Time complexity of recursive algorithm

I have a grid with x-sided field in it. Every field contains a link to it's x surrounding fields. [x is constant]

I have an algorithm which is implemented in this field, (which can probably be optimized):

[java like pseudocode]

``````public ArrayList getAllFields(ArrayList list) {

for each side {
if ( ! list.contains(neighbour) && constantTimeConditionsAreMet()) {
neighbour.getAllFields(list) //Recursive call
}
}

return list;

}
``````

I'm having trouble finding the time complexity.

• `ArrayList#contains(Object)` runs in linear time
• How do i find the time complexity? My approach is this:

``````T(n) = O(1) + T(n-1) +
c(nbOfFieldsInArray - n) [The time to check the ever filling ArrayList]

T(n) = O(1) + T(n-1) + c*nbOfFieldsInArray - cn
``````

Does this give me `T(n) = T(n-1) + O(n)`?

-
Where's the recursive call meant to happen? Is 'getContinent' meant to be 'getAllFields'? –  Gian Apr 26 '11 at 21:19
I put a comment in the code :) –  Samuel Apr 26 '11 at 21:22
Change the list to a hash table and you have an O(n) algorithm where n = number of fields :) –  Antti Huima Apr 27 '11 at 21:14
I was planning on doing that. Would you agree the algorithm is O(n^2) now? –  Samuel Apr 28 '11 at 9:28

The comment you added to your code is not helpful. What does `getContinent` do?
In any case, since you're using a linear search (`ArrayList.contains`) for every potential addition to the list, then it looks like the complexity will be Omega(n^2).