# 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. – Yann Vernier Aug 3 '17 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)`. – MSeifert Aug 3 '17 at 10:49
• you can also do this with `np.add.reduceat(a, np.cumsum(b)[:-1])` – Daniel F Aug 3 '17 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? – jdehesa Aug 3 '17 at 10:59
• @DanielF That would make a fine answer on it's own :) (if it works) – MSeifert Aug 3 '17 at 11:00
• `np.sum` has much more overhead than calling the `sum` method directly. – MSeifert Aug 3 '17 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`

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(,` 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? – Diogo Santos Aug 3 '17 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 – Daniel F Aug 3 '17 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. :) – MSeifert Aug 3 '17 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]),np.sum(a[b:b+b]),np.sum(a[-b:])])
``````

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,dtype=np.int32)
ii=0
for i in range(0,b.shape):
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.