# numbers in a list, find average of surroundings

Question:

Given a list `listA` of numbers, write a program that generates a new list `listB` with the same number of elements as `listA`, such that each element in the new list is the average of its neighbors and itself in the original list.

For example, if `listA = [5, 1, 3, 8, 4]`, `listB = [3.0, 3.0, 4.0, 5.0, 6.0]`, where:

``````(5 + 1)/2 = 3.0
(5 + 1 + 3)/3 = 3.0
(1 + 3 + 8)/3 = 4.0
(3 + 8 + 4)/3 = 5.0
(8 + 4)/2 = 6.0
``````

so i can get the first part, and the last part since they only deal with 2 numbers, but for the middle part i can not get it. my loop is wrong, but i dont know exactly. this is what i have so far.

``````listA= [5,1,3,8,4]

N=len(listA)
print(listA)

listB=[]
listB.append((listA[0]+listA[1])/2)

y=0
x=1
while x in listA:
y=((listA[x-1] + list[x] + list[x+1])/3)
listB.append(y)
y=y+1

listB.append((listA[-1]+listA[-2])/2)

print(listB)
``````
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This looks like homework, so I ask if you have covered slicing yet. This is a prime candidate for using list slicing. –  Silas Ray Oct 11 '12 at 14:20
i think we have gone over it, isnt it when you use the : inside the lists? –  atm atm Oct 11 '12 at 14:21
That's correct, when you have a colon inside the brackets when indexing a list. –  Silas Ray Oct 11 '12 at 14:23

You can do this using iterators without having to resort to looping through indices:

``````import itertools

def neighbours(items, fill=None):
before = itertools.chain([fill], items)
after = itertools.chain(items, [fill]) #You could use itertools.zip_longest() later instead.
next(after)
for a, b, c in zip(before, items, after):
yield [value for value in (a, b, c) if value is not fill]
``````

Used like so:

``````>>> items = [5, 1, 3, 8, 4]
>>> [sum(values)/len(values) for values in neighbours(items)]
[3.0, 3.0, 4.0, 5.0, 6.0]
``````

So how does this work? We create some extra iterators - for the before and after values. We use `itertools.chain` to add an extra value to the beginning and end respectively, in order to allow us to get the right values at the right time (and not run out of items). We then advance the later item on one, to put it in the right position, then loop through, returning the values that are not `None`. This means we can just loop through in a very natural way.

Note that this requires a list, as an iterator will be exhausted. If you need it to work lazily on an iterator, the following example uses `itertools.tee()` to do the job:

``````def neighbours(items, fill=None):
b, i, a = itertools.tee(items, 3)
before = itertools.chain([fill], b)
after = itertools.chain(a, [fill])
next(a)
for a, b, c in zip(before, i, after):
yield [value for value in (a, b, c) if value is not fill]
``````
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I've seen so many great answers from you. Just wanted to say that you're awesome! –  Oleh Prypin Oct 11 '12 at 21:53
@BlaXpirit Cheers. –  Latty Oct 11 '12 at 22:09
``````list_a = [5, 1, 3, 8, 4]
# Start list_b with the special case first element
list_b = [sum(list_a[:1]) / 2.0]
# Iterate over each remaining index in the list
for i in range(1, len(list_a - 1)):
# Get the slice of the element and it's neighbors
neighborhood = list_a[i-1:i+1]
# Add the average of the element and it's neighbors
# have to calculate the len of neighborhood to handle
# last element special case
list_b.append(sum(neighborhood) / float(len(neighborhood)))
``````
-

Could use arcpy.AverageNearestNeighbor_stats

Otherwise, if you like loops:

``````import numpy as np

listA= [5,1,3,8,4]
b = []

for r in xrange(len(listA)):
if r==0 or r==len(listA):
b.append(np.mean(listA[r:r+2]))
else:
b.append(np.mean(listA[r-1:r+2]))
``````
-

It looks like you've got the right idea. Your code is a little tough to follow though, try using more descriptive variable names in the future :) It makes it easier on every one.

Here's my quick and dirty solution:

``````def calcAverages(listOfNums):
outputList = []
for i in range(len(listOfNums)):
if i == 0:
outputList.append((listOfNums[0] + listOfNums[1]) / 2.)
elif i == len(listOfNums)-1:
outputList.append((listOfNums[i] + listOfNums[i-1]) / 2.)
else:
outputList.append((listOfNums[i-1] +
listOfNums[i] +
listOfNums[i+1]) / 3.)
return outputList

if __name__ == '__main__':
listOne =  [5, 1, 3, 8, 4, 7, 20, 12]
print calcAverages(listOne)
``````

I opted for a `for` loop instead of a `while`. This doesn't make a big difference, but I feel the syntax is easier to follow.

``````for i in range(len(listOfNums)):
``````

We create a loop which will iterate over the length of the input list.

Next we handle the two "special" cases: the beginning and end of the list.

``````    if i == 0:
outputList.append((listOfNums[0] + listOfNums[1]) / 2.)
elif i == len(listOfNums)-1:
outputList.append((listOfNums[i] + listOfNums[i-1]) / 2.)
``````

So, if our index is 0, we're at the beginning, and so we add the value of the currect index, `0`, and the next highest `1`, average it, and append it to our output list.

If our index is equal to the length of out list - 1 (we use -1 because lists are indexed starting at 0, while length is not. Without the -1, we would get an IndexOutOfRange error.) we know we're on the last element. And thus, we take the value at that position, add it to the value at the previous position in the list, and finally append the average of those numbers to the output list.

``````    else:
outputList.append((listOfNums[i-1] +
listOfNums[i] +
listOfNums[i+1]) / 3.)
``````

Finally, for all of the other cases, we simply grab the value at the current index, and those immediately above and below it, and then append the averaged result to our output list.

-
``````In [31]: lis=[5, 1, 3, 8, 4]

In [32]: new_lis=[lis[:2]]+[lis[i:i+3] for i in range(len(lis)-1)]

In [33]: new_lis
Out[33]: [[5, 1], [5, 1, 3], [1, 3, 8], [3, 8, 4], [8, 4]]

#now using sum() ans len() on above list and using a list comprehension

In [35]: [sum(x)/float(len(x)) for x in new_lis]
Out[35]: [3.0, 3.0, 4.0, 5.0, 6.0]
``````

or using `zip()`:

``````In [36]: list1=[lis[:2]] + zip(lis,lis[1:],lis[2:]) + [lis[-2:]]

In [37]: list1
Out[37]: [[5, 1], (5, 1, 3), (1, 3, 8), (3, 8, 4), [8, 4]]

In [38]: [sum(x)/float(len(x)) for x in list1]
Out[38]: [3.0, 3.0, 4.0, 5.0, 6.0]
``````
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i dont think we learned zip yet. what exactly does zip do –  atm atm Oct 11 '12 at 14:34
You could also add in a `map` with a `lambda` to generate the final list. Though it's not very explanatory for a new programmer. –  Silas Ray Oct 11 '12 at 14:34
@atmatm read about zip here –  Ashwini Chaudhary Oct 11 '12 at 14:36