You have a vector of entries, say `[x1, x2, ..., xN]`

, and you're aware of the fact that the distribution of the queries is given with probability `1/x`

, on the vector you have. This means your queries will take place with that distribution, i.e., on each consult, you'll take element `xN`

with higher probability.

This causes your binary search tree to be balanced considering your labels, but not enforcing any policy on the search. A possible change on this policy would be to relax the constraint of a balanced binary search tree -- smaller to the left of the parent node, greater to the right --, and actually choosing the parent nodes as the ones with higher probabilities, and their child nodes as the two most probable elements.

Notice this **is not** a binary search tree, as you are not dividing your search space by two in every step, but rather a rebalanced tree, with respect to your search pattern distribution. This means you're worst case of search may reach `O(N)`

. For example, having `v = [10, 20, 30, 40, 50, 60]`

:

```
30
/ \
20 50
/ / \
10 40 60
```

Which can be reordered, or, **rebalanced**, using your function `f(x) = 1 / x`

:

```
f([10, 20, 30, 40, 50, 60]) = [0.100, 0.050, 0.033, 0.025, 0.020, 0.016]
sort(v, f(v)) = [10, 20, 30, 40, 50, 60]
```

Into a new *search tree*, that looks like:

```
10 -------------> the most probable of being taken
/ \ leaving v = [[20, 30], [40, 50, 60]]
20 30 ---------> the most probable of being taken
/ \ leaving v = [[40, 50], [60]]
40 50 -------> the most probable of being taken
/ leaving v = [[60]]
60
```

If you search for `10`

, you only need one comparison, but if you're looking for `60`

, you'll perform `O(N)`

comparisons, which does not qualifies this as a binary search. As pointed by @Steve314, the farthest you go from a fully balanced tree, the worse will be your worst case of search.

`1/x`

distribution – arunmoezhi May 8 '15 at 19:42