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 2^{32} elements in my array, so 2^{n} can be implemented in O(1) using bit-shifts. Possibly `log_2`

as well (???)

`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