# Algorithm for fair distribution of revenue

I am after an algorithm (preferably abstract or in very clear Python or PHP code) that allows for a fair distribution of revenue both in the short and in the long term, based on the following constraints:

• Each incoming amount will be an integer.
• Each distribution will be also an integer amount.
• Each person in the distribution is set to receive a cut of the revenue expressed as a fixed fraction. These fractions can of course be put under a common denominator (think integer percentages with a denominator of 100). The sum of all numerators equals the denominator (100 in the case of percentages)
• To make it fair in the short term, person 'i' must be receiving either floor(revenue*cut[i]) or ceil(revenue*cut[i]). EDIT: Let me emphasize that ceil(revenue*cut[i]) is not necessarily equal to 1+floor(revenue*cut[i]), which is where some algorithms fail including one presented (see my comment on the answer by Andrey).
• To make it fair in the long term, as payments accumulate, the actual cuts received must be as close to the theoretical cuts as possible, preferably always under 1 unit. In particular, if the total revenue is a multiple of the denominator of the common fraction, every person should have received the corresponding multiple of their numerator.
•  Forgot to add that the total amount distributed every time must of course add up to the incoming amount received.

Here's an example for clarity. Say there are three people among which to distribute revenue, and one has to get 31%, another has to get 21%, and the third has to get 100-31-21=48%.

Now imagine that there's an income of 80 coins. The first person should receive either floor(80*31/100) or ceil(80*31/100) coins, the second person should receive either floor(80*21/100) or ceil(80*21/100) and the third person, either floor(80*48/100) or ceil(80*48/100).

And now imagine that there's a new income of 120 coins. Each person should again receive either the floor or the ceiling of their corresponding cuts, but since the total revenue (200) is a multiple of the denominator (100), each person should have now their exact cuts: the first person should have 62 coins, the second person should have 42 coins, and the third person should have 96 coins.

I think I have an algorithm figured out for the case of two people to distribute the revenue among. It goes like this (for 35% and 65%):

``````set TotalRevenue to 0
set TotalPaid[0] to 0
{ TotalPaid[1] is implied and not necessary for the algorithm }
set Cut[0] to 35
{ Cut[1] is implied and not necessary for the algorithm }
set Denominator to 100
each time a payment is received:
let Revenue be the amount received this time
set TotalRevenue = TotalRevenue + Revenue
set tmp = floor(TotalRevenue*Cut[0]/Denominator)
pay person 0 the amount of tmp - TotalPaid[0]
set TotalPaid[0] = tmp
pay person 1 the amount of TotalRevenue - TotalPaid[0]
``````

I think that this simple algorithm meets all of my constraints, but I have not found the way to extend it to more than two people without violating at least one. Can anyone figure out an extension to multiple people (or perhaps prove its impossibility)?

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Interesting problem... Are incoming amounts always distributed to the full set of people? And, if to the full set, can the cut percentages be adjusted between rounds (eg. person i gets 10% on one round but 17% on the next round)? –  NealB Dec 19 '13 at 20:51
In my use case, always to the full set, and a change of percentages would mean a reset of the system: they can't be changed on the fly. I dind't want to complicate it that much. –  Pedro Gimeno Dec 19 '13 at 23:15

I think this works:

• Keep track of a `totalReceived`, the total amount of money that has entered the system.
• When money is added to the system, add it to `totalReceived`.
• Set `person[i].newTotal = floor(totalReceived * cut[i])`. Edit: had error here; thanks commenters. This distributes some of the money. Keep track of how much, to know how much "new money" is left over. To be clear, we are keeping track of how much of the total amount of money is left over, and intuitively we re-distribute the whole sum at every step, although actually nobody's fund ever goes down between one step and the next.
• You need to know how to distribute the left-over integer amount of money: there should be less than `numPeople` amount left over. For `i` ranging from `0` to `leftOverMoney - 1`, increment `person[i].newTotal` by 1. Effectively we give a dollar to each of the first `leftOverMoney` people.
• To compute how much a person "received" during this step, compute `person[i].newTotal - person[i].total`.
• To clean/finish up, set `person[i].total = person[i].newTotal`.
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For maximum fairness, distribute the remainder first to those people with the largest distribution error. I.e. in step 3, also set person[i].error to fract(totalReceived * cut[i]). Then in step 4, sort the people by .error, descending, before giving a coin to each of the first leftOverMoney people. –  A. I. Breveleri Dec 19 '13 at 21:41
@A.I.Breveleri You have to be careful that nobody's `newTotal` ends up being less than his `total` was if you make a modification like that. And I think it's not obvious... in fact I think it's not true. –  Andrey Dec 19 '13 at 21:42
"Set person[i].newTotal = person[i].total + floor(totalReceived * cut[i])" is wrong. If Pedro Gimeno attempts to use this calculation his distributed amounts will be much too large. You are probably looking at "totalReceived" and thinking it represents the money added to the system for the current distribution. But according to steps 1 and 2, it is the total money added to the system for all distributions so far, including the current distribution. –  A. I. Breveleri Dec 19 '13 at 22:03
Without the modification in the first comment by A. I. Breveleri I think that the proposed algorithm can violate one of the constraints, namely that in each step everyone receives either the floor or the ceiling of the corresponding cut. Example: if the cuts are 20%, 37%, and 43%, and the incoming amount at start is 5, we have floor(5*20/100)=ceil(5*20/100)=1 and giving an additional coin to that person would violate the constraint. With the proposed modification of sorting by descending error, I'm not sure but it seems it might work. Can anyone comment on that? –  Pedro Gimeno Dec 20 '13 at 3:45
@PedroGimeno nice counter-example. I think that if you keep track of whether people are owed a fraction of a coin after the first step, and you just skip them in the "additional coin" step if they are not, then this will work. –  Andrey Dec 20 '13 at 20:30