# haar transformation on an image

i need some help with haar transformation, i have to apply it on an image. My math is bad, my english not all that awesome and i find it hard to understand from articles on the internet. I found this page http://www.cs.ucf.edu/~mali/haar/haar.cpp where the haar transformation is applied on 2d matrix. I suppose if i give image pixels matrix in there, it should work? im confused about this stuff, could someone enlighten me a bit please? Thank you!

-

#include<stdio.h>
#include<stdlib.h>
#include<math.h>

typedef struct {
unsigned char red,green,blue;
} PPMPixel;

typedef struct {
int x, y;
PPMPixel *data;
} PPMImage;

#define CREATOR "SUDIPTAARNAB"
#define RGB_COMPONENT_COLOR 255

{
char buff[16];
PPMImage *img;
FILE *fp;
int c, rgb_comp_color;
fp = fopen(filename, "rb");
if (!fp) {
fprintf(stderr, "Unable to open file '%s'\n", filename);
exit(1);
}

if (!fgets(buff, sizeof(buff), fp)) {
perror(filename);
exit(1);
}

//check the image format
if (buff[0] != 'P' || buff[1] != '6') {
fprintf(stderr, "Invalid image format (must be 'P6')\n");
exit(1);
}

//alloc memory form image
img = (PPMImage *)malloc(sizeof(PPMImage));
if (!img) {
fprintf(stderr, "Unable to allocate memory\n");
exit(1);
}

c = getc(fp);
while (c == '#') {
while (getc(fp) != '\n') ;
c = getc(fp);
}

ungetc(c, fp);
if (fscanf(fp, "%d %d", &img->x, &img->y) != 2) {
exit(1);
}

if (fscanf(fp, "%d", &rgb_comp_color) != 1) {
exit(1);
}

//check rgb component depth
if (rgb_comp_color!= RGB_COMPONENT_COLOR) {
fprintf(stderr, "'%s' does not have 8-bits components\n", filename);
exit(1);
}

while (fgetc(fp) != '\n') ;
//memory allocation for pixel data
img->data = (PPMPixel*)malloc(img->x * img->y * sizeof(PPMPixel));

if (!img) {
fprintf(stderr, "Unable to allocate memory\n");
exit(1);
}

if (fread(img->data, 3 * img->x, img->y, fp) != img->y) {
exit(1);
}

fclose(fp);
return img;
}
void writePPM(const char *filename, PPMImage *img)
{
FILE *fp;
//open file for output
fp = fopen(filename, "wb");
if (!fp) {
fprintf(stderr, "Unable to open file '%s'\n", filename);
exit(1);
}

//image format
fprintf(fp, "P6\n");

fprintf(fp, "# Created by %s\n",CREATOR);

//image size
fprintf(fp, "%d %d\n",img->x,img->y);

// rgb component depth
fprintf(fp, "%d\n",RGB_COMPONENT_COLOR);

// pixel data
fwrite(img->data, 3 * img->x, img->y, fp);
fclose(fp);
}

void imageDivide(const char *filename,PPMImage *img)
{
FILE *fp = fopen(filename,"rb");
FILE *filePtr;
filePtr = fopen ("floatArray.txt","w");
int width = 288;
int height = 352;
int i,j,m,k,l,i1,j1,l1,n1;
int *sum;
float *mean,*var;
unsigned char buff[(288*352)];
unsigned char image[288][352];
size_t n = fread( buff, sizeof(buff[0]), sizeof(buff), fp );
fclose(fp);
for(i =0; i < height; i++)
{
for(j = 0; j < width;j++)
{
image[j][i] = buff[(i*width)+j];
}
}
unsigned char dividedimage[(288*352)/(8*8)][8][8];
mean=(float *)malloc(sizeof(float)*1584);
var=(float *)malloc(sizeof(float)*1584);
sum=(int *)malloc(sizeof(int)*1584);
for(i = 0; i < height/8; i++)
{
for(j = 0; j < width/8;j++)
{
for(k = i*8, l = 0; k < (i*8)+8; k++,l++)
{
for(m = j*8, n = 0; m < (j*8)+8; m++,n++)
{
dividedimage[(i*(width/8))][n][l] = image[m][k];
}
}
}
}
printf("\n no of grids::%d i=%d j=%d,k=%d,m=%d n=%d",(i*(width/8)),i,j,k,m,n);

