I have implemented a 2D median filter in CUDA and the whole program is shown below.

```
#include "cuda_runtime.h"
#include "cuda_runtime_api.h"
#include "device_launch_parameters.h"
#include <iostream>
#include <fstream>
#include <iomanip>
#include <windows.h>
#include <io.h>
#include <stdio.h>
#include<conio.h>
#include <cstdlib>
#include "cstdlib"
#include <process.h>
#include <stdlib.h>
#include <malloc.h>
#include <ctime>
using namespace std;
#define MEDIAN_DIMENSION 3 // For matrix of 3 x 3. We can Use 5 x 5 , 7 x 7 , 9 x 9......
#define MEDIAN_LENGTH 9 // Shoul be MEDIAN_DIMENSION x MEDIAN_DIMENSION = 3 x 3
#define BLOCK_WIDTH 16 // Should be 8 If matrix is of larger then of 5 x 5 elese error occur as " uses too much shared data " at surround[BLOCK_WIDTH*BLOCK_HEIGHT][MEDIAN_LENGTH]
#define BLOCK_HEIGHT 16// Should be 8 If matrix is of larger then of 5 x 5 elese error occur as " uses too much shared data " at surround[BLOCK_WIDTH*BLOCK_HEIGHT][MEDIAN_LENGTH]
__global__ void MedianFilter_gpu( unsigned short *Device_ImageData,int Image_Width,int Image_Height){
__shared__ unsigned short surround[BLOCK_WIDTH*BLOCK_HEIGHT][MEDIAN_LENGTH];
int iterator;
const int Half_Of_MEDIAN_LENGTH =(MEDIAN_LENGTH/2)+1;
int StartPoint=MEDIAN_DIMENSION/2;
int EndPoint=StartPoint+1;
const int x = blockDim.x * blockIdx.x + threadIdx.x;
const int y = blockDim.y * blockIdx.y + threadIdx.y;
const int tid=threadIdx.y*blockDim.y+threadIdx.x;
if(x>=Image_Width || y>=Image_Height)
return;
//Fill surround with pixel value of Image in Matrix Pettern of MEDIAN_DIMENSION x MEDIAN_DIMENSION
if (x == 0 || x == Image_Width - StartPoint || y == 0
|| y == Image_Height - StartPoint) {
} else {
iterator = 0;
for (int r = x - StartPoint; r < x + (EndPoint); r++) {
for (int c = y - StartPoint; c < y + (EndPoint); c++) {
surround[tid][iterator] =*(Device_ImageData+(c*Image_Width)+r);
iterator++;
}
}
//Sort the Surround Array to Find Median. Use Bubble Short if Matrix oF 3 x 3 Matrix
//You can use Insertion commented below to Short Bigger Dimension Matrix
//// bubble short //
for ( int i=0; i<Half_Of_MEDIAN_LENGTH; ++i)
{
// Find position of minimum element
int min=i;
for ( int l=i+1; l<MEDIAN_LENGTH; ++l)
if (surround[tid][l] <surround[tid][min] )
min=l;
// Put found minimum element in its place
unsigned short temp= surround[tid][i];
surround[tid][i]=surround[tid][min];
surround[tid][min]=temp;
}//bubble short end
//////insertion sort start //
/*int t,j,i;
for ( i = 1 ; i< MEDIAN_LENGTH ; i++) {
j = i;
while ( j > 0 && surround[tid][j] < surround[tid][j-1]) {
t= surround[tid][j];
surround[tid][j]= surround[tid][j-1];
surround[tid][j-1] = t;
j--;
}
}*/
////insertion sort end
*(Device_ImageData+(y*Image_Width)+x)= surround[tid][Half_Of_MEDIAN_LENGTH-1]; // it will give value of surround[tid][4] as Median Value if use 3 x 3 matrix
__syncthreads();
}
}
int main( int argc, const char** argv )
{
int dataLength;
int p1;
unsigned short* Host_ImageData = NULL;
ifstream is; // Read File
is.open ("D:\\Image_To_Be_Filtered.raw", ios::binary );
// get length of file:
is.seekg (0, ios::end);
dataLength = is.tellg();
is.seekg (0, ios::beg);
Host_ImageData = new unsigned short[dataLength * sizeof(char) / sizeof(unsigned short)];
is.read ((char*)Host_ImageData,dataLength);
is.close();
int Image_Width = 1580;
int Image_Height = 1050;
unsigned short *Host_ResultData = (unsigned short *)malloc(dataLength);
unsigned short *Device_ImageData = NULL;
/////////////////////////////
// As First time cudaMalloc take more time for memory alocation, i dont want to cosider this time in my process.
//So Please Ignore Code For Displaying First CudaMelloc Time
clock_t begin = clock();
unsigned short *forFirstCudaMalloc = NULL;
cudaMalloc( (void**)&forFirstCudaMalloc, dataLength * sizeof(unsigned short) );
clock_t end = clock();
double elapsed_secs = double(end - begin) / CLOCKS_PER_SEC;
cout<<"First CudaMelloc time = "<<elapsed_secs<<" Second\n" ;
cudaFree( forFirstCudaMalloc );
////////////////////////////
//Actual Process Starts From Here
clock_t beginOverAll = clock(); //
cudaMalloc( (void**)&Device_ImageData, dataLength * sizeof(unsigned short) );
cudaMemcpy(Device_ImageData, Host_ImageData, dataLength, cudaMemcpyHostToDevice);// copying Host Data To Device Memory For Filtering
int x = static_cast<int>(ceilf(static_cast<float>(1580.0) /BLOCK_WIDTH));
int y = static_cast<int>(ceilf(static_cast<float>(1050.0) /BLOCK_HEIGHT));
const dim3 grid (x, y, 1);
const dim3 block(BLOCK_WIDTH, BLOCK_HEIGHT, 1);
begin = clock();
MedianFilter_gpu<<<grid,block>>>( Device_ImageData, Image_Width, Image_Height);
cudaDeviceSynchronize();
end = clock();
elapsed_secs = double(end - begin) / CLOCKS_PER_SEC;
cout<<"Process time = "<<elapsed_secs<<" Second\n" ;
cudaMemcpy(Host_ResultData, Device_ImageData, dataLength, cudaMemcpyDeviceToHost); // copying Back Device Data To Host Memory To write In file After Filter Done
clock_t endOverall = clock();
elapsed_secs = double(endOverall - beginOverAll) / CLOCKS_PER_SEC;
cout<<"Complete Time = "<<elapsed_secs<<" Second\n" ;
ofstream of2; //Write Filtered Image Into File
of2.open("D:\\Filtered_Image.raw", ios::binary);
of2.write((char*)Host_ResultData,dataLength);
of2.close();
cout<<"\nEnd of Writing File. Press Any Key To Exit..!!";
cudaFree(Device_ImageData);
delete Host_ImageData;
delete Host_ResultData;
getch();
return 0;
}
```

