I have an image processing problem I'm currently solving in python, using numpy and scipy. Briefly, I have an image that I want to apply many local contractions to. My prototype code is working, and the final images look great. However, processing time has become a serious bottleneck in our application. Can you help me speed up my image processing code?

I've tried to boil down our code to the 'cartoon' version below. Profiling suggests that I'm spending most of my time on interpolation. Are there obvious ways to speed up execution?

```
import cProfile, pstats
import numpy
from scipy.ndimage import interpolation
def get_centered_subimage(
center_point, window_size, image):
x, y = numpy.round(center_point).astype(int)
xSl = slice(max(x-window_size-1, 0), x+window_size+2)
ySl = slice(max(y-window_size-1, 0), y+window_size+2)
subimage = image[xSl, ySl]
interpolation.shift(
subimage, shift=(x, y)-center_point, output=subimage)
return subimage[1:-1, 1:-1]
"""In real life, this is experimental data"""
im = numpy.zeros((1000, 1000), dtype=float)
"""In real life, this mask is a non-zero pattern"""
window_radius = 10
mask = numpy.zeros((2*window_radius+1, 2*window_radius+1), dtype=float)
"""The x, y coordinates in the output image"""
new_grid_x = numpy.linspace(0, im.shape[0]-1, 2*im.shape[0])
new_grid_y = numpy.linspace(0, im.shape[1]-1, 2*im.shape[1])
"""The grid we'll end up interpolating onto"""
grid_step_x = new_grid_x[1] - new_grid_x[0]
grid_step_y = new_grid_y[1] - new_grid_y[0]
subgrid_radius = numpy.floor(
(-1 + window_radius * 0.5 / grid_step_x,
-1 + window_radius * 0.5 / grid_step_y))
subgrid = (
window_radius + 2 * grid_step_x * numpy.arange(
-subgrid_radius[0], subgrid_radius[0] + 1),
window_radius + 2 * grid_step_y * numpy.arange(
-subgrid_radius[1], subgrid_radius[1] + 1))
subgrid_points = ((2*subgrid_radius[0] + 1) *
(2*subgrid_radius[1] + 1))
"""The coordinates of the set of spots we we want to contract. In real
life, this set is non-random:"""
numpy.random.seed(0)
num_points = 10000
center_points = numpy.random.random(2*num_points).reshape(num_points, 2)
center_points[:, 0] *= im.shape[0]
center_points[:, 1] *= im.shape[1]
"""The output image"""
final_image = numpy.zeros(
(new_grid_x.shape[0], new_grid_y.shape[0]), dtype=numpy.float)
def profile_me():
for m, cp in enumerate(center_points):
"""Take an image centered on each illumination point"""
spot_image = get_centered_subimage(
center_point=cp, window_size=window_radius, image=im)
if spot_image.shape != (2*window_radius+1, 2*window_radius+1):
continue #Skip to the next spot
"""Mask the image"""
masked_image = mask * spot_image
"""Resample the image"""
nearest_grid_index = numpy.round(
(cp - (new_grid_x[0], new_grid_y[0])) /
(grid_step_x, grid_step_y))
nearest_grid_point = (
(new_grid_x[0], new_grid_y[0]) +
(grid_step_x, grid_step_y) * nearest_grid_index)
new_coordinates = numpy.meshgrid(
subgrid[0] + 2 * (nearest_grid_point[0] - cp[0]),
subgrid[1] + 2 * (nearest_grid_point[1] - cp[1]))
resampled_image = interpolation.map_coordinates(
masked_image,
(new_coordinates[0].reshape(subgrid_points),
new_coordinates[1].reshape(subgrid_points))
).reshape(2*subgrid_radius[1]+1,
2*subgrid_radius[0]+1).T
"""Add the recentered image back to the scan grid"""
final_image[
nearest_grid_index[0]-subgrid_radius[0]:
nearest_grid_index[0]+subgrid_radius[0]+1,
nearest_grid_index[1]-subgrid_radius[1]:
nearest_grid_index[1]+subgrid_radius[1]+1,
] += resampled_image
cProfile.run('profile_me()', 'profile_results')
p = pstats.Stats('profile_results')
p.strip_dirs().sort_stats('cumulative').print_stats(10)
```

Vague explanation of what the code does:

We start with a pixellated 2D image, and a set of arbitrary (x, y) points in our image that don't generally fall on an integer grid. For each (x, y) point, I want to multiply the image by a small mask centered *precisely* on that point. Next we contract/expand the masked region by a finite amount, before finally adding this processed sub-image to a final image, which may not have the same pixel size as the original image. (Not my finest explanation. Ah well).

give this a try. – Mike Dunlavey Nov 16 '11 at 22:02