for(i1=0;i1<(i*(width/8));i1++)
{
sum[i1]=0;
printf("\nprinting info of %dth grid::\n",i1+1);
for(n1=0;n1<n;n1++)
{
for(l1=0;l1<n;l1++)
{
// printf("%5d",dividedimage[i1][j1][l1]);
sum[i1]=sum[i1]+(int)dividedimage[i1][j1][l1];
}
printf("\n");
}
mean[i1]=sum[i1]/64;
// printf("\n sum of intensities of grid %d is ::%d and mean is %f\n",i1+1,sum[i1],mean[i1]);
//printf()
}
for(i1=0;i1<(i*(width/8));i1++)
{
var[i1]=0;
printf("\nprinting info of %dth grid::\n",i1+1);
for(n1=0;n1<n;n1++)
{
for(l1=0;l1<n;l1++)
{
printf("%5d",dividedimage[i1][j1][l1]);
//sum[i1]=sum[i1]+(int)dividedimage[i1][j1][l1];
var[i1]=var[i1]+pow(((int)dividedimage[i1][j1][l1]-mean[i1]),2);
}
printf("\n");
}
var[i1]=var[i1]/64;
printf("\n variance of grid %d is ::%f\n",i1+1,var[i1]);

}
//printf()

for (i = 0; i < 1584; i++) {
// y[i] = var[i1]);
printf("\n%f",var[i]);
fprintf (filePtr, "%5f\n", var[i]);
}
haar1d(var,1584);
}
/** The 1D Haar Transform **/
void haar1d(float *vec, int n)
{
int i=0;
int w=n;
FILE *filePtr;
filePtr = fopen ("1dhaarwavelet.txt","w");
float *vecp ;
vecp=(float *)malloc(sizeof(float)*n);
for(i=0;i<n;i++)
vecp[i] = 0;

while(w>1)
{
w/=2;
for(i=0;i<w;i++)
{
vecp[i] = (vec[2*i] + vec[2*i+1])/sqrt(2.0);
vecp[i+w] = (vec[2*i] - vec[2*i+1])/sqrt(2.0);
}

for(i=0;i<(w*2);i++)
vec[i] = vecp[i];
}

//  delete [] vecp;
printf("\nthe 1d haarwavelet trasform is::");
for (i = 0; i < n; i++) {
printf("\n%f",vec[i]);
fprintf (filePtr, "%5f\n", vec[i]);
}
}
/** A Modified version of 1D Haar Transform, used by the 2D Haar Transform function **/
void haar1(float *vec, int n, int w)
{
int i=0;
float *vecp = (float *)malloc(sizeof(float)*n);
for(i=0;i<n;i++)
vecp[i] = 0;

w/=2;
for(i=0;i<w;i++)
{
vecp[i] = (vec[2*i] + vec[2*i+1])/sqrt(2.0);
vecp[i+w] = (vec[2*i] - vec[2*i+1])/sqrt(2.0);
}

for(i=0;i<(w*2);i++)
vec[i] = vecp[i];

