# Split a number into three buckets with constraints

Is there a good algorithm to split a randomly generated number into three buckets, each with constraints as to how much of the total they may contain.

For example, say my randomly generated number is 1,000 and I need to split it into buckets a, b, and c.

``````These ranges are only an example. See my edit for possible ranges.
Bucket a may only be between 10% - 70% of the number (100 - 700)
Bucket b may only be between 10% - 50% of the number (100 - 500)
Bucket c may only be between 5% - 25% of the number (50 - 250)
a + b + c must equal the randomly generated number
``````

You want the amounts assigned to be completely random so there's just as equal a chance of bucket a hitting its max as bucket c in addition to as equal a chance of all three buckets being around their percentage mean.

EDIT: The following will most likely always be true: low end of a + b + c < 100%, high end of a + b + c > 100%. These percentages are only to indicate acceptable values of a, b, and c. In a case where a is 10% while b and c are their max (50% and 25% respectively) the numbers would have to be reassigned since the total would not equal 100%. This is the exact case I'm trying to avoid by finding a way to assign these numbers in one pass.

I'd like to find a way to pick these number randomly within their range in one pass.

-
If we select the 10% of the first bucket then the max number we can get is (10%+50%+25%)*x = 85% of the initial number. So a+b+c cannot hold. –  pnezis Nov 15 '11 at 16:06
Sorry this wasn't clear. I've updated the post. –  Aaron Nov 17 '11 at 15:49

Update: Yes, you're right, the result is not uniformly distributed.

Let's say your percent values are natural numbers (if this assumption is wrong, you don't have to read further :) In that case I don't have a solution).

Let's define an event `e` as a tuple of 3 values (percentage of each bucket): e = (pa, pb, pc). Next, create all possible events en. What you have here is a tuple space consisting of a discrete number of events. All of the possible events should have the same possibility to occur.

Let's say we have a function f(n) => en. Then, all we have to do is take a random number n and return en in a single pass.

Now, the problem remains to create such a function `f` :)

In pseudo code, a very slow method (just for illustration):

``````function f(n) {
int c = 0
for i in [10..70] {
for j in [10..50] {
for k in [5..25] {
if(i + j + k == 100) {
if(n == c) {
return (i, j, k) // found event!
} else {
c = c + 1
}
}
}
}
}
}
``````

What you have know is a single pass solution, but problem is only moved away. The function f is very slow. But you can do better: I think you can calculate everything a bit faster if you set your ranges correctly and calculate offsets instead of iterating through your ranges.

Is this clear enough?

First of all you probably have to adjust your ranges. 10% in bucket `a` is not possible, since you can't get condition `a+b+c = number` to hold.

Concerning your question: (1) Pick a random number for bucket `a` inside your range, then (2) update the range for bucket `b` with minimum and maximum percentage (you should only narrow the range). Then (3) pick a random number for bucket `b`. In the end `c` should be calculated that your condition holds (4).

Example:

``````    n = 1000
(1) a = 40%
(2) range b [35,50], because 40+35+25 = 100%
(3) b = 45%
(4) c = 100-40-45 = 15%
``````

Or:

``````    n = 1000
(1) a = 70%
(2) range b [10,25], because 70+25+5 = 100%
(3) b = 20%
(4) c = 100-70-20 = 10%
``````

It is to check whether all the events are uniformly distributed. If that should be a problem you might want to randomize the range update in step 2.

-
I've updated the question to address the possibility and problem of a being 10%. –  Aaron Nov 17 '11 at 15:54
@Aaron: updated my answer, is it more useful for you? –  duedl0r Nov 18 '11 at 13:42

The problem is equivalent to selecting a random point in an N-dimensional object (in your example N=3), the object being defined by the equations (in your example):

``````0.1  <= x  <= 0.7
0.1  <= y  <= 0.5
0.05 <= z  <= 0.25
x + y + z   = 1 (*)
``````

Clearly because of the last equation (*) one of the coordinates is redundant, i.e. picking values for x and y dictates z.

Eliminating (*) and one of the other equations leaves us with an (N-1)-dimensional box, e.g.

``````0.1 <= x  <= 0.7
0.1 <= y  <= 0.5
``````

that is cut by the inequality

``````0.05 <= (1 - x - y) <= 0.25 (**)
``````

that derives from (*) and the equation for z. This is basically a diagonal stripe through the box.

In order for the results to be uniform, I would just repeatedly sample the (N-1)-dimensional box, and accept the first sampled point that fulfills (**). Single-pass solutions might end up having biased distributions.

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The problem with this is if x and y are both 0.1. It would mean that z must be 0.8 which is outside of its acceptable bounds. –  Aaron Nov 17 '11 at 15:53