# Speed up iteration over Numpy arrays / OpenCV cv2 image

I have 3 numpy arrays of shape > (500, 500). I am trying to iterate over them simultaneously. I have tried two different methods but both of them are slow.

Here `Ix_Ix_blur`, `Ix_Iy_blur` and `Iy_Iy_blur` are of the same size. I'm trying to find features and draw it on OpenCV image.

Method 1:

``````for i in xrange (Ix_Ix_blur.shape[1]):
for j in xrange(Ix_Ix_blur.shape[0]):
A = np.array([ [Ix_Ix_blur[j][i], Ix_Iy_blur[j][i]],
[Ix_Iy_blur[j][i], Iy_Iy_blur[j][i]] ])
detA = (A[0][0]*A[1][1])-(A[0][1]*A[1][0])
traceA = A[0][0]+A[1][1]

harmonic_mean = detA/traceA
if(harmonic_mean > thresh):
cv2.circle(img, (i,j), 1, (0, 0, 255), -1, 8)
``````

This takes around `7 seconds` for image of size of 512*512

Method 2:

``````Ix_Iy_blur_iter = np.nditer(Ix_Iy_blur)
Iy_Iy_blur_iter = np.nditer(Iy_Iy_blur)
Ix_Ix_blur_iter = np.nditer(Ix_Ix_blur)

while(not Ix_Iy_blur_iter.finished):
try:
A = np.array([[Ix_Ix_blur_iter.next(), Ix_Iy_blur_iter.next()],[Ix_Iy_blur_iter.value, Iy_Iy_blur_iter.next()]])
except StopIteration:
break
detA = (A[0][0]*A[1][1])-(A[0][1]*A[1][0])
traceA = A[0][0]+A[1][1]

harmonic_mean = detA/traceA
if(harmonic_mean > thresh):
i = Ix_Ix_blur_iter.iterindex/Ix.shape[0]
j = Ix_Ix_blur_iter.iterindex - Ix.shape[0]*i
cv2.circle(img, (j,i), 1, (0, 0, 255), -1, 8)
``````

This method also seems to take `7 seconds` to iterate over the same size of image.

Is there any other way using which I can reduce the time required for iterations?

Configuration:

• Ubuntu 12.04
• 3rd Gen core i5 processor
• 4 GB RAM
• 2 GB ATI RADEON GPU (which I have turned off)
-

First you can use `Ix_Ix_blur[j, i]` instead of `Ix_Ix_blur[j][i]`. `Ix_Ix_blur[j][i]` will create a temporary array which is very slow.

To speedup element access with ndarray, you can use item() method, which return python native numeric values, and you don't need to create a temporary array A. Calculation with native numeric values is faster than numpy scalars.

``````for i in xrange (Ix_Ix_blur.shape[1]):
for j in xrange(Ix_Ix_blur.shape[0]):
a, b, c = Ix_Ix_blur.item(j, i), Ix_Iy_blur.item(j, i), Iy_Iy_blur.item(j, i)
detA = a*c - b*b
traceA = a + c
harmonic_mean = detA/traceA
if harmonic_mean > thresh:
cv2.circle(img, (i,j), 1, (0, 0, 255), -1, 8)
``````

For your particular problem, it's not necessary to do the calculation in a loop, you can:

``````detA = Ix_Ix_blur * Iy_Iy_blur - Ix_Iy_blur**2
traceA = Ix_Ix_blur + Iy_Iy_blur
harmonic_mean = detA / traceA
for j, i in np.argwhere(harmonic_mean > thresh):
cv2.circle(img, (i,j), 1, (0, 0, 255), -1, 8)
``````
-
This is brilliant. I didn't think of doing it this way. Thanks for the answer. –  Froyo Feb 6 '13 at 13:42