+= aSectionSize;



        }
    }// end of createBitmapSections()



    @SuppressWarnings("unchecked")
    public Bitmap barrel (Bitmap input, float k, int r){
          this.radius = r;
          this.input = input;
          int []arr = new int[input.getWidth()*input.getHeight()];


          Log.e(TAG, "bitmap height = "+input.getHeight()); 




          int nrOfProcessors = Runtime.getRuntime().availableProcessors();
          Log.e(TAG, "no of processors = "+nrOfProcessors);

          int[] sections = new int[nrOfProcessors+1];


          createBitmapSections(nrOfProcessors,sections);
          ExecutorService threadPool = Executors.newFixedThreadPool(nrOfProcessors);

          for(int g=0; g<sections.length;g++){
              Log.e(TAG, "++++++++++ sections= "+sections[g]);
          }

         // ExecutorService threadPool = Executors.newFixedThreadPool(nrOfProcessors);

          Object[] task = new Object[nrOfProcessors];

          for(int z = 0; z < nrOfProcessors; z++){
             task[z]  = (FutureTask<PartialResult>) threadPool.submit(new PartialProcessing(sections[z], sections[z+1] - 1, input, k));  
             Log.e(TAG, "++++++++++ task"+z+"= "+task[z].toString()); 
          }

         PartialResult[] results = new PartialResult[nrOfProcessors];

         try{
              for(int t = 0; t < nrOfProcessors; t++){

                  results[t] = ((FutureTask<PartialResult>) task[t]).get();

                  results[t].fill(arr);
              }

          }catch(Exception e){
              e.printStackTrace();
          }

          Bitmap dst2 = Bitmap.createBitmap(arr,input.getWidth(),input.getHeight(),input.getConfig());


        return dst2;


        }//end of barrel()




    public class PartialResult {
           int startP;
           int endP;
           int[] storedValues;

           public PartialResult(int startp, int endp, Bitmap input){

               this.startP = startp;
               this.endP = endp;
               this.storedValues = new int[input.getWidth()*input.getHeight()];


           }

           public void addValue(int p, int result) {
                 storedValues[p] = result;

           }

           public void fill(int[] arr) {



              for (int p = startP; p < endP; p++){
                  for(int b=0;b<radius;b++,x++)
                 arr[x] = storedValues[x];

              } 
              Log.e(TAG, "++++++++++ x ="+x);
              }

           }//end of partialResult




    public class PartialProcessing implements Callable<PartialResult> {
        int startJ;
        int endJ;


        private int[] scalar;
        private float xscale;
        private float yscale;
        private float xshift;
        private float yshift;
        private float thresh = 1;
        private int [] s1;
        private int [] s2;
        private int [] s3;
        private int [] s4;
        private int [] s;
        private Bitmap input;
        private float k;



        public PartialProcessing(int startj, int endj, Bitmap input, float k) {

            this.startJ = startj;
            this.endJ = endj;
            this.input = input;
            this.k = k;

            s = new int[4];
            scalar = new int[4];
            s1 = new int[4];
            s2 = new int[4];
            s3 = new int[4];
            s4 = new int[4];

        }

        int [] getARGB(Bitmap buf,int x, int y){

            int rgb = buf.getPixel(y, x); // Returns by default ARGB.
            // int [] scalar = new int[4];
           //  scalar[0] = (rgb >>> 24) & 0xFF;
             scalar[1] = (rgb >>> 16) & 0xFF;
             scalar[2] = (rgb >>> 8) & 0xFF;
             scalar[3] = (rgb >>> 0) & 0xFF;
             return scalar;

        }



        float getRadialX(float x,float y,float cx,float cy,float k){

            x = (x*xscale+xshift);
            y = (y*yscale+yshift);
            float res = x+((x-cx)*k*((x-cx)*(x-cx)+(y-cy)*(y-cy)));
            return res;
          }

          float getRadialY(float x,float y,float cx,float cy,float k){

            x = (x*xscale+xshift);
            y = (y*yscale+yshift);
            float res = y+((y-cy)*k*((x-cx)*(x-cx)+(y-cy)*(y-cy)));
            return res;
          }



          float calc_shift(float x1,float x2,float cx,float k){

            float x3 = (float)(x1+(x2-x1)*0.5);
            float res1 = x1+((x1-cx)*k*((x1-cx)*(x1-cx)));
            float res3 = x3+((x3-cx)*k*((x3-cx)*(x3-cx)));

