# Allocate an array of integers proportionally compensating for rounding errors

I have an array of non-negative values. I want to build an array of values who's sum is 20 so that they are proportional to the first array.

This would be an easy problem, except that I want the proportional array to sum to exactly 20, compensating for any rounding error.

For example, the array

``````input = [400, 400, 0, 0, 100, 50, 50]
``````

would yield

``````output = [8, 8, 0, 0, 2, 1, 1]
sum(output) = 20
``````

However, most cases are going to have a lot of rounding errors, like

``````input = [3, 3, 3, 3, 3, 3, 18]
``````

naively yields

``````output = [1, 1, 1, 1, 1, 1, 10]
sum(output) = 16  (ouch)
``````

Is there a good way to apportion the output array so that it adds up to 20 every time?

• don't understand the question... what do you mean by a "proportional array" Apr 26, 2013 at 0:45
• Why use a integral type, not just use a floating point type? Apr 26, 2013 at 0:46
• Is it critical that every non-zero numbers are also non-zero in the solution array or can [100, 100, 50, 50] be resolved as [20, 0, 0, 0] ? This would allow some kind of decreasing sum algorithm. Apr 26, 2013 at 0:56
• How close to perfectly proportional are you willing to accept? You obviously can't get exact proportions for all arrays without using floating-point. Apr 26, 2013 at 0:59
• See stackoverflow.com/questions/15769948/… The same principle will work for integers. Apr 26, 2013 at 1:09

There's a very simple answer to this question: I've done it many times. After each assignment into the new array, you reduce the values you're working with as follows:

1. Call the first array A, and the new, proportional array B (which starts out empty).
2. Call the sum of A elements T
3. Call the desired sum S.
4. For each element of the array (i) do the following:
a. B[i] = round(A[i] / T * S). (rounding to nearest integer, penny or whatever is required)
b. T = T - A[i]
c. S = S - B[i]

That's it! Easy to implement in any programming language or in a spreadsheet.

The solution is optimal in that the resulting array's elements will never be more than 1 away from their ideal, non-rounded values. Let's demonstrate with your example:
T = 36, S = 20. B = round(A / T * S) = 2. (ideally, 1.666....)
T = 33, S = 18. B = round(A / T * S) = 2. (ideally, 1.666....)
T = 30, S = 16. B = round(A / T * S) = 2. (ideally, 1.666....)
T = 27, S = 14. B = round(A / T * S) = 2. (ideally, 1.666....)
T = 24, S = 12. B = round(A / T * S) = 2. (ideally, 1.666....)
T = 21, S = 10. B = round(A / T * S) = 1. (ideally, 1.666....)
T = 18, S = 9.   B = round(A / T * S) = 9. (ideally, 10)

Notice that comparing every value in B with it's ideal value in parentheses, the difference is never more than 1.

It's also interesting to note that rearranging the elements in the array can result in different corresponding values in the resulting array. I've found that arranging the elements in ascending order is best, because it results in the smallest average percentage difference between actual and ideal.

• Interesting. The last calculation will always have A[i] == T and B[i] == S, because that's all that's left in each. Way more elegant than mine. Aug 11, 2016 at 23:42

Your problem is similar to a proportional representation where you want to share N seats (in your case 20) among parties proportionnaly to the votes they obtain, in your case [3, 3, 3, 3, 3, 3, 18]

There are several methods used in different countries to handle the rounding problem. My code below uses the Hagenbach-Bischoff quota method used in Switzerland, which basically allocates the seats remaining after an integer division by (N+1) to parties which have the highest remainder:

``````def proportional(nseats,votes):
"""assign n seats proportionaly to votes using Hagenbach-Bischoff quota
:param nseats: int number of seats to assign
:param votes: iterable of int or float weighting each party
:result: list of ints seats allocated to each party
"""
res=[int(f) for f in frac]
n=nseats-sum(res) #number of seats remaining to allocate
if n==0: return res #done
if n<0: return [min(x,nseats) for x in res] # see siamii's comment
#give the remaining seats to the n parties with the largest remainder
remainders=[ai-bi for ai,bi in zip(frac,res)]
limit=sorted(remainders,reverse=True)[n-1]
#n parties with remainter larger than limit get an extra seat
for i,r in enumerate(remainders):
if r>=limit:
res[i]+=1
n-=1 # attempt to handle perfect equality
if n==0: return res #done
raise #should never happen
``````

