# numpy vectorization instead of for loops

I wrote some code in Python which works fine but is very slow; I think due to the for loops. I hope one can speed up the following operations using numpy commands. Let me define the goal.

Let's assume I have a 2D numpy array `all_CMs` of dimensions `row` x `col`. For instance consider a `6`x`11` array (see drawing below).

1. I want to calculate the mean for all rows, i.e. sumⱼ aᵢⱼ resulting in an array. This, of course can be easily done. (I call this value `CM_tilde`)

2. Now, for each row I want to calculate the mean of some selected values, namely all values below a certain threshold by computing their sum and dividing it by the number of all columns (`N`). If the value is above this defined threshold, the `CM_tilde` value (mean of the entire row) is added. This value is called `CM`

3. Afterwards, the `CM` value is subtracted from each element in the row

In addition to this I want to have a numpy array or list where all those `CM` values are listed.

The figure:

The following code is working but very slow (especially if the arrays getting large)

``````CM_tilde = np.mean(data, axis=1)
N = data.shape[1]
data_cm = np.zeros(( data.shape[0], data.shape[1], data.shape[2] ))
all_CMs = np.zeros(( data.shape[0], data.shape[2]))
for frame in range(data.shape[2]):
for row in range(data.shape[0]):
CM=0
for col in range(data.shape[1]):
if data[row, col, frame] < (CM_tilde[row, frame]+threshold):
CM += data[row, col, frame]
else:
CM += CM_tilde[row, frame]
CM = CM/N
all_CMs[row, frame] = CM
# calculate CM corrected value
for col in range(data.shape[1]):
data_cm[row, col, frame] = data[row, col, frame] - CM
print "frame: ", frame
return data_cm, all_CMs
``````

Any ideas?

• In step 2, do you essentially replace any value that is above the treshold by CM_tilde, and then calculate the mean over the entire row, including the replaced values? – user707650 Nov 18 '15 at 23:48
• Start by using `np.where` to replace your inner for loop. Then, using broadcasting, you can remove the outer 2 loops. See the documentation for where – mtadd Nov 19 '15 at 0:00

It's quite easy to vectorize what you're doing:

``````import numpy as np

#generate dummy data
nrows=6
ncols=11
nframes=3
threshold=0.3
data=np.random.rand(nrows,ncols,nframes)

CM_tilde = np.mean(data, axis=1)
N = data.shape[1]

all_CMs2 = np.mean(np.where(data < (CM_tilde[:,None,:]+threshold),data,CM_tilde[:,None,:]),axis=1)
data_cm2 = data - all_CMs2[:,None,:]
``````

``````In [684]: (data_cm==data_cm2).all()
Out[684]: True

In [685]: (all_CMs==all_CMs2).all()
Out[685]: True
``````

The logic is that we work with arrays of size `[nrows,ncols,nframes]` simultaneously. The main trick is to make use of python's broadcasting, by turning `CM_tilde` of size `[nrows,nframes]` into `CM_tilde[:,None,:]` of size `[nrows,1,nframes]`. Python will then use the same values for each column, since that is a singleton dimension of this modified `CM_tilde`.

By using `np.where` we choose (based on the `threshold`) whether we want to get the corresponding value of `data`, or, again, the broadcast value of `CM_tilde`. A new use of `np.mean` allows us to compute `all_CMs2`.

In the final step we made use of broadcasting by directly subtracting this new `all_CMs2` from the corresponding elements of `data`.

It might help in vectorizing code this way by looking at the implicit indices of your temporary variables. What I mean is that your temporary variable `CM` lives inside a loop over `[nrows,nframes]`, and its value is reset with each iteration. This means that `CM` is in effect a quantity `CM[row,frame]` (later explicitly assigned to the 2d array `all_CMs`), and from here it's easy to see that you can construct it by summing up an appropriate `CMtmp[row,col,frames]` quantity along its column dimension. If it helps, you can name the `np.where(...)` part as `CMtmp` for this purpose, and then compute `np.mean(CMtmp,axis=1)` from that. Same result, obviously, but probably more transparent.

• Thank you very much; this is much much faster compared to the loops – pallago Nov 19 '15 at 21:10
• 10001 is a nice value for rep, It would be a shame if someone downvotes this. – Bhargav Rao Jun 29 '16 at 21:31
• @BhargavRao \o/ thank you, sir!:) Or, thank you for not downvoting:D – Andras Deak Jun 29 '16 at 21:34

Here's my vectorization of your function. I worked from the inside out, and commented out earlier versions as I went along. So the first loop that I vectorized has `###` comment marks.

It isn't as clean and well reasoned as `@Andras's` answer, but hopefully it is instructional, giving an idea of how you can address this issue incrementally.

``````def foo2(data, threshold):
CM_tilde = np.mean(data, axis=1)
N = data.shape[1]
#data_cm = np.zeros(( data.shape[0], data.shape[1], data.shape[2] ))
##all_CMs = np.zeros(( data.shape[0], data.shape[2]))
bmask = data < (CM_tilde[:,None,:] + threshold)
CM = np.zeros_like(data)
CM[:] = CM_tilde[:,None,:]
CM = CM.sum(axis=1)
CM = CM/N
all_CMs = CM.copy()
"""
for frame in range(data.shape[2]):
for row in range(data.shape[0]):
###print(frame, row)
###mask = data[row, :, frame] < (CM_tilde[row, frame]+threshold)

##CM = CM/N
##all_CMs[row, frame] = CM
## calculate CM corrected value
#for col in range(data.shape[1]):
#    data_cm[row, col, frame] = data[row, col, frame] - CM[row,frame]
print "frame: ", frame
"""
data_cm = data - CM[:,None,:]
return data_cm, all_CMs
``````

Output matches for this small test case, which more than anything helped me get the dimensions right.

``````threshold = .1
data = np.arange(4*3*2,dtype=float).reshape(4,3,2)
``````