# Determining the lowest child-node (descendant with greatest index) in an array-based binary-tree in O(1)?

Some binary-tree structures (such as heaps) can be implemented using an array by setting indices left-to-right, top-to-bottom

```           0
/        \
1          2
/   \      /   \
3     4    5     6
/ \   / \  / \   / \
7   8 9 10 11 12 13 14
... etc.
```

The children and parent of a node at index `x` can be found easily in O(1):

```child-left(x) = 2x+1
child-right(x) = 2x+2
parent(x) = (x-1)/2
```

But is there a way to find the lowest descendant of x in O(1) (ie. the descendant with highest index)? For instance, in the tree above, the lowest descendant of `x=0` would be 14, while for `x=1` it would be `10`. Note that for `x=1`, if there were only 10 elements in the tree, it should return `9` instead.

I can assume there will never be more than 232 elements in my array, so 2n can be implemented in O(1) using bit-shifts. Possibly `log_2` as well (???)

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As a silly cop-out answer, if you have at most 2^32 elements in the array, you could always just precompute everything and look up the answer in a lookup table in O(1). :-) –  templatetypedef Jul 16 '12 at 17:42
Is the binary tree necessarily a perfect binary tree (that is, no missing nodes), or might there be some nodes missing off the bottom level? –  templatetypedef Jul 16 '12 at 17:47
@templatetypedef: No, it is not necessarily perfect –  BlueRaja - Danny Pflughoeft Jul 16 '12 at 17:50
Why for `N=10` the lowest descendant of `1` is `9`?? Why not `7`? What meaning exactly do you put in the term "lowest" in this case? –  AnT Jul 16 '12 at 18:18
@AndreyT he describes it as "Descendant with the highest index" in latest edit –  Kevin DiTraglia Jul 16 '12 at 18:20

Well, I figured it out. The depth of node x is

```depth(x) = log2(x+1)
```

Similarly, the i-th left-child and i-th right-child of node `x` can easily be found:

```ithLeftChild(x, i) = 2i(x+1) - 1
ithRightChild(x, i) = 2i(x+2) - 2
```

The index of the left-most child at depth `d` is `ithLeftChild(x, d - depth(x))`, and similarly for the right-child.

Let's call the index of the last element `n`. So, now we can find the depth of `n`, and we can also find the indicies of `leftmostChild` and `rightmostChild` at that depth (which could be larger than the last element, meaning they don't actually exist).

Now we just have three cases:

• `n < leftmostChild`. Then our subtree has no elements at that depth, so the highest index must be `parent(rightmostChild)`.
• `leftmostChild <= n <= rightmostChild`. Then the highest index is necessarily `n`.
• `rightmostChild < n`. Then `rightmostChild` must be our highest index.

2i can be implemented in O(1) for reasonable `i` using bit-shifts; `log2(x)` can be implemented in O(1) using a 256-byte lookup table. So the overall algorithm is O(1).

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Was about to type this exact solution out and got distracted with work, +1 for figuring it out though. –  Kevin DiTraglia Jul 16 '12 at 19:07