# complexity of brute force array traversal

If I have a 4x4 grid for example and I want to start at an arbitrary cell (i,j) and then want to travel down every path without crossing over on myself, what is the complexity (big o) of this? I have written the following code:

``````traverse(int[][]grid, int i, int j, boolean[][] visited){
for(int x = -1; x<=1; x++){
for(int y=-1; y<=1; y++){
if(inBounds(grid, i+x, j+y), !visited[i+x][j+y]){
traverse(grid, i+x, j+y, copyOfAndSet(visited, i+x, j+y));
}
}
}
}
``````

assume inBounds exists and copyOfAndSet exists and is O(1) (not O(n*n)) as I have implemented this with bitwise operations but for clarity have used an array of booleans here.

What is the running time of the algorithm above on a NxN grid.

Thanks

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What exactly does `inBounds` do? Is it just checking whether `x` and `y` are in the bounds of `grid`? And does `copyOfAndSet` really copy the array? –  Gumbo Jul 3 '11 at 9:40
inBounds does just what you said, in my real implementation I dont use a visited array instead I use an integer and set bits in O(1) time to track what nodes have been visited, hence I said for the purpose of this assume copyOfAndSet is an O(1) operation as to not complicate the algorithm. Does that make sense? –  Aly Jul 3 '11 at 9:49
I still don’t get what you’re trying to do. What do you mean by “travel down every path without crossing over on myself”? Travel down from where to where? –  Gumbo Jul 3 '11 at 11:18
Starting at a cell, let's say (0,0) I want to go to every child and from there visit every cell in the grid at most once, where each path is evaluated in isolation. –  Aly Jul 3 '11 at 11:34
Gumbo, Please see my comment to @Szabolcs, I think that correctly summaries what I am trying to do. –  Aly Jul 3 '11 at 11:39

If I understand your question, you want to enumerate all self avoiding walks on a 2D grid. (You said "travel down every path without crossing over on myself")

http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.8.5913

The problem seems to be #P-complete, according to the paper.

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Might have misunderstood the question, let me know if this is useful. –  Szabolcs Jul 3 '11 at 11:07
That sounds right - I will google an let you know, thanks! –  Aly Jul 3 '11 at 11:35
Using this terminology, it would appear that given a starting cell(i,j) I am trying to traverse all self avoiding walks from it, to quote wikipedia: "Finding the number of such paths is conjectured to be an NP-hard problem." –  Aly Jul 3 '11 at 11:38
That does not mean you cannot calculate the complexity of this specific algorithm. The number of paths is an exact number, O analysis is a completely different thing. –  Karoly Horvath Jul 3 '11 at 13:46
@yi_H yes, but for an NxN grid this would be NP Hard –  Aly Jul 4 '11 at 17:04

First of all your algorithm can traverse diagonally, I'm not sure that's what you wanted... second: it should first visit the starting node (do a copyOfAndSet), but your algorithm first moves to the direction (-1, -1).

When traversing the array the algorithm visits every node and in every node it checks the 9 neighbours (it should check 8 BTW, (0, 0) doesn't make sense). For the `NxN` grid this is 9*N*N or simply `O(N^2)` If copyOfAndSet does actually copy the array then it's N*N work for each cell so it's `O(N^4)`.

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Hi, the (i+0,j+0) coords wont be checked as the would have been set in the visited array ( I should have stated this), so this makes at most 8 neighbours visited. Secondly, I do want it to traverse diagonally as one possible path, I want it to traverse every possible path that it can from the starting position without creating a loop –  Aly Jul 3 '11 at 9:52
Also, As stated above in the question please assume copyOfAndSet is an O(1) operation as I am not actually using a boolean array but instead passing an int around and setting bits (which is O(1)) –  Aly Jul 3 '11 at 9:54
Well, your code just traverses one path. I can only calculate the complexity for the code you provided. –  Karoly Horvath Jul 3 '11 at 9:57
The code doesn't just traverse the diagonal path, once it has finished traversing the diagonal path it will backtrack and traverse the others –  Aly Jul 3 '11 at 9:58
Yes, I also though that. I said your code only traverses one complete/possible path, that is, it visits every node once and then it finishes. –  Karoly Horvath Jul 3 '11 at 10:02