# Rotate blocks/windows in 3D array efficiently (Vectorized diffusion?)

I have a large 3D `np.array` with let us say with size(200,200,7).

I would like to apply the `np.rot90` for every 2*2 sub-array on the first to axes. The other issue is to rotate every sub-array in a random manner. Like this:

The colors are just for showing the distinct 2*2 arrays, arrows illustrating that every array is rotated based on a random number generated for as an argument in `numpy.rot90(m, k=RND(1,2,3), axes=(0, 1))`.

Is this possible in a single fast step, without for looping on every individual sub-array?

Based on Divakar's answer I also attempted to make an extenson where only x percent of the subarrays move in one step, the rest are left unchanged, this hopefully behaves likea 2D diffusion system.

``````def vectorized_diffusion(a,H,W,pD):
#pD - chance that a sub-array is rotated in a random direction
rand_shift = np.random.randint(-1,2)
rand_axis = np.random.randint(0,2)
a = np.roll(a, shift = randshift, axis = rand_axis)
# Since the 2*2 subgrid system is fixed, I decided to ocassionally
#disturb the grid by rolling the whole array by one in a given
#direction, as in my work the array is a toroid grid i considered every direction
m,n,r = a.shape
a5D = a.reshape(m//H,H,n//W,W,-1)
cw0 = a5D[:,::-1,:,:,:].transpose(0,2,3,1,4)
ccw0 = a5D[:,:,:,::-1,:].transpose(0,2,3,1,4)
original = a5D[:,:,:,:,:].transpose(0,2,1,3,4)
out = out.swapaxes(1,2).reshape(a.shape)
out_rerolled = np.roll(out, shift = -1*randshift, axis = rand_axis)
#this way the disturbed grid is rerolled into its original position
return out_rerolled
``````

I know this is probably not the most elegant solution to sort this out, but it seems to work and I am fine with that.

### Generic way to perform rotation (clockwise and anti-clockwise) with flipping and permuting axes -

``````# Input array
In [176]: k
Out[176]:
array([[26, 48, 71],
[54, 96, 82],
[87, 21,  2]])

# Clockwise
In [178]: k[::-1,:].T
Out[178]:
array([[87, 54, 26],
[21, 96, 48],
[ 2, 82, 71]])

# Anti-clockwise
In [177]: k[:,::-1].T
Out[177]:
array([[71, 82,  2],
[48, 96, 21],
[26, 54, 87]])
``````

### Extend to `2D` array with windowed rotations

``````In [204]: np.random.seed(0)

In [205]: a = np.random.randint(0,100,(6,6))

In [206]: a
Out[206]:
array([[44, 47, 64, 67, 67,  9],
[83, 21, 36, 87, 70, 88],
[88, 12, 58, 65, 39, 87],
[46, 88, 81, 37, 25, 77],
[72,  9, 20, 80, 69, 79],
[47, 64, 82, 99, 88, 49]])

# Clockwise
In [207]: a.reshape(3,2,3,2)[:,::-1,:,:].swapaxes(1,3).reshape(a.shape)
Out[207]:
array([[83, 44, 36, 64, 70, 67],
[21, 47, 87, 67, 88,  9],
[46, 88, 81, 58, 25, 39],
[88, 12, 37, 65, 77, 87],
[47, 72, 82, 20, 88, 69],
[64,  9, 99, 80, 49, 79]])

# Anti-clockwise
In [209]: a.reshape(3,2,3,2)[:,:,:,::-1].swapaxes(1,3).reshape(a.shape)
Out[209]:
array([[47, 21, 67, 87,  9, 88],
[44, 83, 64, 36, 67, 70],
[12, 88, 65, 37, 87, 77],
[88, 46, 58, 81, 39, 25],
[ 9, 64, 80, 99, 79, 49],
[72, 47, 20, 82, 69, 88]])
``````

