Has anyone seen an implementation of the STL where stl::set is not implemented as a red-black tree?

The reason I ask is that, in my experiments, B-trees outperform std::set (and other red-black tree implementations) by a factor of 2 to 4 depending on the value of B. I'm curious if there is a compelling reason to use red-black trees when there appear to be faster data structures available.

  • I'm not an algorithms expert by any means, but std::set and friends come with stringent maximum complexity ("big-O") requirements set by the standard. Would an alternative implementation meet all of these requirements? Oct 24, 2014 at 15:02
  • you can have a look here: Why you shouldn't use set (and what you should use instead).
    – davidhigh
    Oct 24, 2014 at 15:09
  • @TristanBrindle: Yes. B-2B trees give the same complexity guarantees. (In fact, red-black trees are actually a simulation of 2-3-4 trees using binary trees; this makes them more complicated and slower.)
    – Pat Morin
    Oct 24, 2014 at 15:19
  • 1
    @davidhigh: I did see that document in my searches. It doesn't answer my question. It suggests using linear update/search time data structures instead of the O(log n) time structures. That's fine if you don't intend to do many searches or modifications, but stl::set still fills a pretty important role in the STL.
    – Pat Morin
    Oct 24, 2014 at 15:24

2 Answers 2


Some folks over at Google actually built a B-tree based implementation of the C++ standard library containers. They seem to have much better performance than standard binary tree implementations.

There is a catch, though. The C++ standard guarantees that deleting an element from a map or set only invalidates other iterators pointing to the same element in the map or set. With the B-tree based implementation, due to node splits and consolidations, the erase member functions on these new structures may invalidate iterators to other elements in the tree. As a result, these implementations aren't perfect replacements for the standard implementations and couldn't be used in a conformant implementation.

Hope this helps!

  • Aha. That's what I was looking for. I figured there had to be a catch. I didn't realize that the standard allowed for modifications to the tree when there were other iterators into the tree. This is a pretty non-standard use-case though. It should be possible to hack around it when it occurs.
    – Pat Morin
    Oct 24, 2014 at 17:02
  • 1
    Reading up on the page you pointed to, I see they thoughtfully already provided such a hack: code.google.com/p/cpp-btree/wiki/…
    – Pat Morin
    Oct 24, 2014 at 17:47

There is at least one implementation based on AVL trees instead of red-black trees.

I haven't tried to verify conformance of this implementation, but at least (unlike a B-tree based implementation) it at least could be written to conform perfectly to the requirements of the standard.

  • 1
    I'm not sure AVL trees will do; insert and erase require amortized constant modification times when changing a known location, and AVL trees don't supply this.
    – jbapple
    Oct 26, 2014 at 16:36
  • Unfortunately it is GNU GPL licensed.
    – plasmacel
    Nov 2, 2017 at 14:06

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