            if(res1>-thresh && res1 < thresh)
              return x1;
            if(res3<0){
              return calc_shift(x3,x2,cx,k);
            }
            else{
              return calc_shift(x1,x3,cx,k);
            }
          }


          void sampleImage(Bitmap arr, float idx0, float idx1)
          {

             // s = new int [4];
            if(idx0<0 || idx1<0 || idx0>(arr.getHeight()-1) || idx1>(arr.getWidth()-1)){
              s[0]=0;
              s[1]=0;
              s[2]=0;
              s[3]=0;
              return;
            }

            float idx0_fl=(float) Math.floor(idx0);
            float idx0_cl=(float) Math.ceil(idx0);
            float idx1_fl=(float) Math.floor(idx1);
            float idx1_cl=(float) Math.ceil(idx1);



             s1 = getARGB(arr,(int)idx0_fl,(int)idx1_fl);
             s2 = getARGB(arr,(int)idx0_fl,(int)idx1_cl);
             s3 = getARGB(arr,(int)idx0_cl,(int)idx1_cl);
             s4 = getARGB(arr,(int)idx0_cl,(int)idx1_fl);

            float x = idx0 - idx0_fl;
            float y = idx1 - idx1_fl;

           // s[0]= (int) (s1[0]*(1-x)*(1-y) + s2[0]*(1-x)*y + s3[0]*x*y + s4[0]*x*(1-y));
            s[1]= (int) (s1[1]*(1-x)*(1-y) + s2[1]*(1-x)*y + s3[1]*x*y + s4[1]*x*(1-y));
            s[2]= (int) (s1[2]*(1-x)*(1-y) + s2[2]*(1-x)*y + s3[2]*x*y + s4[2]*x*(1-y));
            s[3]= (int) (s1[3]*(1-x)*(1-y) + s2[3]*(1-x)*y + s3[3]*x*y + s4[3]*x*(1-y));


          }



        @Override public PartialResult call() { 

             PartialResult partialResult = new PartialResult(startJ, endJ,input);

             float centerX=input.getWidth()/2; //center of distortion
             float centerY=input.getHeight()/2;



             int width = input.getWidth(); //image bounds
             int height = input.getHeight();



              xshift = calc_shift(0,centerX-1,centerX,k);

              float newcenterX = width-centerX;
              float xshift_2 = calc_shift(0,newcenterX-1,newcenterX,k);

              yshift = calc_shift(0,centerY-1,centerY,k);

              float newcenterY = height-centerY;
              float yshift_2 = calc_shift(0,newcenterY-1,newcenterY,k);

              xscale = (width-xshift-xshift_2)/width;

              yscale = (height-yshift-yshift_2)/height;


            int p = startJ*radius; 
            int origPixel = 0;
            int color = 0;
            int i;

            for (int j = startJ; j <  endJ; j++){

                for ( i = 0; i < width; i++, p++){


             origPixel = input.getPixel(i,j);

             float x = getRadialX((float)j,(float)i,centerX,centerY,k);


             float y = getRadialY((float)j,(float)i,centerX,centerY,k);

             sampleImage(input,x,y);

             color = ((s[1]&0x0ff)<<16)|((s[2]&0x0ff)<<8)|(s[3]&0x0ff);
            //Log.e(TAG, "radius = "+radius);

             if(((i-centerX)*(i-centerX) + (j-centerY)*(j-centerY)) <= radius*(radius/4)){

                                 partialResult.addValue(p, color);


            }else{


                partialResult.addValue(p, origPixel);



            }

                }//end of inner for

        }//end of outer for

            return partialResult;
    }//end of call


}// end of partialprocessing

}//end of MultiProcesorFilter

@And_Dev as promised

Below is the view that gets the users touch co-ords and then calls the filter on a selected area. the selected area is the cord eg center of circle plus a radius(a circle). the code does this twice as its for a breast augmentation app:) Just comment out the HorizontalSlider code as you don't need this.

