# fastest way to find smallest sum of length n subsequences in python

given a list `L`, what is the fastest method to find all consecutive length `n` subsequences, and find the index of the smallest sum. Here is my (slow) version:

``````from random import randrange
import numpy as np
L = np.array([randrange(-5000, 5000) for _ in range(10 * 10**6)])   #random array
subarray_length = 3                                                 #for example
sublist_sums = [sum(L[i:i+subarray_length]) for i
in range(0, len(L) - (subarray_length - 1))]

candidate_idx = 0
candidate_sum = sublist_sums[0]

for idx, val in enumerate(sublist_sums[1:]):
if val < candidate_sum:
candidate_sum, candidate_idx = val, idx + 1

print(candidate_idx)
``````

MWE:

``````L = [6,5,4,3,2,1]

# sublists: [[6,5,4], [5,4,3], [4,3,2], [3,2,1] ]

subarray_length = 3
sublist_sums = [sum(L[i:i+subarray_length]) for i
in range(0, len(L) - (subarray_length - 1))]

# sublist_sums = [15, 12, 9, 6]

for idx, val in enumerate(sublist_sums[1:]):
if val < candidate_sum:
candidate_sum, candidate_idx = val, idx + 1

candidate_idx = 3

# 3 is the index of the first element of the length 3 sublist
# with the smallest sum of all 3 length consecutive sublists
``````

Here's one approach -

``````# Based on http://stackoverflow.com/a/14314054/3293881 by @Jaime
def moving_sum(a, n) :
ret = np.cumsum(a)
ret[n:] = ret[n:] - ret[:-n]
return ret[n - 1:]

sums = moving_sum(L, subarray_length)
min_idx = sums.argmin()
candidate_sum, candidate_idx = sums[min_idx], min_idx
``````

Alternatively, we could use `np.convolve` to compute the windowed summations, like so -

``````sums = np.convolve(L,np.ones(subarray_length,dtype=int),'valid')
``````

Another way to get `sums` with `Scipy's uniform 1D filter` -

``````from scipy.ndimage.filters import uniform_filter1d as unif1d

W = subarray_length
a = np.array(L,dtype=float)

hW = (W-1)//2
sums = W*unif1d(a,size=W, mode='constant')[hW:-hW]
``````
• wow, that first approach is so smart. `np.convolve` so useful as well – dimebucker91 Apr 4 '17 at 10:48

Slightly less performant than @Divakar's answer, you can use `as_strided` to collect the sub-arrays and go from there:

``````import numpy as np

def min_sub_sum(arr,n):
shape = (arr.shape[0]-n+1,n)
strides = arr.strides
subs = np.lib.stride_tricks.as_strided(arr,shape,strides*2)
sums = np.einsum('ij->i',subs)
return np.argmin(sums)

L = np.array([x for x in range(10000,0,-1)])
n = 5

print(min_sub_sum(L,n))
# 9995
``````