# recursive ceiling java

This is a homework question, so a basic recursive algorithm is all I'm really after. I am working on floor/ceiling methods for an AATree. My current tree has this structure:

``````        40
20        60
10  30    50    80
70  90
100
``````

(Level Order). I have an iterative solution for my floor method:

`````` /**
* Returns the greatest element in the set <= the_target.
* Strings are compared by ASCII values.
*
* @param the_target Element to compare set values with.
* @return Greatest element <= the_target, null if no such element exists.
*/
public E floor(final E the_target) {
AANode<E> current_node = my_root;
E result = null;
int root_value = compare(current_node.my_element, the_target);
while (true) {
if (root_value == 0) {
if (current_node.my_left.equals(my_null_node)
&& current_node.my_right.equals(my_null_node)) {
break;
}
result = current_node.my_element;
break;
}
if (contains(the_target)) {
result = the_target;
break;
} else if (root_value > 0) {
if (current_node.my_left.my_element == null) {
break;
}
current_node = current_node.my_left;
root_value = compare(current_node.my_element, the_target);
} else {
if (current_node.my_right.my_element == null) {
result = current_node.my_element;
break;
}
result = current_node.my_element;
current_node = current_node.my_right;
root_value = compare(current_node.my_element, the_target);
}
}
return result;
}
``````

But I want to make my ceiling() method recursive. It has to have this method signature:

``````  /**
* Returns the smallest element in the set >= the_target.
*
* @param the_target Element to compare set values with.
* @return Smallest element >= the_target, null if no such element exists.
*/
public E ceiling(final E the_target);
``````

and I was going to implement this using a helper recursive method that returns E. I am trying to get my logic right and would love some algorithm suggestions.

Thanks everyone for your help! I got it.

`````` /**
* Helper recursive method for ceiling().
*
* @param the_root The current node.
* @param the_smallest The previous smallest element.
* @param the_target The target for ceiling.
* @return The ceiling element of the tree.
*/
private E findCeiling(final AANode<E> the_root, final AANode<E> the_smallest,
final E the_target) {
AANode<E> small = the_smallest;
if (compare(the_target, small.my_element) > 0) {
small = the_root;
}
// base case
if (the_root.my_left.my_element == null
&& the_root.my_right.my_element == null) {
return small.my_element;
} else {
if (compare(the_target, the_root.my_element) > 0) {
if (compare(the_smallest.my_element, the_root.my_element) > 0) {
small = the_root;
}
return findCeiling(the_root.my_right, small, the_target);
} else {
if (compare(the_smallest.my_element, the_root.my_element) > 0) {
small = the_root;
}
return findCeiling(the_root.my_left, small, the_target);
}
}
}
``````
-
unless your class assignment states that you must use recursion, both of these are better solved with a simple loop. In general, I view recursion as a terrible solution to any problem. –  DwB Mar 1 '13 at 19:07
Have you taken a crack at it yet? –  Mark Peters Mar 1 '13 at 19:08
Im working on it again right now, more to come ;) –  David Everitt Jr Mar 1 '13 at 19:52

You want to traverse the tree and keep track of the smallest value in the set seen so far that is less than target. Lets call this value `SGT`

Your helper routine needs to take in the current node being examined, and the current `SGT` value.

Here's a hint to get you started...

`````` public E ceiling(final E target) {
return ceilingHelper(root, root.my_element, target);
}

private E ceilingHelper(final AANode<E> current_node,
final E SGT,
final E target) {
//now do you get the idea ?  your recursion will need a base case
//and a recursive step.  you can traverse the tree using a depth first
//search
}
``````
-
Thats helpful. I was heading in that direction but with the method signature: E findCeiling(AANode<E> the_root, E the_smallest, E the_target, boolean the_found); –  David Everitt Jr Mar 1 '13 at 19:53
If this helps, you should upvote or accept as the answer. –  Amir Afghani Mar 1 '13 at 20:24

I don't think providing an exact solution would be appropriate but you should look at http://en.wikipedia.org/wiki/Tree_traversal. There are all the general algorithms you need to do this recursively.

Generally the recursive solution involves defining the problem as a subproblem. As a hint, how are the ceils of two neighboring subtrees related? Also think about what the basecase would be where recursion ends. What is the ceil of a leaf node?

Recursive solutions for tree problems can be very very concise and simple.

-
Thank you Daniel. I wasnt looking for an answer, so this is helpful. –  David Everitt Jr Mar 1 '13 at 19:29
FYI, the acceptable type of help I can receive is basic logic and higher level abstraction –  David Everitt Jr Mar 1 '13 at 19:55