Actually, if the array is static and you want to make multiple queries for `O(log n)`

each, you don't need that complicated data structures.

What you're actually asking for - "the number that is farthest (towards the left) from the number at index i and is less than k." - can be transformed to "the leftmost number before `i`

that is less than `k`

". Then you can see this as the following:

- find the leftmost number that is less than K - say it's at position
`j`

;
- if
`j < i`

, `j`

is the answer to the question
- otherwise, there is no such number - all the entries before position
`i`

are larger than or equal to `k`

.

To answer the first of these questions, all you need to know is: for position `i`

, what is the smallest number on positions `0..i`

- let's call this `min(i)`

. Notice that `min`

is a monotonically decreasing function of `i`

- if the `min(5) = 10`

, there is no way that `min(6) = 15`

, since `min(6)`

is the smallest number on positions `0`

to `6`

, and that necessarily includes the smallest number on positions `0`

to `5`

, which we know to be 10. (`min`

is fairly trivial to construct - if we call the array `a`

, then: `min(0) = a[0]`

, and `min(i) = minimum(min(i - 1), a[i])`

for `i > 0`

.)

With this information, you can perform a binary search for the leftmost index `i`

such that `min(i) < k`

. Then, by the construction of `min`

, we know that all numbers on positions from `0`

to `i - 1`

are greater than or equal to `k`

. So `i`

must be the answer of the question.