# Vectorizing triple for loop in Python/Numpy with different array shapes

I am new in Python/Numpy and is trying to improve my triple for loop into a more efficient calculation, but can't quiet figure out how to do it.

The calculations is carried out on a grid of the size (25,35) and the shapes of arrays is:

`````` A = (8760,25,35)
B = (12,25,35)
``````

The first dimensions in A corresponds to the number hours in a year (~8760), and the first dimension in B is the number of months(12). I want to use the values in B[0,:,:] for the first month, and B[1,:,:] for the second etc.

So far I created, in a very unrefined way, a index array filled with 1,1,1...,2,2,2...,12 to extract the values from B. My code with some random numbers

``````    N,M = (25, 35)
A = np.random.rand(8760,N,M)
B = np.random.rand(12,N,M)
q = len(A)/12
index = np.hstack((np.full((1,q),1),np.full((1,q),2),np.full((1,q),3),np.full((1,q),4),np.full((1,q),5),np.full((1,q),6),np.full((1,q),7),np.full((1,q),8),np.full((1,q),9),np.full((1,q),10),np.full((1,q),11),np.full((1,q),12)))-1
results = np.zeros((len(A),N,M))

for t in xrange(len(A)):
for i in xrange(N):
for j in xrange(M):
results[t][i][j] = some_function(A[t][i][j], B[index[(0,t)]][i][j],H = 80.)

def some_function(A,B,H = 80.0):
results = A*np.log(H/B)/np.log(10./B)
return results
``````

How can increase the speed of this calculation?

• Can you share details about `some_function`? Because for real vectorization, that function being buried deep inside the nested loops has to come out of the loops and that would depend on its implementation. – Divakar Sep 24 '15 at 8:05
• I have edited the question to include the function! I appreciate your help! – HolmN Sep 24 '15 at 8:19
• `index` being a 1D array would throw error at `index[(0,t)][i][j]`, because `index[(0,t)]` would be a scalar. – Divakar Sep 24 '15 at 8:24
• I think your code needs few changes : 1) `index` has to be subtracted by `1`. 2) Initalization of results be changed to `results = np.zeros((len(A),N,M))`. 3) `B[index[(0,t)][i][j]]` be changed to `B[index[(0,t)]][i][j]`. – Divakar Sep 24 '15 at 8:47
• Thank for the remarks, I have updated the code. How would you continue from here to vectorize the loop? – HolmN Sep 24 '15 at 8:58

NumPy suports `broadcasting` that allows elementwise operations to be performed across different shaped arrays in a highly optimized manner. In your case, you have the number of rows and columns in `A` and `B` the same. But, at the first dimension, the number of elements are different across these two arrays. Looking at the implementation, it seems `B` 's first dimension elements are repeated per `q` number until we go over to the next element in it's first dimension. This coincides with the fact that the number of elements in first dimension of `B` is `q` times the number of elements in first dimension of `A`.

Now, going back to `broadcasting`, the solution would be to split the first dimension of `A` to have a 4D array, such that we have the number of elements in the first dimension of this reshaped 4D array matching up with the number of elements in B's first dimension. Next up, `reshape` `B` to a 4D array as well by creating singleton dimension (dimension with no elements) at the second dimension with `B[:,None,:,:]`. Then, NumPy would use broadcasting magic and perform broadcasted elementwise multiplications, as that's what we are doing in our `some_function`.

Here's the vectorized implementation using `NumPy's broadcasting` capability -

``````H = 80.0
M,N,R = B.shape
B4D = B[:,None,:,:]
out = ((A.reshape(M,-1,N,R)*np.log(H/B4D))/np.log(10./B4D)).reshape(-1,N,R)
``````

Runtime tests and output verification -

``````In [50]: N,M = (25, 35)
...: A = np.random.rand(8760,N,M)
...: B = np.random.rand(12,N,M)
...: H = 80.0
...:

In [51]: def some_function(A,B,H = 80.0):
...:     return A*np.log(H/B)/np.log(10./B)
...:

In [52]: def org_app(A,B,H):
...:    q = len(A)/len(B)
...:    index = np.repeat(np.arange(len(B))[:,None],q,axis=1).ravel()[None,:] # Simpler
...:    results = np.zeros((len(A),N,M))
...:    for t in xrange(len(A)):
...:        for i in xrange(N):
...:            for j in xrange(M):
...:                results[t][i][j] = some_function(A[t][i][j], B[index[(0,t)]][i][j])
...:    return results
...:

In [53]: def vectorized_app(A,B,H):
...:    M,N,R = B.shape
...:    B4D = B[:,None,:,:]
...:    return ((A.reshape(M,-1,N,R)*np.log(H/B4D))/np.log(10./B4D)).reshape(-1,N,R)
...:

In [54]: np.allclose(org_app(A,B,H), vectorized_app(A,B,H))
Out[54]: True

In [55]: %timeit org_app(A,B,H)
1 loops, best of 3: 1min 32s per loop

In [56]: %timeit vectorized_app(A,B,H)
10 loops, best of 3: 217 ms per loop
``````