# Proving a set of requirements can be met with a set of values using LINQ

This is a subset of the question posted here.

Given a set of buckets of volume `B={x1, x2, ..., xn}` and a set of vials with liquid of volumes `V={v1, v2, ..., vn }` what is the best way to prove that the number of buckets can be filled with the contents of the vials assuming that vials must be poured all into one bucket. Overflow is permitted.

Some obvious invariants here are that the cardinality of the buckets `|B|` must be less than or equal to the cardinality of the vials `|V|` and that the combined volume of the buckets `Sum(B)` must be less than or equal to the combined volume of the vials `Sum(V)`

Is this a well known computational problem? If so can a simple LINQ solution be crafted to express this in C#?

I feel like this is something Eric Lippert would have blogged about ;-).

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I've never blogged about this particular problem; I don't know much about partitioning problems. It is an interesting subject though! –  Eric Lippert May 26 at 18:29
@EricLippert I should have known better than to invoke your name you're like Beetlejuice I swear. –  Daniel Green May 26 at 20:18

Consider an instance of this problem where you have two buckets of the same size, and Sum(B) = Sum(V). This means you need to distribute the vials equally over the two buckets, otherwise one will overflow and there won't be enough left for the other. This is called the partition problem, and it is known to be NP-complete.

Edit: Of course, NP-completeness doesn't mean the problem can't be solved, just that the running time will be exponential in the size of the input (in this case, the log2 of the biggest bucket size).

If we can find the smallest amount of liquid needed to fill a bucket (including spillage), solving the problem is a simple matter of doing this for each bucket, and removing the used vials from the set of available vials after each bucket.

We can do this by using dynamic programming:

• For a given bucket b, consider all the buckets of size 0 up to volume(b).
• The size 0 bucket obviously requires no liquid
• For each size s, find a vial v such that:
• The solution for s-volume(v) does not use v
• (The amount of liquid used for s-volume(v)) + volume(v) is minimized
• At the end of all this you will have the vials used to fill bucket b. Then you just remove those from the set of available vials, and move on to the next bucket.
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Also, if you read my previous answer, please disregard it as it was WRONG. –  Imre Kerr May 24 at 21:40
Sure... that's an easy case to solve. But there are cases where Sum(B) = Sum(V) that are unsolvable. –  Daniel Green May 24 at 21:45
What I showed was that the partition problem, an NP-complete problem, can be expressed as an instance of this problem. Thus this problem is also NP-complete, and therefore (probably) not an easy case to solve at all. –  Imre Kerr May 24 at 21:51
@ImreKerr What you have shown is that this problem is NP-hard (NP-complete or harder), not NP-complete. –  svick May 27 at 0:20
You're right, sorry. But say you have a candidate solution to the problem, expressed as a set of vials for each bucket. You can then take the set for a given bucket, sum it up, and see if they can fill the bucket in O(V) time. Seeing if a vial has been used twice can also be done in polynomial time. Therefore the problem is in NP, and therefore NP-complete. –  Imre Kerr May 27 at 7:05
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