I've tried to replicate the main bottleneck in one of my programs.

I want to get the linearly (or rather bilinearly) interpolated values of several non-integer pixel values simultaneously. It is *not* the case that each pixel coordinate is perturbed in the same way. Below is a complete/minimal script along with comments that demonstrates the problem. How can I speed up the calculation of `result`

?

```
import numpy as np
import time
im = np.random.rand(640,480,3) # my "image"
xx, yy = np.meshgrid(np.arange(im.shape[1]), np.arange(im.shape[0]))
print "Check these are the right indices:",np.sum(im - im[yy,xx,:])
# perturb the indices slightly
# I want to calculate the interpolated
# values of "im" at these locations
xx = xx + np.random.normal(size=im.shape[:2])
yy = yy + np.random.normal(size=im.shape[:2])
# integer value/pixel locations
x_0 = np.int_(np.modf(xx)[1])
y_0 = np.int_(np.modf(yy)[1])
x_1, y_1 = x_0 + 1, y_0 + 1
# the real-valued offsets/coefficients pixels
a = np.modf(xx)[0][:,:,np.newaxis]
b = np.modf(yy)[0][:,:,np.newaxis]
# make sure we don't go out of bounds at edge pixels
np.clip(x_0,0,im.shape[1]-1,out=x_0)
np.clip(x_1,0,im.shape[1]-1,out=x_1)
np.clip(y_0,0,im.shape[0]-1,out=y_0)
np.clip(y_1,0,im.shape[0]-1,out=y_1)
# now perform linear interpolation: THIS IS THE BOTTLENECK!
tic = time.time()
result = ((1-a) * (1-b) * im[y_0, x_0, :] +
a * (1-b) * im[y_1, x_0, :] +
(1-a) * b * im[y_0, x_1, :] +
a * b * im[y_1, x_1, :] )
toc = time.time()
print "interpolation time:",toc-tic
```

`scipy.ndimage.map_coordinates`

? (E.g. wanting to avoid a dependency on scipy.ndimage?) If not, it's the function you want. – Joe Kington Feb 23 '12 at 16:24