This is tricky to get right in general, especially to handle degenerate series that are already sorted, or have a bunch of values at the "start" of the list but the end of the list has values in a different range.

The basic idea of making a histogram is most promising. This lets you accumulate distribution information and answer queries (like median) from it. The median will be approximate since you obviously don't store all values. The storage space is fixed so it will work with whatever length sequence you have.

But you can't just build a histogram from say the first 100 values and use that histogram continually.. the changing data may make that histogram invalid. So you need a dynamic histogram that can change its range and bins on the fly.

Make a structure which has N bins. You'll store the X value of each slot transition (N+1 values total) as well as the population of the bin.

Stream in your data. Record the first N+1 values. If the stream ends before this, great, you have all the values loaded and you can find the exact median and return it. Else use the values to define your first histogram. Just sort the values and use those as bin definitions, each bin having a population of 1. It's OK to have dupes (0 width bins).

Now stream in new values. For each one, binary search to find the bin it belongs to.
In the common case, you just increment the population of that bin and continue.
If your sample is beyond the histogram's edges (highest or lowest), just extend the end bin's range to include it.
When your stream is done, you find the median sample value by finding the bin which has equal population on both sides of it, and linearly interpolating the remaining bin-width.

But that's not enough.. you still need to ADAPT the histogram to the data as it's being streamed in. When a bin gets over-full, you're losing information about that bin's sub distribution.
You can fix this by adapting based on some heuristic... The easiest and most robust one is if a bin reaches some certain threshold population (something like 10*v/N where v=# of values seen so far in the stream, and N is the number of bins), you SPLIT that overfull bin. Add a new value at the midpoint of the bin, give each side half of the original bin's population. But now you have too many bins, so you need to DELETE a bin. A good heuristic for that is to find the bin with the smallest product of population and width. Delete it and merge it with its left or right neighbor (whichever one of the neighbors itself has the smallest product of width and population.). Done!
Note that merging or splitting bins loses information, but that's unavoidable.. you only have fixed storage.

This algorithm is nice in that it will deal with **all** types of input streams and give good results. If you have the luxury of choosing sample order, a random sample is best, since that minimizes splits and merges.

The algorithm also allows you to query any percentile, not just median, since you have a complete distribution estimate.

I use this method in my own code in many places, mostly for debugging logs.. where some stats that you're recording have unknown distribution. With this algorithm you don't need to guess ahead of time.

The downside is the unequal bin widths means you have to do a binary search for each sample, so your net algorithm is O(NlogN).