Yes, it is possible.

We will borrow the typical computational geometry "scan line" trick.

First, let's answer an easier (but closely related) question. Instead of reporting how many other intervals each interval contains, let's report how many intervals each is *contained in*. So for your example with only two intervals, interval `I0 = [1,4]`

has value zero because it is contained in zero intervals, while `I1 = [2,3]`

has value one because it is contained in one interval.

You will see in a minute (a) why this question is easier and (b) how it leads to the answer for the original question.

To solve this easier question: Take all starting *and ending* points -- all of the a_{i} and b_{i} -- and put them into a master list. Call each element of this list an "event". So an event would be something like "interval I_{37} started" or "interval I_{23} ended".

Sort this list of events and process it in order.

As you process the list of events, maintain a set S of "active intervals". An interval is "active" if we have encountered its start event but not its ending event; that is, if we are within that interval.

Now, whenever we see an ending event b_{j}, we are ready to compute how many intervals contain I_{j} (= [a_{j}, b_{j}]). All we need to do is examine the set S of active intervals and determine how many of them started before a_{j}. That is our answer for how many intervals contain interval I_{j}.

To do this efficiently, keep S itself sorted by starting point; e.g., by using a self-balancing binary tree.

Sorting the list of events is O(2n log 2n) = O(n log n). Adding or removing an element from a self-balancing binary tree is O(log n). Asking "how many elements of the self-balancing binary tree are less than x?" is also O(log n). Therefore this entire algorithm is O(n log n).

So, that solves the easy question. Call that the "easy algorithm". Now for what you actually asked.

Think of the number line as extending to infinity and wrapping around to -infinity, and define an interval with b_{i} < a_{i} to start at a_{i}, stretch to infinity, wrap to minus infinity, and end at b_{i}.

For any interval I_{j} = [a_{j}, b_{j}], define Complement(I_{j}) as the interval [b_{j}, a_{j}]. (For example, the interval [2, 3] starts at 2 and ends at 3; so Complement([2,3]) = [3,2] starts at 3, stretches to infinity, wraps to -infinity, and ends at 2.)

Observe that interval I contains interval J if and only if Complement(J) contains Complement(I). (Prove this.)

So, we can answer your original question simply by running the "easy algorithm" on the set of complements of all of the intervals. That is, start your scan at -infinity with the set S of "active intervals" containing *all* intervals (because all complements contain infinity/-infinity). Keep S sorted by end point (i.e. start point of complement).

Sort all start points and end points and process them in order. When you encounter a starting point for interval I_{j} (= [a_{j}, b_{j}]), you are actually hitting the end point of its complement... So remove I_{j} from S, query S to see how many of its endpoints (i.e. complement start points) come before b_{j}, and report that as the answer for I_{j}. If you later encounter the end point of I_{j}, you are encountering the start point of its complement, so you need to add it back into the set S of active intervals.

This final algorithm is O(n log n) for the same reasons the "easy algorithm" was.

[Update]

One clarification, one correction, one comment...

Clarification: Of course, the "self-balancing binary tree" has to be augmented such that each sub-tree knows how many elements it contains. Otherwise, you cannot answer "how many elements are less than x?" This augmentation is straightforward to maintain, but it is not something that every implementation provides; e.g. the C++ `std::set`

does not, to my knowledge.

Correction: You do *not* want to add any elements back in to the set S of active intervals; in fact, doing so can result in the wrong answer. For example, if the intervals are just [1,2] and [3,4], you would hit 1 (and remove [1,2] from the set), then 2 (and add it back in again), then 3... And since 2<4, you would conclude that [3,4] contains [1,2]. Which is wrong.

Conceptually, you already processed all of the "start events" for the complement intervals; that is why S begins will all intervals inside of it. So all you need to worry about are the ending points; you do *not* want to add any elements to S, ever.

Put another way, instead of having the intervals wrap around, you can think of [b_{i},a_{i}] (where b_{i} > a_{i}) as meaning [b_{i} - infinity, a_{i}] with no wrap-around. The logic still works, but the processing is more clear: First you process all of the "whatever - infinity" terms (i.e. the end points), then you process the others (i.e. the start points).

With this correction, I am pretty sure my solution actually works. This formulation also extends -- I think -- to the case where you have both normal and "backward" intervals together in one input.

Comment: This problem is tricky because if you have to *enumerate* the set of all intervals contained within every interval, the output itself can be O(n^2). So any working approach has to somehow count the intervals without even being able to identify them :-).