# Algorithm for finding if an array is balanced [closed]

I'm trying to create a program that will create a 10 element array and then assign random values to each element. I then want the program to tell if the array is balanced. By balanced I mean, is there anywhere in the array values that at a certain element the sum of the values in the elements are equal to the sum of the array values in the elements greater than that current element.

Example

Element (1,2,3,4) Values (2,1,3,0) The program would then display that elements 1-2 are balanced to elemtns 3-4, because they both equal 4.

So far I have

``````import random

size = 10
mean = 0
lists = [0] * size
for i in range(size):
var = random.randint(0,4)
lists[i] = var

for i in lists:
mean += i

avg = (mean)/(size)
``````

I figured the only way the elements could be balanced is if the values average is equal to 2, so I figured that's how I should start.

I'd appreciate any help in the right direction.

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## closed as too localized by Blorgbeard, Minko Gechev, Jean-Bernard Pellerin, tkanzakic, StonyMay 10 '13 at 7:17

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To make a random list of `n` elements: `lists = [randint(0, 4) for _ in range(n)]`. To find the mean/first sample moment of a list of numbers: `avg = sum(lists) / float(len(lists))`. –  Joel Cornett May 8 '13 at 0:29
Your variable names are confusing, like having a single list named `lists`, a total called `mean`, … –  abarnert May 8 '13 at 0:29
Do you mean that the sum of some elements in your list is equal to the sum of some other elements, and that those twe groups may not intersect? –  Lennart May 8 '13 at 0:29
@Lennart yes that's what I mean. It's a confusing problem I know. –  user2348621 May 8 '13 at 0:31
Also, your logic is confusing. The average of the values in your example is 1.5, not 2, and yet it's balanced. So, what makes you think that the elements are balanced iff the average is 2? –  abarnert May 8 '13 at 0:31

If I understand the question, the simplest solution is something like this:

``````def balanced(numbers):
for pivot in range(len(numbers)):
left_total = sum(numbers[:pivot])
right_total = sum(numbers[pivot:])
if left_total == right_total:
return pivot
return None
``````

For example:

``````>>> numbers = [2, 1, 3, 0]
>>> balanced(numbers)
2
>>> more_numbers = [2, 1, 3, 4]
>>> balanced(numbers)
``````

(That didn't print anything, because it returned `None`, meaning there is no pivot to balance the list around.)

While this is the simplest solution, it's obviously not the most efficient, because you keep adding the same numbers up over and over.

If you think about it, it should be pretty easy to figure out how to keep running totals for `left_total` and `right_total`, only calling `sum` once.

``````def balanced(numbers):
left_total, right_total = 0, sum(numbers)
for pivot, value in enumerate(numbers):
if left_total == right_total:
return pivot
left_total += value
right_total -= value
return None
``````

Finally, here's how you can build a program around it:

``````size = 10
numbers = [random.range(4) for _ in range(size)]
pivot = balanced(numbers)
if pivot is None:
print('{} is not balanced'.format(numbers))
else:
print('{} is balanced, because elements 1-{} equal {}-{}'.format(
numbers, pivot+1, pivot+2, size+1))
``````
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One suggestion about your final function: If the list is balanced, at some point `left_total` must equal `right_total` and so they must both be equal to half the total of the whole list. So, you can avoid doing some of the work by just calculating `sum(numbers)/2` once and testing `left_total` against it. You don't need to keep updating `right_total` as you go. –  Blckknght May 8 '13 at 6:02

A good data structure to know about for this kind of problem is an array that has the cumulative sum. `element[j] - element[i]` is the sum from `i` to `j` in the original series. If you have the original series `[1, 2, 3, 4]`, the cumulative series is `[0, 1, 3, 6, 10]`. The sum up to the `i` position in the original series is `element[i] - element[0]`. For this problem, we are interested in only a sum starting at 0, so this is a bit of overkill but, again, more fully useful for other problems.

Here is code to make a cumulative sum:

``````def cumulative_sum(series):
s = [0]
for element in series:
s.append(element + s[-1])
return s
``````

Given that, we can find the pivot point with this code:

``````def find_pivot(series):
cs = cumulative_sum(series)
total = cs[-1]
even_total = not (total & 1)
if even_total:
target = total // 2
for i, element in enumerate(cs[1:]):
if element == target:
return i + 1
return -1
``````

Notice that it is not necessary to try dividing the series if we know the series sums to an odd number: there cannot be a pivot point then.

Alternatively, you can write `find_pivot` like this:

``````def find_pivot(series):
cs = cumulative_sum(series)
total = cs[-1]
even_total = not (total & 1)
if even_total:
target = total // 2
try:
return cs.index(target)
except ValueError:
return -1
return -1
``````

It has the advantage that the looping is not done explicitly in python but in C code in the standard library.

Trying the code out:

``````def test():
for i in range(1, 30):
test_values = range(i)
j = find_pivot(test_values)
if j >= 0:
print "{0} == {1}".format(test_values[:j], test_values[j:])
``````

And we get this output:

``````[0] == []
[0, 1, 2] == [3]
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14] == [15, 16, 17, 18, 19, 20]
``````
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