import java.io.BufferedInputStream;
import java.io.DataInputStream;
import java.io.File;
import java.io.FileInputStream;
import java.io.InputStream;

import android.content.Context;
import android.graphics.Bitmap;
import android.graphics.BitmapFactory;
import android.graphics.Canvas;
import android.graphics.Color;
import android.graphics.Paint;
import android.graphics.PorterDuff.Mode;
import android.graphics.PorterDuffXfermode;
import android.os.Environment;
import android.util.AttributeSet;
import android.util.Log;
import android.view.MotionEvent;
import android.view.View;

import com.tecmark.HorizontalSlider.OnProgressChangeListener;

public class TouchView extends View{


    private File tempFile;
    private byte[] imageArray;
    private Bitmap bgr;

    private Bitmap crop;
    private Bitmap crop2;
    private Bitmap overLay;
    private Bitmap overLay2;


    private float centreX;
    private float centreY;
    private float centreA = 200;
    private float centreB = 200;
    private Boolean xyFound = false;
    private int Progress = 1;
    private static final String TAG = "*********TouchView";
    private Filters f = null;
    private boolean bothCirclesInPlace = false;
    private MultiProcessorFilter mpf;
    private MultiProcessorFilter mpf2;
    private MultiRuntimeProcessorFilter mrpf;
    private MultiRuntimeProcessorFilter mrpf2;





    public TouchView(Context context) {
        super(context);

    }




    public TouchView(Context context, AttributeSet attr) {
        super(context,attr);
        Log.e(TAG, "++++++++++ inside touchview constructor");



        tempFile = new File(Environment.getExternalStorageDirectory().
                getAbsolutePath() + "/"+"image.jpg");

        imageArray = new byte[(int)tempFile.length()];


     try{

            InputStream is = new FileInputStream(tempFile);
            BufferedInputStream bis = new BufferedInputStream(is);
            DataInputStream dis = new DataInputStream(bis);


            int i = 0;

            while (dis.available() > 0) {
            imageArray[i] = dis.readByte();
            i++;
            }

            dis.close();

       } catch (Exception e) {

               e.printStackTrace();
            }


       Bitmap bm = BitmapFactory.decodeByteArray(imageArray, 0, imageArray.length);




        bgr = bm.copy(bm.getConfig(), true);;

        overLay = null;
        overLay2 = null;



       bm.recycle();

    }// end of touchView constructor




    public void findCirclePixels(){ 

         //  f = new Filters();
         //  mpf = new MultiProcessorFilter();
         //  mpf2 = new MultiProcessorFilter();
         mrpf = new MultiRuntimeProcessorFilter();
         mrpf2 = new MultiRuntimeProcessorFilter();

         crop = Bitmap.createBitmap(bgr,Math.max((int)centreX-75,0),Math.max((int)centreY-75,0),150,150);
         crop2 = Bitmap.createBitmap(bgr,Math.max((int)centreA-75,0),Math.max((int)centreB-75,0),150,150);

              new Thread(new Runnable() {
                public void run() {
                    float prog = (float)Progress/150001;

               // final Bitmap bgr3 = f.barrel(crop,prog);
               // final Bitmap bgr4 = f.barrel(crop2,prog);

              //  final Bitmap bgr3 = mpf.barrel(crop,prog);
              //  final Bitmap bgr4 = mpf2.barrel(crop2,prog);

                    final Bitmap bgr3 = mrpf.barrel(crop,prog);
                    final Bitmap bgr4 = mrpf2.barrel(crop2,prog);

                  TouchView.this.post(new Runnable() {
                    public void run() {


                      TouchView.this.overLay = bgr3;
                      TouchView.this.overLay2 = bgr4;

                      TouchView.this.invalidate();

                    }
                  });
                }
              }).start();


        }// end of changePixel()






    @Override
    public boolean onTouchEvent(MotionEvent ev) {

        switch (ev.getAction()) {

            case MotionEvent.ACTION_DOWN: {

                if(xyFound == false){
                centreX = (int) ev.getX();
                centreY = (int) ev.getY();
                xyFound = true;
                }else{
                centreA = (int) ev.getX();
                centreB = (int) ev.getY();
                bothCirclesInPlace  = true;
                }


                break;
            }

          /*  case MotionEvent.ACTION_MOVE: {

                if(xyFound == false){
                    centreX = (int) ev.getX();
                    centreY = (int) ev.getY();
                    xyFound = true;
                }else{
                    centreA = (int) ev.getX();
                    centreB = (int) ev.getY();
                    bothCirclesInPlace = true;
                    }

                    findCirclePixels();
                 // TouchView.this.invalidate();
                    break;

            }*/           

            case MotionEvent.ACTION_UP: 

                break;

        }
        return true;
    }//end of onTouchEvent





    public void initSlider(final HorizontalSlider slider)
    {

        slider.setOnProgressChangeListener(changeListener);


