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# Packing problem revisited

I'm developing a game and I found a problem that I have to solve to handle the layout of a component which resembles me a packing problem.

To summarize what I need to do suppose I've got a space similar to the following one:

``````+------------+---------+------------+
| 0          | 1       | 2          |
|            |         |            |
|            |         |            |
|            |         |            |
+------------+---------+------------+
| 3          | 4       | 5          |
|            |         |            |
|            |         |            |
+------------+---------+------------+
| 6          | 7       | 8          |
|            |         |            |
|            |         |            |
|            |         |            |
+------------+---------+------------+
``````

in which every corner cell is 4x4 while central one is 3x3 (so that remaining ones are 3x4 and 4x3). Then I have a set of elements to place inside these blocks that can vary from 1x1 to 3x3 (I don't think any 4x4 is needed yet but it shouldn't change anything). Of course these elements cannot cross the lines and must lay entirely within one single block.

Which could be the best way to allocate them? Assuming that I prefer not to have them all stickied together if is not necessary (eg. do not place two elements together if there's enough room around to place them apart). I'm looking for a simple algorithm, also because the situation is quite limited..

Bonus question: assuming other blocks in addition to these 9 (maybe other 3-4) how could I prioritize these compared to the new ones? (I mean just doesn't use the additional block until a fill threshold has been reached)..

Of course I'm looking for the general idea, no implementation :)

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Is rotating the elements allowed/desirable if it produces better results? – Jon Dec 23 '10 at 14:17
no, it is actually unallowed.. if an element to be placed is 2x3 then it must be placed that way and not 3x2.. – Jack Dec 23 '10 at 14:20
How does the probability distribution of the block types (1x1, 2x2, 3x3, and maybe 4x4) look like? An optimal solution depends on this. And, thus, whether 4x4 blocks have to be considered or not, indeed affects an optimal solution. – Flinsch Dec 23 '10 at 14:46
I have a fixed sets of elements but not all of them will be placed inside the layout. Just to let you understand: they are buildings of a city and this layout is the city layout, of course I know the list of every building available but not which of them will be inside a specific city (since they depends on what the player builds there). – Jack Dec 23 '10 at 14:50

This 2D Bin Packing problem looks like it's NP hard.

Here are a couple of your options:

• Brute force or better yet branch and bound. Doesn't scale (at all!), but will find you the optimal solution (not in our lifetime maybe).

• Deterministic algorithm: sort the blocks on largest size or largest side and go through that list one by one and assign it the best remaining spot. That will finish very fast, but the solution can be far from optimal (or feasible). Here's a nice picture showing an example what can go wrong. But if you want to keep it simple, that's the way to go.

• Meta-heuristics, starting from the result of a deterministic algorithm. This will give you a very good result in reasonable time, better than what humans come up with. Depending on how much time you give it and the difficulty of the problem it might or might not be the optimal solution. There are a couple of libraries out there, such as Drools Planner (open source java).

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On the bonus question: model the basic blocks as "hard constraints" and those bonus blocks as "soft constraints". – Geoffrey De Smet Dec 23 '10 at 16:27
Can you update the link to "Here's a nice picture showing an example what can go wrong."? – tommy.carstensen May 26 '15 at 15:56
done, link adjusted – Geoffrey De Smet May 27 '15 at 7:24
This is very relevant to a LEGO packing problem I'm working on. I'm replacing 1x1 bricks and plates with larger bricks and plates to reduce the cost. Thanks for the great example! – tommy.carstensen May 27 '15 at 16:02