# Fastest way to calculate the sum of specific regions of an array

Given the following data (in python 2.7):

``````import numpy as np
a = np.array([1,2,3,4,5,6,7,8,9,10,11,12,14])
b = np.array([8,2,3])
``````

I want to get the sum of the first 8 elements in `a`, then the sum of the 9 and 10 element and in the end the last 3 (basic the information in `b`). The desired output is:

``````[36, 19, 37]
``````

I can do this with for loops and such, but there must be a more pythonic way and a more efficient way of doing!

• You're using numpy. Use an array based solution. Numpy's sum and slice operations are far faster than anything in Python itself, though your data is too small to matter. Commented Aug 3, 2017 at 10:33

That's easy with `np.split`:

``````result = [part.sum() for part in np.split(a, np.cumsum(b))[:-1]]
print(result)
>>> [36, 19, 37]
``````
• If you care about performance - especially if these subarrays are small - then you should use `part.sum()` instead of `np.sum(part)`. Commented Aug 3, 2017 at 10:49
• you can also do this with `np.add.reduceat(a, np.cumsum(b)[:-1])` Commented Aug 3, 2017 at 10:56
• @MSeifert I'm taking your word for it and changing it in the answer, but do have a reference to a benchmark about it, or just some explanation? Commented Aug 3, 2017 at 10:59
• @DanielF That would make a fine answer on it's own :) (if it works) Commented Aug 3, 2017 at 11:00
• `np.sum` has much more overhead than calling the `sum` method directly. Commented Aug 3, 2017 at 11:09

A much faster way than `np.split` is:

``````np.add.reduceat(a, np.r_[0, np.cumsum(b)[:-1]])
``````

What this does:

1. Creates an array of ascending indices out of `b` corresponding to the ranges you want to sum over - for simplicity, you can assign `c = np.r_[0, np.cumsum(b)[:-1]]` which for your example would be `array([0, 8, 10])` - which is `0` followed all but the last element of the cumulative sum of `b` (`np.cumsum(b) -> array([8, 10, 13])` (the domain of `np.ufunc.reduceat` is exclusive of the endpoint, so we have to get rid of that `13`)
2. `np.ufunc.reduceat(a, c)` `reduce`s `a` by `ufunc` (in this case, `add`) over ranges specified by `c[i]:c[i+1]`. When `i+1` would overflow `c`, it instead `reduce`s over `c[i]:-1`
3. `reduce` just condenses an array to a single value. For example, `np.add.reduce(a)` is equivalent to (but slower than) `np.sum(a)` (which is in turn slower than `a.sum()`). However, since `reduceat` pushes the `for` loop in the answer by @jdehsa out of python and into `numpy` core compiled c-code, it is much faster.

Speed test:

``````b = np.random.randint(1,10,(10000,))
a = np.random.randint(1,10,(np.sum(b),))

1000 loops, best of 3: 293 µs per loop
%timeit [part.sum() for part in np.split(a, np.cumsum(b))[:-1]]
10 loops, best of 3: 44.6 ms per loop
``````

And with the added benefit of not wasting memory creating a temporary `split` copy of `a`

• Should have known something was up when @MSeifert started hedging "if it works." Fixed now. Commented Aug 3, 2017 at 11:09
• Can you explain a little bit more, what your solution does? It looks a little bit like magic ;) Commented Aug 3, 2017 at 12:56
• Check out `np.ufunc.reduceat`. `add` is one of the simplest of the `ufunc` family. Commented Aug 3, 2017 at 13:44

You can use the `reduceat` method of the `np.add` ufunc. You just need to add a zero in front of your indices and discard the last index (if it covers the complete array):

``````>>> import numpy as np
>>> a = np.array([1,2,3,4,5,6,7,8,9,10,11,12,14])
>>> b = np.array([8,2,3])
array([36, 19, 37], dtype=int32)
``````

The `[:-1]` discards the last index and the `np.append([0],` adds a zero in front of the indices.

If you don't like the `append` you could also create a new array yourself containing the indices:

``````>>> b_sum = np.zeros_like(b)
>>> np.cumsum(b[:-1], out=b_sum[1:])  # insert the cumsum in the b_sum array directly
array([36, 19, 37], dtype=int32)
``````
• if b is very large isn't that append expensive? Commented Aug 3, 2017 at 11:11
• Shouldn't be. It's only done once and over one dimension. Considering the overhead of all the indexing and adding it should be negligible Commented Aug 3, 2017 at 11:21
• @DiogoSantos It depends (it's done only once here so it's just an `O(n)` operation like all the other steps), I also included an approach that doesn't need the `append`. You might want to check which one is faster. :) Commented Aug 3, 2017 at 11:21

You can do that if you have to use the elements in b :

``````import numpy as np
a = np.array([1,2,3,4,5,6,7,8,9,10,11,12,14])
b = np.array([8,2,3])

c = np.array([np.sum(a[:b[0]]),np.sum(a[b[0]:b[0]+b[1]]),np.sum(a[-b[2]:])])
``````

A solution using numba

There is already a good pythonic answer from @Daniel F. I wan't to show a alternative less pythonic, but faster solution. You can use loops in Python, but if you wan't to get reasonable speed you have to use a compiler. Numba is very easy to use so I wan't to give an example here.

``````import numba as nb
import numpy as np
import time
def main():
b = np.random.randint(1,10,(10000,))
a = np.random.randint(1,10,(np.sum(b),))

nb_splitsum = nb.njit(nb.int32[:](nb.int32[:], nb.int32[:]),nogil=True)(splitsum)

t1=time.time()
for i in xrange(0,1000):
c=nb_splitsum(a,b)

print("Numba Solution")
print(time.time()-t1)

t1=time.time()
for i in xrange(0,1000):
print("Numpy Solution")
print(time.time()-t1)

def splitsum(a,b):
sum=np.empty(b.shape[0],dtype=np.int32)
ii=0
for i in range(0,b.shape[0]):
for j in range(0,b[i]):
sum[i]+=a[ii]
ii+=1
return sum

if __name__ == "__main__":
main()

#Output
Numba Solution
0.125
Numpy Solution
0.280999898911
``````

You have a compilation overhead of about 0.15s on my machine. But when the function is compiled, the solution shown above is about twice as fast than the pure numpy solution.