    }



    private OnProgressChangeListener changeListener = new OnProgressChangeListener() {


        @Override
        public void onProgressChanged(View v, int progress) {



              setProgress(progress);



        }
    };




    @Override
    public void onDraw(Canvas canvas){
        super.onDraw(canvas);

        Log.e(TAG, "******about to draw bgr ");
        canvas.drawBitmap(bgr, 0, 0, null);

        if(bothCirclesInPlace == true){

                if(overLay != null){
                    Log.e(TAG, "******about to draw overlay1 ");
        canvas.drawBitmap(overLay, centreX-75, centreY-75, null);
                }
            if(overLay2 != null){
                Log.e(TAG, "******about to draw overlay2 ");
        canvas.drawBitmap(overLay2, centreA-75, centreB-75, null);
            }

        }

    }//end of onDraw




    protected void setProgress(int progress2) {
        Log.e(TAG, "***********in SETPROGRESS");
        this.Progress = progress2;



        findCirclePixels();


    }




}

.

The calling activity.

import android.app.Activity;
import android.os.AsyncTask;
import android.os.Bundle;
import android.util.Log;
import android.view.View;
import android.view.Window;
import android.view.WindowManager;
import android.view.View.OnClickListener;
import android.widget.Button;

public class Jjilapp extends Activity {




    private static final String TAG = "*********jjil";


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

        requestWindowFeature(Window.FEATURE_NO_TITLE);
        getWindow().setFlags(WindowManager.LayoutParams.FLAG_FULLSCREEN,
                WindowManager.LayoutParams.FLAG_FULLSCREEN);

        setContentView(R.layout.touchview);
        final TouchView touchView = (TouchView)findViewById(R.id.touchview); 
        final HorizontalSlider slider = (HorizontalSlider)findViewById(R.id.slider); 

        touchView.initSlider(slider);




    }//end of oncreate




}

If you need any help mate just ask. hope this helps

share|improve this answer
    
I have tried your code in android but the sphere is still black. I have also tried this on OpenCV and its working fine but i need this feature in android app. Could you please guide me on this. Thanks –  WildFire Jun 9 '12 at 10:18
    
@Challenger what version of android are you running it on? –  turtleboy Jun 14 '12 at 9:47
    
I have debugged it and found the problem that alpha value of pixel is not setting up in the sphere region that why it coming black. setting the alpha of pixel solves the problem. Thanks for your time –  WildFire Jun 14 '12 at 11:45
    
@challenger hey glad you worked it out! I've actually re-done this code so it processes the bitmap using parallelisation. It check the device to see how many processor are available eg on my htc one X there are 4 cores. it will divide the bitmap into 4, assign each core a segment and then stitch it all back together when done. You can have the code if you like, just let me know. it works on android 2.1, but not too good on android 4.0. if u wanna play around with it and see if u can get it going, if u do, i just ask for an update;) –  turtleboy Jun 15 '12 at 21:09
    
Thanks, I appreciate for your help. I have used the above code it's working great for square image but when image has too much difference between width and height then output sphere will come black from the boundary also its not from the centre, I have tried to debugged but not successful yet, if you any idea how to resolve this issue please share it. It would be my pleasure if you share the parallisation code with me. –  WildFire Jun 16 '12 at 5:40
show 13 more comments

Thanks to you for that code. It helps me a lot. I transcrypted it for Java. Maybe someone has a similar function for symulating tangencial distorsion?

import java.awt.image.BufferedImage;
import java.io.File;
import java.io.IOException;
import javax.imageio.ImageIO;
import com.jhlabs.image.InterpolateFilter;

class Filters{
    float xscale;
    float yscale;
    float xshift;
    float yshift;
    int [] s;
    public Filters(){

    }

    public BufferedImage barrel (BufferedImage input, float k){

        float centerX=input.getWidth()/2; //center of distortion
        float centerY=input.getHeight()/2;

        int width = input.getWidth(); //image bounds
        int height = input.getHeight();