Here is the link for the file I use. I used ImajeJ to store the image in "raw" format and the same for reading the "raw" Image. My image pixel is `16`

bit, `unsigned short`

. The width of the image is `1580`

and the height is `1050`

.

**I strongly believe that the filter can be made more efficient and fast by using proper CUDA optimization.**

Indeed, I'm running on a GeForce GT 520M card and the timings are the following

1) For `MEDIAN_DIMENSION`

of `3 x 3 = 0.027 seconds`

2) For `MEDIAN_DIMENSION`

of `5 x 5 = 0.206 seconds`

3) For `MEDIAN_DIMENSION`

of `7 x 7 = 1.11 seconds`

4) For `MEDIAN_DIMENSION`

of `9 x 9 = 4.931 seconds`

As you can see, as we increase `MEDIAN_DIMENSION`

, the time increases very much and I have applications where I generally use higher `MEDIAN_DIMENSION`

like `7 x 7`

and `9 x 9`

. I think that, by using Cuda, even for `9 x 9`

the time should be less than `1 second`

.

Since I think that the sorting part is taking most of the time here, can we make the sorting part of the algorithm faster?

Can we use `grid`

and `block`

more efficiently? Can I use larger `BLOCK_WIDTH`

and `BLOCK_HEIGHT`

(like `32`

and `32`

) and still not hit the maximum `__shared__`

memory limit which is `4Kb`

for my device?

Can `__shared__`

memory be used more efficiently?

Any help will be appreciated.

Thanks in advance.

shared_memory more efficiently. – Jony Oct 29 '13 at 9:25