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I was deriving NDVI (Normalized Difference Vegetation Index), which is a ratio of (NIR-R)/(NIR+R) where NIR is Near-Infrared band and R is Red band. This index ranges from -1 to 1. So I wrote a pyopencl code and here is what I have done and observed.

Python code:

import pyopencl as cl
import cv2
from PIL import Image
import numpy as np
from time import time
import matplotlib.pyplot as plt


#get kernel file
def getKernel():
    kernel = open('kernel.c').read()
    return kernel

#return images as numpy int32 arrays
def convToArray(im_r,im_nir):
    a = np.asarray(im_r).astype(np.int32)
    b = np.asarray(im_nir).astype(np.int32)

    return a,b

#processing part
def getDerivation(platform,device,im_r,im_nir):

    #setting device
    pltfrm = cl.get_platforms()[platform]
    dev = pltfrm.get_devices()[device]
    cntx = cl.Context([dev])
    queue = cl.CommandQueue(cntx)

    #get 2Darrays
    r,nir = convToArray(im_r,im_nir)

    #shape of array
    x = r.shape[1]

    mf = cl.mem_flags

    bs = time()

    #input images buffer
    inR = cl.Buffer(cntx,mf.READ_ONLY | mf.COPY_HOST_PTR,hostbuf=r)
    inIR = cl.Buffer(cntx,mf.READ_ONLY | mf.COPY_HOST_PTR,hostbuf=nir)

    #output image buffers
    ndvi = cl.Buffer(cntx,mf.WRITE_ONLY,r.nbytes)

    be = time()
    print("Buffering time: " + str(be-bs) + " sec")
    ts = time()

    #load kernel
    task = cl.Program(cntx,getKernel()%(x)).build()

    #execute the process
    task.derive(queue,r.shape,None,inR,inIR,ndvi)

    #create empty buffer to store result
    Vout = np.empty_like(r)

    #dump output buffers to empty arrays
    cl.enqueue_copy(queue,Vout,ndvi)

    te = time()

    #convert arrays to gray - image compatible formate
    NDVI = Vout.astype(np.uint8)

    print("Processing time: " + str(te - ts) + " On: " + pltfrm.name + " --> " + dev.name)

    return NDVI

def process(platform,device,im_r,im_nir):
    NDVI,NDBI,NDWI = getDerivation(platform,device,im_g,im_r,im_nir,im_swir)
    print(NDVI)
    cv2.imshow("NDVI",NDVI)
    cv2.waitKey(0)

if __name__ == '__main__':

    R = cv2.imread("BAND3.jpg",0)
    NIR = cv2.imread("BAND4.jpg",0)

    print(R.dtype) #returns uint8

    process(0,0,R,NIR) #(0,0) is my intel gpu

kernel code(C):

__kernel void derive(__global int* inR,__global int* inIR,__global int* ndvi){

    int x = get_global_id(0);
    int y = get_global_id(1);

    int width = %d;
    int index = x + y*width;

    //ndvi ratio (-1 to 1)

    int a = ((inIR[index] - inR[index])/(inIR[index] + inR[index])) * (256);

    a = (a <   (0) ?   (-1*a)  :   (a));
    a = (a >   (255) ?   (255) :   (a));

    ndvi[index] = (a);

}

input image R:Red band image

input image NIR: Near-Infrared image

both the images have bit depth of 8

BUT I GET JUST A BLANK IMAGE. I wrote the result on the command line for debugging reasons initially, command line output:

(1151, 1151)
Buffering time: 0.015959739685058594 sec
Processing time: 0.22115755081176758 On: Intel(R) OpenCL --> Intel(R) HD Graphics 520
[[0 0 0 ... 0 0 0]
 [0 0 0 ... 0 0 0]
 [0 0 0 ... 0 0 0]
 ...
 [0 0 0 ... 0 0 0]
 [0 0 0 ... 0 0 0]
 [0 0 0 ... 0 0 0]]

Now what i think is i may not be using proper datatype for the images? also, in the kernel the line ((inIR[index] - inR[index])/(inIR[index] + inR[index])) will gives a float value, which i multiply with 256 to get a pixel value for that respective float value. So is it there the problem? Does any one know where i am going wrong?

Help is much appreciated!

  • 1
    Why do you think you'll get a float? You'll get an int. Try casting the top or bottom to float before dividing. – Mark Setchell Jun 2 at 7:44
  • @MarkSetchell float num = (inIR[index] - inR[index]); float deno = (inIR[index] + inR[index]); int a = (int)((num/deno) * (256)); is this you talking about ? – Sajil Jun 2 at 7:53
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    Also, you probably don't want to multiply NDVI, which is in the range [-1,+1] by 256. You'd probably add 1 to bring it to range [0,2] and multiply by 127.5 to bring it to range [0,255]. – Mark Setchell Jun 2 at 7:54
  • float num = (float)(inIR[index] - inR[index]); float deno = (float)(inIR[index] + inR[index]); int a = (int)(((num/deno)+1)*127.5); i did this, but the result is the same... blank array. Is it what you were talking about BTW ? – Sajil Jun 2 at 7:59
  • I can't try it for the moment, but try just using straight Numpy to compare. It's just one line NDVI = (im_nir.astype(np.float)-im_r.astype(np.float))/... then look at NDVI.max() and NDVI.min(). – Mark Setchell Jun 2 at 8:09
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Okay ... i got it. I just changed the datatype in the line a = np.asarray(im_r).astype(np.int32) in the function convToArray() to float32 and in the kernel file, i changed the parameter type to float and added int a = (int)((((float)(inIR[index] - inR[index])/(float)(inIR[index] + inR[index]))+1)*127.5); for the calculation. However, i need an explaination, why this worked and not the other way... I probably can think like, the result what we get after this calculation, int type loses data while conversion from float...is it?

| improve this answer | |
  • int can only hold whole numbers... i.e. integers. There are only 3 integers in your range [-1,1] which are -1, 0 and 1. All fractional stuff gets lost. – Mark Setchell Jun 2 at 13:29

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