However this method doesn't always give the same number of seats to parties with perfect equality as in your case:

``````proportional(20,[3, 3, 3, 3, 3, 3, 18])
[2,2,2,2,1,1,10]
``````
• +1 For the blog post drgoulu.com/2013/12/02/repartition-proportionnelle Dec 2, 2013 at 20:03
• right ... added a line to handle this : if n<0: return [min(x,nseats) for x in res] Mar 14, 2014 at 10:27
• I've found that the code in this answer fairly often results in an off-by-one error between the sum of the seats for each party and the number of seats to be allocated. Anyone else who's looking to use an algorithm like this will, depending on their needs, be better-served using another implementation or algorithm, e.g. the D'Hondt method code published here: github.com/rg3/dhondt/blob/master/dhondt Mar 6, 2021 at 5:15

You have set 3 incompatible requirements. An integer-valued array proportional to `[1,1,1]` cannot be made to sum to exactly 20. You must choose to break one of the "sum to exactly 20", "proportional to input", and "integer values" requirements.

If you choose to break the requirement for integer values, then use floating point or rational numbers. If you choose to break the exact sum requirement, then you've already solved the problem. Choosing to break proportionality is a little trickier. One approach you might take is to figure out how far off your sum is, and then distribute corrections randomly through the output array. For example, if your input is:

``````[1, 1, 1]
``````

then you could first make it sum as well as possible while still being proportional:

``````[7, 7, 7]
``````

and since `20 - (7+7+7) = -1`, choose one element to decrement at random:

``````[7, 6, 7]
``````

If the error was `4`, you would choose four elements to increment.

• Thank you! Excellent point... I should have said "roughly proportional", or to answer jwodder's comment above "within 1 of the proportional value" Apr 26, 2013 at 1:07

A naïve solution that doesn't perform well, but will provide the right result...

Write an iterator that given an array with eight integers (`candidate`) and the `input` array, output the index of the element that is farthest away from being proportional to the others (pseudocode):

``````function next_index(candidate, input)
// Calculate weights
for i in 1 .. 8
w[i] = candidate[i] / input[i]
end for
// find the smallest weight
min = 0
min_index = 0
for i in 1 .. 8
if w[i] < min then
min = w[i]
min_index = i
end if
end for

return min_index
end function
``````

Then just do this

``````result = [0, 0, 0, 0, 0, 0, 0, 0]
result[next_index(result, input)]++ for 1 .. 20
``````

If there is no optimal solution, it'll skew towards the beginning of the array.

Using the approach above, you can reduce the number of iterations by rounding down (as you did in your example) and then just use the approach above to add what has been left out due to rounding errors:

``````result = <<approach using rounding down>>
while sum(result) < 20
result[next_index(result, input)]++
``````
• There is a problem getting started above - my suggestion will always start out by filling up the array with ones. This can be avoided by adding in descending order according to `input`. Apr 26, 2013 at 1:10
• Thank you! I'll work through this tonight with some examples and see how it looks. Apr 26, 2013 at 1:11

The solution I came up with takes advantage of the fact that for an input array v, sum(v_i * 20) is divisible by sum(v). So for each value in v, I mulitply by 20 and divide by the sum. I keep the quotient, and accumulate the remainder. Whenever the accumulator is greater than sum(v), I add one to the value. That way I'm guaranteed that all the remainders get rolled into the results.

Is that legible? Here's the implementation in Python:

``````def proportion(values, total):
# set up by getting the sum of the values and starting
# with an empty result list and accumulator
sum_values = sum(values)
new_values = []
acc = 0

for v in values:
# for each value, find quotient and remainder
q, r = divmod(v * total, sum_values)

if acc + r < sum_values:
# if the accumlator plus remainder is too small, just add and move on
acc += r
else:
# we've accumulated enough to go over sum(values), so add 1 to result
if acc > r:
new_values[-1] += 1
else: