AVL and Red black trees are both self-balancing except Red and black color in the nodes. What's the main reason for choosing Red black trees instead of AVL trees? What are the applications of Red black trees?


What's the main reason for choosing Red black trees instead of AVL trees?

Both red-black trees and AVL trees are the most commonly used balanced binary search trees and they support insertion, deletion and look-up in guaranteed O(logN) time. However, there are following points of comparison between the two:

  • AVL trees are more rigidly balanced and hence provide faster look-ups. Thus for a look-up intensive task use an AVL tree.
  • For an insert intensive tasks, use a Red-Black tree.
  • AVL trees store the balance factor at each node. This takes O(N) extra space. However, if we know that the keys that will be inserted in the tree will always be greater than zero, we can use the sign bit of the keys to store the colour information of a red-black tree. Thus, in such cases red-black tree takes no extra space.

What are the application of Red black tree?

Red-black trees are more general purpose. They do relatively well on add, remove, and look-up but AVL trees have faster look-ups at the cost of slower add/remove. Red-black tree is used in the following:

| improve this answer | |
  • 43
    In general, the rotations for an AVL tree are harder to implement and debug than that for a Red-Black tree. is not true. – Jingguo Yao Dec 7 '15 at 15:06
  • 9
    To be pedantic, the C++ standard does not mandate that std:: map and friends use any particular structure. That's left to the implementation, although libstdc++ and Dinkumware at least uses red-black trees, and it seems like you're right in practice. – mbozzi Mar 21 '16 at 17:44
  • 28
    The balance factor stored in each node of an AVL tree is two bits (-1 / 0 / +1). A red-black tree stores one bit of color information in each node. Thus in total both trees require O(N) memory for the extra information. – Seppo Enarvi Jan 19 '17 at 14:46
  • 7
    "For an insert intensive tasks, use a Red-Black tree." Why? AVL tree insertion only takes one rotation at worst, while Red Black tree can take two. – Daniel Jun 13 '17 at 22:05
  • 3
    This should be updated per Ben Pfaff's 2003 analysis of BST performance - AVL trees are more general purpose and perform better. Exact historical reasons for Java, C++ and the Linux kernel choosing the slower implementation would be interesting to track down. – David McManamon Oct 18 '18 at 20:10

Try reading this article

It offers some good insights on differences, similarities, performance, etc.

Here's a quote from the article:

RB-Trees are, as well as AVL trees, self-balancing. Both of them provide O(log n) lookup and insertion performance.

The difference is that RB-Trees guarantee O(1) rotations per insert operation. That is what actually costs performance in real implementations.

Simplified, RB-Trees gain this advantage from conceptually being 2-3 trees without carrying around the overhead of dynamic node structures. Physically RB-Trees are implemented as binary trees, the red/black-flags simulate 2-3 behaviour

As far as my own understanding goes, AVL trees and RB trees are not very far off in terms of performance. An RB tree is simply a variant of a B-tree and balancing is implemented differently than an AVL tree.

| improve this answer | |
  • 2
    AFIAK, an AVL tree has also O(1) rotation per insertion. For RB-tree and AVL - one insertion may have 1 or 0 rotations. If rotation happens, the algorithms stop. If it doesn't happen, usually, algorithms continue to check/repaint nodes from bottom to the root of the tree. So, sometimes rotation O(1) can be better because it eliminates scanning remaining items O(log(n)). Because AVL tree, in average, makes more rotation, AVL tree is, usually, has better balance ~1.44 log(N) than RB-tree 2 log(N). – Sergey Shandar Jan 23 '18 at 17:18

Our understanding of the differences in performance has improved over the years and now the main reason to use red-black trees over AVL would be not having access to a good AVL implementation since they are slightly less common perhaps because they are not covered in CLRS.

Both trees are now considered forms of rank-balanced trees but red-black trees are consistently slower by about 20% in real world tests. Or even 30-40% slower when sequential data is inserted.

