# Summary:

I have an array `x`

of length `n`

and can run all kinds of `O(nlog(n))`

operations on `x`

and cache results. E.g. I can pre-compute `indices = argsort(x)`

and `order = argsort(argsort(x))`

. Now, given `sample`

, which is an array of indices `0`

to `n`

of length at most `n`

, I would like to compute `argsort(x[sample])`

in `O(length(sample))`

time (or as fast as possible). Is this possible?

# Background:

To train a decision tree on a dataset `(X, y)`

, at each split we are given an array with indices corresponding to obervations at the node (`sample`

), and need to compute `y[argsort(X[sample, i])]`

for each feature `i`

in my dataset. A random forest is an ensemble of decision trees trained on `X[sample, :]`

where `sample`

is a length `n`

array of indices . I am wondering if it is possible to only sort each feature once (i.e. pre-compute `argsort(X[:, i])`

for each `i`

) and reuse this in every tree.

One can assume that `sample`

is sorted.

# Example

Consider `x = [0.5, 9.5, 2.5, 8.5, 6.5, 3.5, 5.5, 4.5, 1.5, 7.5]`

. Then `indices = argsort(x) = [0, 8, 2, 5, 7, 6, 4, 9, 3, 1]`

. Let `sample = [9, 9, 5, 6, 4]`

. we would like to obtain `argsort(x[sample]) = [2, 3, 4, 0, 1]`

without any sorting / in `O(length(sample))`

time.

# Ideas

Given `samples`

, we can compute `counts = tabulate(samples)`

. For the above example this would be equal to `[0, 0, 0, 0, 1, 1, 1, 0, 0, 2]`

. If `inverse_tabulate`

is the inverse of `tabulate`

(irgnoring order), then `inverse_tabulate(tabulate(samples)[indices]) = argsort(x[samples])`

. However to my best understanding `inverse_tabulate`

is optimally `O(n)`

in time, which is suboptimal if `length(sample) << n`

.

# References

This question discusses the runtime of decision trees. This lecture script mentiones on page 6, paragraph 4:

(Many implementations such as scikit-learn use efficient caching tricks to keep track of the general order of indices at each node such that the features do not need to be re-sorted at each node; hence, the time complexity of these implementations merely is O(m · n log(n)).)

This *caching* however seems to only be within one tree. Also, looking at the scikit-learn tree source code, the `samples`

appear to be re-sorted at each step / for each split.