Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I have a function A whose input is a numpy vector (numpy.ndarray) called x. This function calculates, for each element of x, the sum of that element itself with other elements of x given by a list of those elements.

The following example should illustrate this better:

x = [[2,3], [3,4], [1,2], [1,3], [1,4]] # my input
n = [[1,2,3], [0,4,2], [3,0,1], [0,1,4], [3,1,2]] # list with lists of element to be added for each element in x

So for the first element of x, which is x[0] = [2,3] I have to add the values given by n[0], so those are 1, 2 and 3. I obtain them by x[n[0][0]],x[n[0][1]] and x[n[0][2]].

The expected output for the example should be:

l = [[11, 18], [13, 21], [9, 16], [9, 20], [8, 21]]

The final sum for a element x[i] should be

(x[i] + x[n[i][0]] + x[i] + x[n[i][1]] + x[i] + x[n[i][2]])

The return of the function is the list with each calculated sum.

As this is iterative I move through both lists x and n. The following code achieve this but goes element by element in both lists x and n.

def A(x):
    a = []
    for i, x_i in enumerate(x):
        mysum = np.zeros(2)
        for j, n_j in enumerate(n[i]):
           mysum = mysum + x_i + x[n_j]
    return np.array(a)

I want to make this code more vectorial, but this is my best since some days ago.

Edit: If it is helpful, I always sum 3 values per element, so the sublists of n are always of lenght 3.

share|improve this question
nope haha thanks for the advice again – Alejandro Sazo May 25 '14 at 2:42
How the result came like that? Isn't it [2,3]+[3,4]+[2,3]+[1,2]+[2,3]+[1,3]=[11,18] for first element as per your equation of x[i] – Abid Rahman K May 25 '14 at 3:22
It can be done without for loop, but is the answer given in your question right? – Abid Rahman K May 25 '14 at 3:38
no, the code in the question is my approach – Alejandro Sazo May 25 '14 at 4:00
By the way, be more polite next time. – Alejandro Sazo May 25 '14 at 4:14
up vote 2 down vote accepted

You can at least remove the inner loop as follows:

def A(x, n):
    a = 3 * x
    for i in range(len(x)):
        a[i] += np.sum(x[np.ix_(n[i]-1)], axis=0)
    return a
share|improve this answer
Nice! it worked very good – Alejandro Sazo May 25 '14 at 3:26

(Please see the UPDATE at the end for simpler and faster solution)

This can be done without the for loop, by the technique of broadcasting

def C(x,n):
    y = x[n.ravel()-1]
    z = y.reshape((-1,3,2))
    xx = x[:,np.newaxis,:]
    ans = z+xx
    ans = ans.sum(axis=1)
    return ans

It is atleast 5-6x faster compared to the solution with for loop.

In [98]: np.all(A(x,n)==C(x,n))
Out[98]: True

In [95]: %timeit ans=A(x,n)
10000 loops, best of 3: 153 us per loop

In [96]: %timeit ans=C(x,n)
10000 loops, best of 3: 27 us per loop


Jaime has reduced my 6 lines of code into a simple 1-line code (check comments below), and it is 20% faster too.

ans = 3*x + x[n-1].sum(axis=1)
share|improve this answer
excellent! I was wondering how costly it would be to work with big arrays of size N * 3 * 2, but I guess I have my answer :) – noziar May 25 '14 at 4:16
Please explain x[n.ravel()-1]. – wwii May 25 '14 at 5:05
n.ravel() returns a flattened version of n. then apply -1. (But I have doubts regarding that, because it doesn't match with the question description. So I modelled my code based on accepted answer). Now, it becomes like x[[1,2,3,...]] which will return the row of x corresponding to each indices. – Abid Rahman K May 25 '14 at 5:22
3*x + x[n-1].sum(axis=1) does the same as your whole function, and is ~20% faster. And I too do not think the -1 is needed. – Jaime May 25 '14 at 5:23
Cool!!! please, put it as an answer... It will benefit newcomers... Or I can append this to my answer as an update... – Abid Rahman K May 25 '14 at 8:12

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.