So people who have studied red-black trees but not AVL trees tend to choose red-black trees. The primary uses for red-black trees are detailed on the Wikipedia entry for them.

| improve this answer | |
  • 1
    Funny! in my reading, the libavl article seems to say that AVL and RB are head-to-head, and neither is very clearly better than the other in general (which one is better depends on the workload). I don't see anywhere a claim that AVL is overall about 20% faster. – Stefan Mar 1 '19 at 19:38

Other answers here sum up the pros & cons of RB and AVL trees well, but I found this difference particularly interesting:

AVL trees do not support constant amortized update cost [but red-black trees do]

Source: Mehlhorn & Sanders (2008) (section 7.4)

So, while both RB and AVL trees guarantee O(log(N)) worst-case time for lookup, insert and delete, restoring the AVL/RB property after inserting or deleting a node can be done in O(1) amortized time for red-black trees.

| improve this answer | |
  • 1
    I believe, AVL tree insertion has the same/similar amortized cost but produces better balanced tree (1.44log(N) vs 2log(N)). In the same time, deletion in AVL tree may require more rotations. IMHO, this is addressed in WAVL en.wikipedia.org/wiki/WAVL_tree – Sergey Shandar Jan 23 '18 at 19:08

Programmers generally don't like to dynamically allocate memory. The problem with the avl tree is that for "n" elements you need atleast log2(log2(n))...(height->log2(n)) bits to store the height of the tree! So when you are handling enormous data you cannot be sure of how many bits to allot for storing height at each node.

For instance if you use 4 bytes int (32 bits) for storing height. Maximum height can be : 2^32 and hence Maximum number of elements you can store in the tree is 2^(2^32) --(seems to be very big but in this age of data nothing is too big I guess). And hence if you over shoot this limit you have to dynamically allocate more space for storing height.

This is an answer suggested by a professor at my university which seemed reasonable to me! Hope I make sense.

Edits:The AVL trees are more balanced compared to Red Black Trees, but they may cause more rotations during insertion and deletion. So if your application involves many frequent insertions and deletions, then Red Black trees should be preferred. And if the insertions and deletions are less frequent and search is more frequent operation, then AVL tree should be preferred over Red Black Tree. --Source GEEKSFORGEEKS.ORG

| improve this answer | |
  • 1
    I would say this is interesting but impractical. While it's true that in the most compact case it would be a difficult task to choose the most efficient number of bits to allocate for height, in practice any left-over space that is less than a byte will definitely be unused, and anything left over in a 4 or even 8 byte space will almost certainly go unused. Memory is not allocated unaligned for performance reasons greatly overriding the benefit of reclaiming a tiny amount of space. The pointers to the children and the value occupy 24 bytes; 8 more are unlikely to have any practical cost. – Mumbleskates Sep 28 '16 at 18:25
  • 4
    you need need atleast log2(log2(n))...(height->log2(n)) bits to store the height of [an AVL] tree I don't need the height of any node in an AVL-tree to implement it. You nee one bit of extra information for each node (I AM THE GREATEST (the sibling with highest sub-tree))); it is more convenient as well as conventional to have two extra bits (child is higher for left&right), as presented by A-V & L. – greybeard Jan 17 '17 at 3:12
  • 4
    2^(2^32) elements is a lot... like you could store every single molecule in the entire universe, and every possible pair of those molecules, and every possible triple, and still not even begin to come even remotely close to being within a tiny fraction of a tiny percentage of the cubed root of that number divided by a hundred quintillion. – semicolon Jan 19 '17 at 2:50
  • 4
    This is very misleading. First, we don't need to store the height in a node of an AVL tree. Second, even if we did, and even if the typical amount of available memory doubles every year, we still have 4 billion years until the height of our trees exceeds what can be stored in 32 bits. – Gassa Jan 19 '17 at 12:17
  • 3
    2^(2^32) objects is ridulously, insanely, absolutely more than any computer we can envision right now can ever hold. We're at something like 2^40. Check you're math again. – Stefan Reich Dec 26 '17 at 2:00

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.