Consider an infinite binary tree defined as follows.

For a node labelled v, let its left child be denoted 2*v and its right child 2*v+1. The root of the tree is labelled 1.

For a given n ranges [a_1, b_1], [a_2, b_2], ... [a_n, b_n] for which (a_i <= b_i) for all i, each range [a_i,b_i] denotes a set of all integers not less than a_i and not greater than b_i. For example, [5,9] would represent the set {5,6,7,8,9}.

For some integer T, let S represent the union [a_i, b_i] for all i up to n. I need to find the number of unique pairs (irrespective of order) of elements x,y in S such that the lca(x,y) = T

(Wikipedia has a pretty good explanation of what the LCA of two nodes is.)

For example, for input:

```
A = {2, 12, 11}
B = {3, 13, 12}
T = 1
```

The output should be 6. (The ranges are [2,3], [12,13], and [11,12], and their union is the set {2,3,11,12,13}. Of all 20 possible pairs, exactly 6 of them ((2,3), (2,13), (3,11), (3,12), (11,13), and (12,13)) have an LCA of 1.)

And for input:

```
A = {1,7}
B = {2,15}
T = 3
```

The output should be 6. (The given ranges are [1,2] and [7,15], and their union is the set {1,2,7,8,9,10,11,12,13,14,15}. Of the 110 possible pairs, exactly 6 of them ((7,12), (7,13), (12,14), (12, 15), (13,14) and (13,15)) have an LCA of 3.)

`class Node { Node parent, first, second; }`

. You are using some weird notation that seems to be referring to the array indices at which you are storing node elements, but trees are not normally stored in arrays that way. – AJMansfield Mar 3 '14 at 15:01