Why is std::map implemented as a redblack tree?
There are several balanced binary search trees (BSTs) out there. What were design tradeoffs in choosing a redblack tree?
Why is std::map implemented as a redblack tree? There are several balanced binary search trees (BSTs) out there. What were design tradeoffs in choosing a redblack tree? 


It really depends on the usage. AVL tree has higher complexity of rebalancing. So if your application doesn't have too many insertion and deletion operations, but weights heavily on searching, then AVL tree probably is a good choice. std::map uses RedBlack tree as it gets a reasonable tradeoff between the complexity of node insertion/deletion and searching. 


Probably the two most common self balancing tree algorithms are RedBlack trees and AVL trees. To balance the tree after an insertion/update both algorithms use the notion of rotations where the nodes of the tree are rotated to perform the rebalancing. While in both algorithms the insert/delete operations are O(log n), in the case of RedBlack tree rebalancing rotation is an O(1) operation while with AVL this is a O(log n) operation, making the RedBlack tree more efficient in this aspect of the rebalancing stage and one of the possible reasons that it is more commonly used. RedBlack trees are used in most collection libraries, including the offerings from Java and Microsoft .NET Framework. 


AVL trees have a maximum height of 1.44logn, while RB trees have a maximum of 2logn. Inserting an element in a AVL may imply a rebalance at one point in the tree. The rebalancing finishes the insertion. After insertion of a new leaf, updating the ancestors of that leaf has to be done up to the root, or up to a point where the two subtrees are of equal depth. The probability of having to update k nodes is 1/3^k. Rebalancing is O(1). Removing an element may imply more than one rebalancing (up to half the depth of the tree). RBtrees are Btrees of order 4 represented as binary search trees. A 4node in the Btree results in two levels in the equivalent BST. In the worst case, all the nodes of the tree are 2nodes, with only one chain of 3nodes down to a leaf. That leaf will be at a distance of 2logn from the root. Going down from the root to the insertion point, one has to chnage 4nodes into 2nodes, to make sure any insertion will not saturate a leaf. Coming back from the insertion, all these nodes have to be analysed to make sure they correctly represent 4nodes. This can also be done going down in the tree. The global cost will be the same. There is no free lunch! Removing an element from the tree is of the same order. All these trees require that nodes carry information on height, weight, color, etc. Only Splay trees are free from such additional info. But most people are afraid of Splay trees, because of the ramdomness of their structure! Finally, trees can also carry weight information in the nodes, permitting weight balancing. Various schemes can be applied. One should rebalance when a subtree contains more than 3 times the number of elements of the other subtree. Rebalancing is again done either throuh a single or double rotation. This means a worst case of 2.4logn. One can get away with 2 times instead of 3, a much better ratio, but it may mean leaving a little less thant 1% of the subtrees unbalanced here and there. Tricky! Which type of tree is the best? AVL for sure. They are the simplest to code, and have their worst height nearest to logn. For a tree of 1000000 elements, an AVL will be at most of height 29, a RB 40, and a weight balanced 36 or 50 depending on the ratio. There are a lot of other variables: randomness, ratio of adds, deletes, searches, etc. 


It is just the choice of your implementation  they could be implemented as any balanced tree. The various choices are all comparable with minor differences. Therefore any is as good as any. 

