STL __merge_without_buffer algorithm?

Where can I get a decent high-level description of the algorithm used in `__merge_without_buffer()` in the C++ STL? I'm trying to reimplement this code in the D programming language, with some enhancements. I can't seem to grok what it's doing at the algorithmic level from just reading the STL source code because there are too many low-level details obscuring it. Also, I don't want to just blindly translate the code because then, if it didn't work I wouldn't know why, and I wouldn't be able to add my enhancements.

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`__merge_without_buffer()` is performing an in-place merge, as the merge step of an in-place merge sort. It takes as input two ranges of data `[first, middle)` and `[middle, last)` which are assumed to already be sorted. The `len1` and `len2` parameters are equal to the lengths of the two input ranges, namely `(middle - first)` and `(last - middle)` respectively.

First, it picks a pivot element. Then, it rearranges the data into the order `A1 B1 A2 B2`, where `A1` is the set of elements in `[first, middle)` that are less than the pivot, `A2` is the set of elements in `[first, middle)` greater than or equal to the pivot, `B1` is the set of elements in `[middle, last)` less than the pivot, and `B2` is the set of elements in `[middle, last)` greater than or equal to the pivot. Note that the data is originally in the order `A1 A2 B1 B2`, so all we need to do is to turn `A2 B1` into `B1 A2`. This is with a call to `std::rotate()`, which does just that.

Now we've separated out the elements which are less than the pivot (`A1` and `B1`) from those that are greater than or equal to the pivot (`A2` and `B2`), so now we can recursively merge the two subranges `A1 A2` and `B1 B2`.

How do we choose a pivot? In the implementation I'm looking at, it chooses the median element from the larger subrange (i.e. if `[first, middle)` has more elements than `[middle, last)`, it chooses the median of `[first, middle)`; otherwise, it chooses the median of `[middle, last)`). Since the subranges are already sorted, choosing the median is trivial. This pivot choice ensures that when recursively merging the two subranges, each subproblem is no more than 3/4 the size of the current problem, because in the worst case, at least 1/4 of the elements are larger than or smaller than the pivot.

What is the running time of this? The `std::rotate()` call takes O(N) time, and we make two recursive calls to ourselves. This equates to a running time of O(N log N). However, note that this is only one step in mergesort: remember that in mergesort you first recursively sort both halves and then merge. Thus, the recurrence relation for the running time of mergesort is now:

`T(N) = 2T(N/2) + O(N log N)`

Plug this into the Master theorem, and you get that mergesort now runs in O(N log2 N) time!

As an interesting final point, consider the following three qualities of a comparison-based sorting algorithm:

1. In-place
2. Stable
3. Runs in O(N log N) time

You can usually only get 2 of these at once - quicksort gets you (1) and (3), mergesort gets you (2) and (3), and an in-place mergesort gets you (1) and (2). Non-comparison-based sorts such as count sort can achieve all 3, but those sorts can only sort certain data types. It's possible there exists a comparison-based sort which achieves all 3, but if there is, I'm not aware of its existence, and it's almost certainly much more complicated.

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Does O(N log2 N) mean N (log N)^2? I was confused, because I thought log2 meant log_2, but the base is irrelevant here. Also, is the last part "you can only get 2 of these at once" strictly true, or is it simply that the algorithms that get all three are complicated? My guess is the latter? –  A. Rex Jan 13 '09 at 5:42
I've edited to address your questions. I messed up the HTML superscript tag. log^2 N means (log N)^2. Although base 2 is implied, the actual base is irrelevant, since it's a constant factor that gets eaten up by the big-O notation. –  Adam Rosenfield Jan 13 '09 at 5:51
In paragraph 3, I think you mean that subranges A1 and B1 get merged together recursively, and subranges A2 and B2 get merged recursively, right? After rotation, there is no subrange A1 A2 anymore. –  Rob Kennedy Jan 13 '09 at 5:56
Thanks, but now that I know it's O(N log N) not O(N) I'm not even sure I want to bother implementing it anymore, though I think it's a really cool algorithm, so I might just to see how slow it is in practice. –  dsimcha Jan 13 '09 at 14:51
Note that it's only called when you're low on memory. When callers can allocate a temporary buffer, they don't call the in-place version. They call the O(n) "adaptive" version instead. When it's between "slow" and failure, choose the former. –  Rob Kennedy Jan 13 '09 at 15:05