# Split number into sum components

Is there an efficient algorithm to split up a number into `N` subsections so that the sum of the numbers adds up to the original, with a base minimum? For example, if I want to split 50 into 7 subsections, and have a base minimum of 2, I could do `10,5,8,2,3,5,17` (as well as any other number of combinations). I'd like to keep the numbers as integers, and relatively random but I'm not sure how to efficiently generate numbers that sum up to the original and don't include numbers lower than the given minimum. Any suggestions?

EDIT - Just to copy/paste my comment, the integers don't have to be unique, but I want to avoid equal sizes for all of them (e.g. 50 split into 10 equal sizes) everytime.

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Subset sum: Given a set of number find a subset that sums to a specific number. Your Problem: Given a number find it's corresponding subset that sums up to it. I'm willing to bet you are in the NP-complete domain :) – PhD Oct 16 '11 at 23:46
Are you wanting all of the integers to be unique? – Ben Hocking Oct 16 '11 at 23:49
@Skoder - Why not 'randomize' :) It'll be super easy and you'll get what you want! If you need to 'slice' into 5 pieces - just randomly select 4 incremental numbers upto upper bound! – PhD Oct 16 '11 at 23:58
@Nupul I think that's enough a matrix [N,Set]. In the OP's example a matrix [7,50], in your case [100,23]. As a problem constraint you are going to ignore the solutions that have numbers < min. In my opinion this is also a not so hard to solve problem. Thus, I think this problem is solvable in polynomial time. – Aurelio De Rosa Oct 17 '11 at 0:02
I see nothing related to NP in this question. You could even find a (complex) combinatorial formula `Spl(X,N,M)=..ComplexFormula..` that gives you how many ways you can split a number `X` into `N` subsections having `M` as minimum. `Spl(50,7,7)` would be `=1` for example. – ypercubeᵀᴹ Oct 17 '11 at 0:04

Here's an algorithm:

1. Divide `N` by `m` where `N` is your number and `m` is the number of subsections.
2. Round the result down to its nearest value and assign that value to all of the subsections.
3. Add one to each subsection until the values add up to `N`. At this point if `N` was 50 and `m` was 7, you'd have 8, 7, 7, 7, 7, 7, 7
4. Iterate from 1 to N, stepping by 2, and add a random number between `-(N-base)` and `N-base`. Add the inverse of that number to its neighboring bucket. If you have an odd number of buckets, then on the last bucket instead of adding the inverse of that number to its neighboring bucket, add it to all of the other buckets in a distributed manner similar to steps 2 and 3 above.

Performance: Step 1 is `O(1)`, Steps 2, 3, and 4 are `O(m)`, so overall it's `O(m)`.

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@Skoder: As per your requirement it seems just incrementally selecting random numbers upto the specified maximum should give you what you want. You want to split a block into constituent parts is the main intent, not whether numbers can add up exactly to a specific number – PhD Oct 17 '11 at 0:18

You can easily remove the requirement of a minimum by subtracting minimum times N from the number, generating the N subsections and adding the minimum. In your example, the problem reduces to splitting 36 into 7 integers, and you have given the split 8,3,6,0,1,3,15.

The rest of the solution depends on the nature of the "relatively random" requirement. For some minimal randomness, consider choosing numbers sequentially between 0 and the unsplitted part (e.g. between 0 and 36 first, gaining 8, then between 0 and 28, gaining 3, and so on 7 times). If that doesn't suffice, you'll need to define randomness first.

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By 'randomness', I just mean that the results are not always the same. So if 50 was to be split 10 times, it wouldn't always be 10,10,10,10,10. – Skoder Oct 16 '11 at 23:59
@Skoder: Well, then my "minimum randomness" solution should suffice, and your solution is in O(k). The first parts will tend to be the largest, though. – thiton Oct 17 '11 at 0:07
You should shuffle the list after doing the steps above. – Fantius Oct 17 '11 at 16:11
@Fantius: That would help a bit, but still give a skewed distribution. – thiton Oct 17 '11 at 16:53

here is a pseudo random solution [note that solution might be biased, but will be relatively random].

``````input:
n - the number we should sum up to
k - the number of 'parts'
m - minimum

(1) split n into k numbers: x1,x2,...,xk such that x1+...+xk = n, and the numbers
are closest possible to each other [in other words, x1 = x2 = ... = n/k where
possible, the end might vary at atmost +-1.]
(2) for each number xi from i=1 to k-1:
temp <- rand(m,xi)
spread x - temp evenly among xi+1,...,xk
xi <- temp
(3) shuffle the resulting list.
``````

regarding part 1, for example: for `n=50, k = 7`, you will set: `x1=x2=...=x6=7,x7=8`, no problem to compute and populate such a list with linear time.

Performance:

As said, step1 is O(k).

Step2, with naive implementation is O(k^2), but since you distribute result of `temp-xi` evenly, there is O(k) implementation, with just storing and modifying delta.

Step3 is just a simple shuffle, O(k)

Overall performance: O(k) with delta implemntation of step2

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Well I've come up with something "just for fun".

It goes incrementally from `minimum` to `number` and populates an array with `N` sections using modulo and random.

See the jsFiddle here.

It won't work as expected if there are too many sections for this number. (ie `number < N(N+1)/2`)

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