### Extend to `3D` array with windowed rotations across each 2D slice -

``````In [223]: a = np.random.randint(0,100,(6,6,2))

# Clockwise
In [224]: cw = a.reshape(3,2,3,2,2)[:,::-1,:,:,:].swapaxes(1,3).reshape(a.shape)

# Anti-clockwise
In [233]: ccw = a.reshape(3,2,3,2,2)[:,:,:,::-1,:].swapaxes(1,3).reshape(a.shape)

In [225]: a[...,0]
Out[225]:
array([[44, 64, 67, 83, 36, 70],
[88, 58, 39, 46, 81, 25],
[72, 20, 69, 47, 82, 88],
[29, 19, 39, 65, 57, 31],
[23, 75, 28,  0, 36,  5],
[17,  4, 58,  1, 41, 35]])

In [226]: cw[...,0]
Out[226]:
array([[88, 44, 39, 67, 81, 36],
[58, 64, 46, 83, 25, 70],
[29, 72, 39, 69, 57, 82],
[19, 20, 65, 47, 31, 88],
[17, 23, 58, 28, 41, 36],
[ 4, 75,  1,  0, 35,  5]])

In [236]: ccw[...,0]
Out[236]:
array([[64, 58, 83, 46, 70, 25],
[44, 88, 67, 39, 36, 81],
[20, 19, 47, 65, 88, 31],
[72, 29, 69, 39, 82, 57],
[75,  4,  0,  1,  5, 35],
[23, 17, 28, 58, 36, 41]])
``````

### Solving our case to choose between these two with a mask

We need to make it work for our case. We will use a mask to choose between clockwise and anti-clockwise versions -

``````cw0 = a.reshape(3,2,3,2,2)[:,::-1,:,:,:].swapaxes(1,3)
ccw0 = a.reshape(3,2,3,2,2)[:,:,:,::-1,:].swapaxes(1,3)
``````

We could optimize/ make it more compact -

``````cw0 = a.reshape(3,2,3,2,2)[:,::-1,:,:,:].transpose(0,2,3,1,4)
ccw0 = a.reshape(3,2,3,2,2)[:,:,:,::-1,:].transpose(0,2,3,1,4)
``````

Finally, let's make it handle generic cases -

``````def random_rotate_windows(a,H,W):
m,n,r = a.shape
a5D = a.reshape(m//H,H,n//W,W,-1)
cw0 = a5D[:,::-1,:,:,:].transpose(0,2,3,1,4)
ccw0 = a5D[:,:,:,::-1,:].transpose(0,2,3,1,4)
return out.swapaxes(1,2).reshape(a.shape)
``````

Ending with a sample run -

``````In [332]: np.random.seed(0)
...: a = np.random.randint(0,100,(6,6,2))

In [333]: a[...,0]
Out[333]:
array([[44, 64, 67, 83, 36, 70],
[88, 58, 39, 46, 81, 25],
[72, 20, 69, 47, 82, 88],
[29, 19, 39, 65, 57, 31],
[23, 75, 28,  0, 36,  5],
[17,  4, 58,  1, 41, 35]])

In [334]: out = random_rotate_windows(a,2,2)

In [335]: out[...,0]
Out[335]:
array([[64, 58, 83, 46, 81, 36],
[44, 88, 67, 39, 25, 70],
[20, 19, 47, 65, 57, 82],
[72, 29, 69, 39, 31, 88],
[17, 23,  0,  1, 41, 36],
[ 4, 75, 28, 58, 35,  5]])
``````
• Wow, I am still trying to grasp what is going on here exactly, but this seems pretty much what I needed. Thank you! – Commander Shepard Feb 28 at 13:25
• Another question: Is it possible to rework this into a function, where only the x percent of the 2*2 sub-arrays are rotated, while the other 100-x percent remains the same? This way I would basically get a diffusion-like behavior, where the rate of diffusion could be controlled. Maybe i should use another mask telling where is happening the rotation – Commander Shepard Mar 2 at 10:35