Bad news: this problem is NP-hard by a reduction from subset sum. Given numbers x_{1}, …, x_{n}, S, the object of subset sum is to determine whether or not some subset of the x_{i}s sum to S. We make A-bottles with capacities x_{1}, …, x_{n} and B-bottles with capacities S and (x_{1} + … + x_{n} - S) and determine whether n pours are sufficient.

Good news: any greedy strategy (i.e., choose any nonempty A, choose any unfilled B, pour until we have to stop) is a 2-approximation (i.e., uses at most twice as many pours as optimal). The optimal solution uses at least max(|A|, |B|) pours, and greedy uses at most |A| + |B|, since every time greedy does a pour, either an A is drained or a B is filled and does not need to be poured out of or into again.

~~There might be an approximation scheme (a (1 + ε)-approximation for any ε > 0).~~ I think now it's more likely that there's an inapproximability result – the usual tricks for obtaining approximation schemes don't seem to apply here.

Here are some ideas that might lead to a practical exact algorithm.

Given a solution, draw a bipartite graph with left vertices `A`

and right vertices `B`

and an (undirected) edge from `a`

to `b`

if and only if `a`

is poured into `b`

. If the solution is optimal, I claim that there are no cycles – otherwise we could eliminate the smallest pour in the cycle and replace the lost volume going around the cycle. For example, if I have pours

```
a1 -> b1: 1
a1 -> b2: 2
a2 -> b1: 3
a2 -> b3: 4
a3 -> b2: 5
a3 -> b3: 6
```

then I can eliminate by `a1 -> b1`

pour like so:

```
a2 -> b1: 4 (+1)
a2 -> b3: 3 (-1)
a3 -> b3: 7 (+1)
a3 -> b2: 4 (-1)
a1 -> b2: 3 (+1)
```

Now, since the graph has no cycle, we can count the number of edges (pours) as `|A| + |B| - #(connected components)`

. The only variable here is the number of connected components, which we want to maximize.

I claim that the greedy algorithm forms graphs that have no cycle. If we knew what the connected components of an optimal solution were, we could use a greedy algorithm on each one and get an optimal solution.

One way to tackle this subproblem would be to use dynamic programming to enumerate all subset pairs X of A and Y of B such that sum(X) == sum(Y) and then feed these into an exact cover algorithm. Both steps are of course exponential, but they might work well on real data.