# Python vectorizing nested for loops

I'd appreciate some help in finding and understanding a pythonic way to optimize the following array manipulations in nested for loops:

``````def _func(a, b, radius):
"Return 0 if a>b, otherwise return 1"
return 1
else:
return 0

for x in range(volume.shape[0]):
for y in range(volume.shape[1]):
for z in range(volume.shape[2]):
``````

Where `volume.shape` (182, 218, 200) and `roi.shape` (3,) are both `ndarray` types; and `radius` is an `int`

• Did any of these answers help? Relevant page to read: How does accepting an answer work? Commented Oct 18, 2016 at 21:23
• please excuse the necropost, but A: you should accept @Divakar's post.. It's a wonderful demonstration of vectorizing with numpy, and B: you should take a look at KD trees and the ball point algorithm from `scipy.spatial`. It is a generalizable method for your specific problem when the data is sparse or not on a regular grid. Although it's not the best method for this exact question, It's a very good thing to know about (I recently used it myself) Commented Dec 16, 2016 at 22:39
• @Divakar your explanation was very helpful, thanks. I upvoted initially, but just recently realized purpose of the checkmark. It's done. Commented May 9, 2017 at 19:08

Approach #1

Here's a vectorized approach -

``````m,n,r = volume.shape
x,y,z = np.mgrid[0:m,0:n,0:r]
X = x - roi[0]
Y = y - roi[1]
Z = z - roi[2]
``````

Possible improvement : We can probably speedup the last step with `numexpr` module -

``````import numexpr as ne

``````

Approach #2

We can also gradually build the three ranges corresponding to the shape parameters and perform the subtraction against the three elements of `roi` on the fly without actually creating the meshes as done earlier with `np.mgrid`. This would be benefited by the use of `broadcasting` for efficiency purposes. The implementation would look like this -

``````m,n,r = volume.shape
vals = ((np.arange(m)-roi[0])**2)[:,None,None] + \
((np.arange(n)-roi[1])**2)[:,None] + ((np.arange(r)-roi[2])**2)
``````

Simplified version : Thanks to @Bi Rico for suggesting an improvement here as we can use `np.ogrid` to perform those operations in a bit more concise manner, like so -

``````m,n,r = volume.shape
x,y,z = np.ogrid[0:m,0:n,0:r]-roi
``````

Runtime test

Function definitions -

``````def vectorized_app1(volume, roi, radius):
m,n,r = volume.shape
x,y,z = np.mgrid[0:m,0:n,0:r]
X = x - roi[0]
Y = y - roi[1]
Z = z - roi[2]
return X**2 + Y**2 + Z**2 < radius**2

m,n,r = volume.shape
x,y,z = np.mgrid[0:m,0:n,0:r]
X = x - roi[0]
Y = y - roi[1]
Z = z - roi[2]
return ne.evaluate('X**2 + Y**2 + Z**2 < radius**2')

m,n,r = volume.shape
vals = ((np.arange(m)-roi[0])**2)[:,None,None] + \
((np.arange(n)-roi[1])**2)[:,None] + ((np.arange(r)-roi[2])**2)

m,n,r = volume.shape
x,y,z = np.ogrid[0:m,0:n,0:r]-roi
``````

Timings -

``````In [106]: # Setup input arrays
...: volume = np.random.rand(90,110,100) # Half of original input sizes
...: roi = np.random.rand(3)
...:

1 loops, best of 3: 41.4 s per loop

In [108]: %timeit vectorized_app1(volume, roi, radius)
10 loops, best of 3: 62.3 ms per loop

In [109]: %timeit vectorized_app1_improved(volume, roi, radius)
10 loops, best of 3: 47 ms per loop

In [110]: %timeit vectorized_app2(volume, roi, radius)
100 loops, best of 3: 4.26 ms per loop

In [139]: %timeit vectorized_app2_simplified(volume, roi, radius)
100 loops, best of 3: 4.36 ms per loop
``````

So, as always `broadcasting` showing its magic for a crazy almost `10,000x` speedup over the original code and more than `10x` better than creating meshes by using on-the-fly broadcasted operations!

• Approach #2 is a lot like approach one with np.ogrid replacing np.mgrid. Commented Sep 23, 2016 at 18:54
• Can we get a timing of 'app1' with `ogrid` instead of `mgrid` :). Commented Sep 23, 2016 at 19:14
• @BiRico Why instead, when we can get everything :) Thanks a lot for the improvement there, looks much cleaner now! Commented Sep 23, 2016 at 19:18

Say you first build an `xyzy` array:

``````import itertools

xyz = [np.array(p) for p in itertools.product(range(volume.shape[0]), range(volume.shape[1]), range(volume.shape[2]))]
``````

Now, using `numpy.linalg.norm`,

``````np.linalg.norm(xyz - roi, axis=1) < radius
``````

checks whether the distance for each tuple from `roi` is smaller than radius.

Finally, just `reshape` the result to the dimensions you need.