        BufferedImage dst = new BufferedImage(width, height,BufferedImage.TYPE_INT_RGB); //output pic

          xshift = calc_shift(0,centerX-1,centerX,k);
          float newcenterX = width-centerX;
          float xshift_2 = calc_shift(0,newcenterX-1,newcenterX,k);

          yshift = calc_shift(0,centerY-1,centerY,k);
          float newcenterY = height-centerY;
          float yshift_2 = calc_shift(0,newcenterY-1,newcenterY,k);

          xscale = (width-xshift-xshift_2)/width;
          yscale = (height-yshift-yshift_2)/height;

          for(int j=0;j<dst.getHeight();j++){
              for(int i=0;i<dst.getWidth();i++){
                float x = getRadialX((float)i,(float)j,centerX,centerY,k);
                float y = getRadialY((float)i,(float)j,centerX,centerY,k);
                sampleImage(input,x,y);
                int color = ((s[1]&0x0ff)<<16)|((s[2]&0x0ff)<<8)|(s[3]&0x0ff);
    //            System.out.print(i+" "+j+" \\");

                dst.setRGB(i, j, color);

              }
            }
        return dst;
    }

    void sampleImage(BufferedImage arr, float idx0, float idx1)
    {
        s = new int [4];
      if(idx0<0 || idx1<0 || idx0>(arr.getHeight()-1) || idx1>(arr.getWidth()-1)){
        s[0]=0;
        s[1]=0;
        s[2]=0;
        s[3]=0;
        return;
      }

      float idx0_fl=(float) Math.floor(idx0);
      float idx0_cl=(float) Math.ceil(idx0);
      float idx1_fl=(float) Math.floor(idx1);
      float idx1_cl=(float) Math.ceil(idx1);

      int [] s1 = getARGB(arr,(int)idx0_fl,(int)idx1_fl);
      int [] s2 = getARGB(arr,(int)idx0_fl,(int)idx1_cl);
      int [] s3 = getARGB(arr,(int)idx0_cl,(int)idx1_cl);
      int [] s4 = getARGB(arr,(int)idx0_cl,(int)idx1_fl);

      float x = idx0 - idx0_fl;
      float y = idx1 - idx1_fl;

      s[0]= (int) (s1[0]*(1-x)*(1-y) + s2[0]*(1-x)*y + s3[0]*x*y + s4[0]*x*(1-y));
      s[1]= (int) (s1[1]*(1-x)*(1-y) + s2[1]*(1-x)*y + s3[1]*x*y + s4[1]*x*(1-y));
      s[2]= (int) (s1[2]*(1-x)*(1-y) + s2[2]*(1-x)*y + s3[2]*x*y + s4[2]*x*(1-y));
      s[3]= (int) (s1[3]*(1-x)*(1-y) + s2[3]*(1-x)*y + s3[3]*x*y + s4[3]*x*(1-y));
    }

    int [] getARGB(BufferedImage buf,int x, int y){
        int rgb = buf.getRGB(x, y); // Returns by default ARGB.
        int [] scalar = new int[4];
        scalar[0] = (rgb >>> 24) & 0xFF;
        scalar[1] = (rgb >>> 16) & 0xFF;
        scalar[2] = (rgb >>> 8) & 0xFF;
        scalar[3] = (rgb >>> 0) & 0xFF;
        return scalar;
    }

    float getRadialX(float x,float y,float cx,float cy,float k){
      x = (x*xscale+xshift);
      y = (y*yscale+yshift);
      float res = x+((x-cx)*k*((x-cx)*(x-cx)+(y-cy)*(y-cy)));
      return res;
    }

    float getRadialY(float x,float y,float cx,float cy,float k){
      x = (x*xscale+xshift);
      y = (y*yscale+yshift);
      float res = y+((y-cy)*k*((x-cx)*(x-cx)+(y-cy)*(y-cy)));
      return res;
    }

    float thresh = 1;

    float calc_shift(float x1,float x2,float cx,float k){
      float x3 = (float)(x1+(x2-x1)*0.5);
      float res1 = x1+((x1-cx)*k*((x1-cx)*(x1-cx)));
      float res3 = x3+((x3-cx)*k*((x3-cx)*(x3-cx)));

      if(res1>-thresh && res1 < thresh)
        return x1;
      if(res3<0){
        return calc_shift(x3,x2,cx,k);
      }
      else{
        return calc_shift(x1,x3,cx,k);
      }
    }
}
share|improve this answer
    
hi, this java code is exactly what i need. i'm trying to create the same efect on Android but can't use bufferedimage, as android doesn't support it. is there a way around to get this code running on android? any help would be appreciated, thanks matt –  turtleboy May 22 '11 at 16:20
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Do you want to use this distortion on sintetic images, or do you want to apply to a video camera or something ?

In OpenCv you should be able to do camera calibration (using the built-in functions, Zhang's algorithm) ..

In OpenGL see this.

Regards

share|improve this answer
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