# Formula for the max number of paths through a grid?

Given a grid of open spots, and a certain number of tiles to place in those spots, what function `f(openSpots, tilesToPlace)` will give you the number of continuous paths you can form?

Continuous paths are placements of the tiles such that each tile shares an edge with another. (Only corners touching is not good enough. So `(0, 1)` and `(0, 0)` are legal, but `(1, 1)` and `(2, 2)` is not.)

I already have a function that will find all these paths. However, it only works for small numbers. For larger values, all I need is a count of how many could possibly exist. Here is some data:

``````For 1 tiles, there are 1 paths.
For 2 tiles, there are 4 paths.
For 3 tiles, there are 22 paths.
For 4 tiles, there are 89 paths.
For 5 tiles, there are 390 paths.
For 6 tiles, there are 1476 paths.
For 7 tiles, there are 5616 paths.
For 8 tiles, there are 19734 paths.
For 9 tiles, there are 69555 paths.
``````

This gets really slow to calculate as the puzzle size increases. I think the asymptotic complexity of my path finding solution is pretty bad.

If there are `n` tiles, the grid is at most `n` spots long and wide.

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Should we assume that the initial grid is infinitely large (or at least sufficiently large that the edges can be ignored)? –  Mark Byers Jan 3 '10 at 22:15
Are you sure there are 22 paths for 3 tiles? I can only think of 18. –  Mark Byers Jan 3 '10 at 22:16
@Mark: clarified and no, I'm not sure it's 22. –  Rosarch Jan 3 '10 at 22:42
I'm fairly sure it's 18. I've written a naive program to calculate it by checking all possibilities recursively, and it also gets 18. I can give you the list of paths I found if you like (tile coordinates for each path). It's also pretty slow for n=9, taking about 30 seconds. Would you like the source code? I suspect that to get faster you would need to use a more intelligent algorithm, but I'm not sure what. –  Mark Byers Jan 3 '10 at 22:46
yeah I'd like to see what you came up with. –  Rosarch Jan 3 '10 at 22:52

Your problem seems to be at least as difficult as enumerating polyominoes. There are no known fast algorithms for doing this, and the best known algorithms struggle after n=50. I doubt there is a fast way to solve this problem.

I'm not even going to pretend that this is an optimal solution but it might be useful as a reference solution. I think it at least gives the correct answer, although it takes some time. It solves the problem recursively by finding all paths of length n-1, then checking for all possible places it can add one more tile and removing duplicate solutions. It has a particularly ugly part where it checks for duplicate by converting the path to a string and comparing the strings, but it was fast to write.

Here's the output it generates:

``````n = 1, number of paths found = 1
n = 2, number of paths found = 4
n = 3, number of paths found = 22
n = 4, number of paths found = 113
n = 5, number of paths found = 571
n = 6, number of paths found = 2816
n = 7, number of paths found = 13616
n = 8, number of paths found = 64678
n = 9, number of paths found = 302574
``````

And here's the code:

``````using System;
using System.Collections.Generic;
using System.Linq;

public struct Tile
{
public Tile(int x, int y) { X = x; Y = y; }
public IEnumerable<Tile> GetNeighbours(int gridSize)
{
if (X > 0)
yield return new Tile(X - 1, Y);
if (X < gridSize - 1)
yield return new Tile(X + 1, Y);
if (Y > 0)
yield return new Tile(X, Y - 1);
if (Y < gridSize - 1)
yield return new Tile(X, Y + 1);
}
public override string ToString()
{
return string.Format("({0},{1})", X, Y);
}
}

public class Path
{
public Path(Tile[] tiles) { Tiles = tiles; }
public Tile[] Tiles { get; private set; }
public override string ToString()
{
return string.Join("", Tiles.Select(tile => tile.ToString()).ToArray());
}
}

public class PathFinder
{
public IEnumerable<Path> FindPaths(int n, int gridSize)
{
if (n == 1)
{
for (int x = 0; x < gridSize; ++x)
for (int y = 0; y < gridSize; ++y)
yield return new Path(new Tile[] { new Tile(x, y) });
}
else
{
Dictionary<string, object> pathsSeen = new Dictionary<string, object>();
foreach (Path shortPath in FindPaths(n - 1, gridSize))
{
foreach (Tile tile in shortPath.Tiles)
{
foreach (Tile neighbour in tile.GetNeighbours(gridSize))
{
// Ignore tiles that are already included in the path.
if (shortPath.Tiles.Contains(neighbour))
continue;

Path newPath = new Path(shortPath.Tiles
.Concat(new Tile[] { neighbour })
.OrderBy(t => t.X)
.ThenBy(t => t.Y)
.ToArray());

string pathKey = newPath.ToString();
if (!pathsSeen.ContainsKey(pathKey))
{
pathsSeen[pathKey] = null;
yield return newPath;
}
}
}
}
}
}

static void Main()
{
PathFinder pathFinder = new PathFinder();
for (int n = 1; n <= 9; ++n)
{
List<Path> paths = pathFinder.FindPaths(n, n).ToList();
Console.WriteLine("n = {0}, number of paths found = {1}", n, paths.Count);
//foreach (Path path in paths)
//    Console.WriteLine(path.ToString());
}
}
}
``````
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Would using a n-bit integer, like a 64-bit integer, speed up looking for path duplicates? Consider each tile a bit in the integer, which would at least allow you to use a basic integer to generate a key for the dictionary. For smaller n's, you could also use the integer directly into a boolean-array to figure out if you've seen it before. Just a thought. –  Lasse V. Karlsen Jan 3 '10 at 23:37
It seems like that would help for small n where it runs fast anyway, but not for large n where the actual problem is. I'm considering splitting the alg. into two: first part would identify what shapes are possible without placing them, and the second part would calculate in how many different ways the shape can be placed onto the grid. The second half is actually just a simple multiplication based on the size of the bounding box of the shape. But since we can't even agree what the correct answer is or even what a "path" is, I don't want to make any optimizations just yet. Correctness first. –  Mark Byers Jan 4 '10 at 0:01
I think the first part of the two-part optimized algorithm I suggested above is equivalent to enumerating polyominos: en.wikipedia.org/wiki/Polyomino#Enumeration_of_polyominoes. –  Mark Byers Jan 4 '10 at 0:20