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So I have the following problem:

Given a grid of x by y dimensions, calculate the number of routes through it that start in one corner (let's say top left) and end in another (bottom right) and pass through every vertex.

So my current method just brute forces it by just trying every possible path and counting the ones that reach the finish and traverse every node. While it works, it's O(n^2) and gets unbelievably slow extremely quickly. I'm not sure how to do it combinatorially because of the requirement that the path traverse every vertex.

I've looked up more complex algorithms, and Hierholzer's algorithm for calculating Eulerian paths seems somewhat related but not perfect because nodes cannot be traversed more than once for this.

As it is, my program works, but badly, and I would like to make it more efficient. Are there better algorithms I could be using?

Edit Thanks for the answers so far. Just to clarify, all nodes in the 2d grid are connected by n/e/s/w

Also, the grid does not have to be a square

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Isn't this the traveling salesman problem? If so, the person who answers it not only gets a few points, but also a Nobel prize! –  ccleve Jan 9 '13 at 23:29
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If it "gets unbelievably slow extremely quickly" then it's not O(n^2) –  Jan Dvorak Jan 9 '13 at 23:30
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@Jan Dvorak Yeah I think brute forcing this is factorial –  David Saxon Jan 9 '13 at 23:32
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@ccleve This is not the TSP. TSP is when you're minimizing the total distance traveled, not simply counting the number of paths. –  anorton Jan 9 '13 at 23:32
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After the edits, this is just a math problem with a final answer, should not need to use traversal/etc. Simply calculate by plugging in a value for x in an expression –  im so confused Jan 10 '13 at 0:03
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3 Answers

There is not much you can do, because it's Hamiltonian path problem, which is NP-complete.

However, you may actually search for something else and add some restrictions to the problem you are trying to solve...

EDIT:

As @JanDvorak noted, your specific restriction is that your are using square grid. My findings so far:

If x is even, than there is no way to go through all vertices starting from top left corner and end in bottom right. Proof:

Lets count directed movements along axes, e.g. up is -1, down is 1, left is -1, right -1. So, having x by x grid, your total movement would be 2*x. At each vertex (except the last one!) your are selecting only one direction. So, if there is even number of vertices you need to go through, your total movement would be even and vice versa for odd. If x is even, than there is odd number of vertices, but total movement is stil even => you are not able to find any way.

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You know the graph is a grid. Doesn't that simplify things a bit? –  Jan Dvorak Jan 9 '13 at 23:39
    
@JanDvorak, yes you are probably right, I'm thinking about it right now. –  hate-engine Jan 9 '13 at 23:44
    
I see. In this case, the corners were just for example purposes (I'm looking for methods that work for any combination of 2 corners) but that definitely helps in the diagonal cases. What about in cases where the start and finish corners are on the same side? –  CharmQuark Jan 10 '13 at 0:00
    
@user1965018 doesn't help –  Jan Dvorak Jan 10 '13 at 0:00
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@JanDvorak, sure. BTW, there was a square grid in question. However, if OP could show some numbers, it probably may be easer to guess correct formula and prove it. –  hate-engine Jan 10 '13 at 0:13
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First off, if x is even, there is a simple parity argument that shows the answer is always zero; chequer the grid and notice that the top-left and bottom-right squares are the same colour, and that colour cannot be visited both first and n2th since n2 is even while 1 is odd.

If x is odd, I don't know how to count the paths, but notice that the total number grows at least exponentially quickly: any traversal of an n*n grid can be lifted to two distinct traversals of an (n+2)*(n+2) grid. You get one by going right along the top row, left along the second row, down along the first column, up along the second column, and then doing your n*n grid traversal on the remaining squares; you get the other by covering the first two rows and columns in the opposite order.

This should tell you that a brute-force solution is unlikely to work very well.

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I worked with problems like this on a subject this semester. I think you could have a look on metaheuristic algorithms such us:

You might want to stay with brute force though, Unless you really need an improvement; because they are quite complex.

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