# Optimizing a Parking Lot Problem. What algorithims should I use to fit the most amount of cars in the lot?

What algorithms (brute force or not) would I use to put in as many cars (assume all cars are the same size) in a parking lot so that there is at least one exit (from the container) and a car cannot be blocked. Or can someone show me an example of this problem solved programmatically.

The parking lot varies in shape would be nice but if you want to assume its some invariant shape that is fine.

Another Edit: Assume that driving distance in the parking lot is not a factor (although it would be totally awesome if it was weighted factor to number of cars in lot).

Another Edit: Assume 2 Dimensional (no cranes or driving over cars).

Another Edit: You cannot move cars around once they are parked (its not a valet parking lot).

I hope the question is specific enough now.

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What do you mean "organize a parking lot"? Optimize the choice of space each car parks in? Optimize the physical layout of the parking lot? What are your constraints--are all cars the same size? What geometry are we working with? I think you're getting ahead of yourself; you didn't give much detail about the problem you're trying to solve! –  John Kugelman May 13 '10 at 17:43
I have voted to close. Reason: too vague. Please edit to add more specifics. –  Aryabhatta May 13 '10 at 17:43
I didn't vote to close, but to be honest I'm not sure I understand what the OP wants. What exactly is a parking lot and what exactly is a car in a programming context? What is an exit? Can you post an example? Also, much clearer questions have been closed before. Just saying. –  IVlad May 13 '10 at 19:03
@Shaggy Frog: Consider a parking lot that looks like this, only longer: `_ | | _`, where cars can only be placed on a `_` facing a `|`. It's pretty obvious what the solution is in this case, so I'm honestly not sure what the OP is after as long as he says "the shape can change, but only if you want it to". Well, I want it to always be that shape so the problem is trivial. I just don't really see what his question is. When you say "parking lot", I think of real life parking lots, for which a greedy algorithm will find the optimal solution easily. Use programming terms to make this less vague. –  IVlad May 13 '10 at 19:44
Talking about NP-Completeness for an open-ended question like this is complete nonsense. For instance, I will have a parking lot with a crane attached. It will just pick up the cars and put them out. Completely full. Or use a tunnel as a queue, and if we need the 10th car, drive the first 9 out, and put them back in by driving on the roof of the tunnel. Again completely full. 'Polynomial' time algorithms to put and take out the cars. I guess I will take ShaggyFrog's suggestion and move on. –  Aryabhatta May 13 '10 at 20:28

Well, let's simplify/concreteify a bit. Assume that our cars are unit squares, the parking lot is N x N, and we need to enter/exit from the lower left corner. A simple pattern gets the lot almost 2/3 full with cars (shown for N=12):

``````+------------+
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|C CC CC CC C|
|
-----------+
``````

I can prove that the best you can possibly do is to get the lot 2/3 full. Imagine that you build up the empty spaces by starting with a completely full garage and driving out a (currently reachable) car one at a time. Each time you remove a car, you produce up to 3 newly reachable cars, and remove one once-reachable car (now an empty space). So for every space you make, you create at most 2 more reachable cars. To make 2/3 N^2 reachable cars, you need to make at least 1/3 N^2 spaces, and that's all the squares you have. So you can fill the garage at most 2/3 full.

The simple pattern above is asymptotically optimal, as its density approaches 2/3 as N -> infinity. (Kinda boring, I was hoping some tree-looking pattern would do better.)

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This is basically equivalent to bin-packing, with the added requirement that an exit be in a particular place and all the cars can exit -- which is itself a hard problem!

So your problem is at least NP-hard.

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Exactly. It was the point I was trying to make in the question is that while it may be NP-Hard to pack him in its also hard to figure out how there exit path. –  Adam Gent May 13 '10 at 18:24
Figuring out the sequence of moves to get all the cars out is the basis behind the game Rush Hour. I wrote a program to "solve" Rush Hour puzzles back in university for a course. It's actually a more complex version of a sliding-tile game, and those (I believe) are NP-Complete. –  Shaggy Frog May 13 '10 at 18:56

Is your definition of efficiency the greatest number of parking spots in a lot of a given size and shape (assuming that each car can be driven away without moving any other car)? If so, it is a packing problem, not a knapsack problem, and it sounds NP to me, but the range of solutions for any real-world lot being so small it could be solved with an practical exhaustive search.

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Yes and No because you also have to figure out the exit strategy of each car. And as bonus keeping the distance down would be nice also but you would have to weight that in some how. –  Adam Gent May 13 '10 at 18:31
An "exhaustive search" of either a bin packing problem OR the "Rush Hour" type puzzle is not practically done with an "exhaustive search". They are difficult problems to solve. –  Shaggy Frog May 13 '10 at 19:54