I have solution of this problem.
I have coded my solution in C#, because it is my strongest language, but I hope that you will catch a main idea. Let's suppose, that each tree node has 3 references: to left, right and parent nodes.
So we have BinaryTree. How could we print it? Obviously:
this._tree.Print();
That wasn't very difficult. But how could we build Print method, if we should avoid recursion (because the last one involves O(log(n)) memory)? Have you ever read about lazy lists (or streams)? Lazy list doesn't hold the whole list in memory, but knows how to calculate next item based on current item. In every moment lazy list allocates O(1) memory. So, suppose we have managed to describe lazy list for tree. Then Print method is very simple:
public static void Print<T>(this BinaryTree<T> tree)
where T : IComparable<T>
{
var node = new TreeNodeWalker<T>(tree.Root, WalkerState.FromParent);
while (node != null)
{
node = node.WalkNext();
}
}
During this code snippet you could find out one unfamiliar entity: TreeNodeWalker. This object holds tree node that should be walked, state that signals in what moment of traversing this walker was created and method which gives next walker. In short walker performs next actions:
- If we drop in any subtree from parent node, we should walk left subtree.
- If we emerges from left subtree, we should print node value and walk right subtree.
- If we emerges from right subtree we should walk parent.
It could be represented in code in the next way:
public class TreeNodeWalker<T>
where T:IComparable<T>
{
// Tree node, for which walker is created.
private readonly BinaryTreeNode<T> _node;
// State of walker.
private readonly WalkerState _state;
public TreeNodeWalker(BinaryTreeNode<T> node, WalkerState state)
{
this._node = node;
this._state = state;
}
public TreeNodeWalker<T> WalkNext()
{
if (this._state == WalkerState.FromParent)
{
// If we come to this node from parent
// we should walk left subtree first.
if (this._node.Left != null)
{
return new TreeNodeWalker<T>(this._node.Left, WalkerState.FromParent);
}
else
{
// If left subtree doesn't exist - return this node but with changed state (as if we have already walked left subtree).
return new TreeNodeWalker<T>(this._node, WalkerState.FromLeftSubTree);
}
}
else if (this._state == WalkerState.FromLeftSubTree)
{
// If we have returned from left subtree - current node is smallest in the tree
// so we should print it.
Console.WriteLine(this._node.Data.ToString());
// And walk right subtree...
if (this._node.Right != null)
{
//... if it exists
return new TreeNodeWalker<T>(this._node.Right, WalkerState.FromParent);
}
else
{
// ... or return current node as if we have returned from right subtree.
return new TreeNodeWalker<T>(this._node, WalkerState.FromRightSubTree);
}
}
else if (this._state == WalkerState.FromRightSubTree)
{
// If we have returned from right subtree, then we should move up.
if (this._node.Parent != null)
{
// If parent exists - we compare current node with left parent's node
// in order to say parent's walker which state is correct.
return new TreeNodeWalker<T>(this._node.Parent, this._node.Parent.Left == this._node ? WalkerState.FromLeftSubTree : WalkerState.FromRightSubTree);
}
else
{
// If there is no parent... Hooray, we have achieved root, which means end of walk.
return null;
}
}
else
{
return null;
}
}
}
You could see a lot of memory allocation in code and make decision that O(1) memory requirement is not fulfilled. But after getting next walker item, we don't need previous one any more. If you are coding in C++ don't forget to free memory. Alternatively, you could avoid new walker instance allocation at all with changing internal state and node variables instead (you should always return this reference in corresponding places).
As for time complexity - it's O(n). Actually O(3*n), because we visit each node three times maximum.
Good luck.