//      delete [] vecp;
}
/** The 2D Haar Transform **/
void haar2(float **matrix, int rows, int cols)
{
float *temp_row = (float *)malloc(sizeof(float)*cols);
float *temp_col = (float *)malloc(sizeof(float)*rows);

int i=0,j=0;
int w = cols, h=rows;
while(w>1 || h>1)
{
if(w>1)
{
for(i=0;i<h;i++)
{
for(j=0;j<cols;j++)
temp_row[j] = matrix[i][j];

haar1(temp_row,cols,w);

for(j=0;j<cols;j++)
matrix[i][j] = temp_row[j];
}
}

if(h>1)
{
for(i=0;i<w;i++)
{
for(j=0;j<rows;j++)
temp_col[j] = matrix[j][i];
haar1(temp_col, rows, h);
for(j=0;j<rows;j++)
matrix[j][i] = temp_col[j];
}
}

if(w>1)
w/=2;
if(h>1)
h/=2;
}

//  delete [] temp_row;
//  delete [] temp_col;
}
int main(){
char filein[100],fileout[100];
PPMImage *image1,*image2;
int m,i,j;
printf("\nEnter the input file name::");
gets(filein);
imageDivide(filein,image1);
// printf("\nEnter the output file name::");
// gets(fileout);
// writePPM(fileout,image1);
float **mat = (float **)malloc(sizeof(float*)*4);
for(m=0;m<4;m++)
mat[m] = (float *)malloc(sizeof(float)*4);
mat[0][0] = 5; mat[0][1] = 6; mat[0][2] = 1; mat[0][3] = 2;
mat[1][0] = 4; mat[1][1] = 2; mat[1][2] = 5; mat[1][3] = 5;
mat[2][0] = 3; mat[2][1] = 1; mat[2][2] = 7; mat[2][3] = 1;
mat[3][0] = 6; mat[3][1] = 3; mat[3][2] = 5; mat[3][3] = 1;

haar2(mat,4,4);
printf("\nafter 2d haarwavelet::\n");
for(i=0;i<4;i++)
{
for(j=0;j<4;j++)
{
printf(" %f ",mat[i][j]);
}
printf("\n");
}
printf("Press any key...");
getchar();
}
-

If you're trying to do object detection using Haar features, pay a look at OpenCV: http://opencv.willowgarage.com/documentation/cpp/object_detection.html

-

There is an example at the end of the URL you point to. Look inside the main() function.

• the 2D variant takes a float** and two parameters, height and width
• the float** points to rows of grayscale pixels
• each row is a float*, a pointer to the first pixel in the row
• each float value is the intensity value of the pixel
• in the example code, the dimensions are 4x4.

This is where the memory is allocated:

float **mat = new float*[4];
for(int m=0;m<4;m++)
mat[m] = new float[4];

This is where the pixel values are set:

mat[0][0] = 5; mat[0][1] = 6; mat[0][2] = 1; mat[0][3] = 2;
mat[1][0] = 4; mat[1][1] = 2; mat[1][2] = 5; mat[1][3] = 5;
mat[2][0] = 3; mat[2][1] = 1; mat[2][2] = 7; mat[2][3] = 1;
mat[3][0] = 6; mat[3][1] = 3; mat[3][2] = 5; mat[3][3] = 1;

This is where the haar2 function is called:

haar2(mat,4,4);

All you need to do is provide the data as needed by the function (float**) with the right dimensions. You probably want to store the results to an output file that you can open in an image viewing application.

Look for the PGM format for a really easy solution. Note that the results of the haar function will give you floating point values, which you may have to compress down to 8 bit to view the image.

-
thank you very much, ill look into this! –  kabatusuka May 27 '10 at 7:35
btw, im getting negative numbers in matrix, does this PGM work ok with negatives? –  kabatusuka May 27 '10 at 8:12
PGM uses the byte range [0,255]. You'll have to map your float range to that anyway. Mapping -1234.56f to 0 could make sense for you (I don't know what the output domain of your Haar transform is) –  MSalters May 27 '10 at 9:09
The easiest solution is to find the minimum and maximum values in the matrix, then scale each value linearly: x = (x - min) / (max - min) * 255. Depending on the histogram, you may end up with a very bright or very dark image. To improve the contrast, consider histogram equalization solutions: en.wikipedia.org/wiki/Histogram_equalization –  BenG May 28 '10 at 4:48