Is it possible to iterate through a binary tree using iteration instead of recursion?

In school, when we need to iterate through a tree (e.g. binary search tree), we were always taught to iterate through the tree recursively.

Since every recusion can be written as iteration, is it possible to solely use iteration to access the elements of a tree?

I am asking this in context of C++

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you can always replace recursion with a loop and a stack. –  Karoly Horvath Mar 23 at 18:49
cool, thanks. I always have trouble understanding the program flow of a recursion. –  user3437460 Mar 23 at 18:59
I think you have to understand it once well, after that, all recursions will make sense. Don't replace it with something more complicated just because you don't understand it. –  Karoly Horvath Mar 23 at 19:10

Yes.

For each node you process, store the children into a queue. This goes on for the rest of the nodes in the same level. After processing all the nodes in that level, you then process the queued children. In turn, you store the children's children into the queue. This goes on until you hit the bottom.

For instance the following:

D
B       F
A   C   E   G

// 1
Current: D
Queue: B, F

// 2
Current: B, F
Queue: A, C, E, G

// 3
Current: A, C, E, G
Queue: no more!

Iteration is much more intricate than recursion since you need to implement a queue (if not provided) as well as some additional logic for unbalanced trees. However, iteration is more "memory-friendly" because your queue is just a bunch of pointers to nodes whereas recursion eats up the stack per call.

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I am glad you said yes, because I always thought recursive is the only way to access the nodes in the tree and this misconception kept me away from using tree structure (which IMO tree is actually a powerful structure to use) as I don't really have gd understanding on how to use recursion. –  user3437460 Mar 23 at 18:43
@user3437460 Depends on the developer, as well as the use. Recursion for me is easier to implement than iteration, as recursion is much straight-forward. However, iteration is "memory-friendly" since it does not eat up the stack. –  Joseph the Dreamer Mar 23 at 18:45
Thanks for the reply. May I know, what about non-binary trees which have more than 2 child nodes? Is it still possible to do it iteratively? –  user3437460 Mar 23 at 18:49
@user3437460 Same applies. Just queue up the child nodes. The concept behind iteration of trees is that you are doing it "by level" (breadth first) rather than by branch (depth first) as in recursion. –  Joseph the Dreamer Mar 23 at 18:52
@user3437460 read karoly-horvath comment in your question. –  agarwaen Mar 23 at 18:52

Yes. There exists a method called threading of a tree, which basically joins the nodes in a particular traversal order. So, you can traverse through the whole tree iteratively just like any other traversal recursively.

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It depends on what kind of traversal you want to do (Preorder, Inorder, Postorder). If you want to replicate the recursive behavior then you need to simulate the stack recursion. It may be useful in a few scenarios but recursion is simpler.

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The most common implementation of std::set and std::map is a Red-Black Tree; both can be iterated over with only two iterators (obtained by calls to begin and end); thus, not only is it possible to iterate without recursion, it's even possible to iterate in O(1) space providing the tree is structured correctly.

There are multiple representations for a tree:

• parent to children access: the parent may have one pointer to the first child, a pointer to the first and last children or an array of pointers to each child
• children to parent access: a child may or may not have a pointer to its parent
• sibling access: a child may or may not have a pointer to its predecessor and successor

In general, if:

• a child has a pointer to its parent
• it's possible to access the first child of a parent and know when you reach the last child

then you can implementation iteration in O(1) space; and you may even chose to "visit" the parent right before, in the middle of, or right after its children.

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