# Tag Info

33

Part 1 - height As starblue says, height is just recursive. In pseudo-code: height(node) = max(height(node.L), height(node.R)) + 1 Now height could be defined in two ways. It could be the number of nodes in the path from the root to that node, or it could be the number of links. According to the page you referenced, the most common definition is for ...

31

Take this with a pinch of salt: B-tree when you're managing more than thousands of items and you're paging them from a disk or some slow storage medium. RB tree when you're doing fairly frequent inserts, deletes and retrievals on the tree. AVL tree when your inserts and deletes are infrequent relative to your retrievals.

23

You can measure the height of a branch at a given point to calculate the unbalance (remember a difference in height (levels) >= 2 means your tree is not balanced) int Tree::Height(TreeNode *node){ int left, right; if(node==NULL) return 0; left = Height(node->left); right = Height(node->right); if(left > right) ...

16

Assuming you may destroy the input trees: remove the rightmost element for the left tree, and use it to construct a new root node, whose left child is the left tree, and whose right child is the right tree: O(log n) determine and set that node's balance factor: O(log n). In (temporary) violation of the invariant, the balance factor may be outside the range ...

15

Both splay trees and AVL trees are binary search trees with excellent performance guarantees, but they differ in how they achieve those guarantee that performance. In an AVL tree, the shape of the tree is constrained at all times such that the tree shape is balanced, meaning that the height of the tree never exceeds O(log n). This shape is maintained on ...

14

Both the AVL tree and the B-tree are similar in that they are data structures that, through their requirements, cause the height of their respective trees to be minimized. This "shortness" allows searching to be performed in O(log n) time, because the largest possible number of reads corresponds to the height of the tree. 5 / \ 3 7 / / \ 1 6 ...

14

Red-Black trees are more general purpose. The do relatively well on add, remove, and look-up but AVL trees have faster look-ups at the cost of slower add/remove. Java's general policy is to provide the best general purpose data structures. It's also the same reason Java's default Array.sort(Object[] a) implementation is merge sort instead of quicksort.

13

A scapegoat tree possibly has the simplest balance-determination algorithm to understand. If any insertion causes the new node to be too deep, it finds a node around which to rebalance, by looking at weight balance rather than height balance. The rule for whether to rebalance on delete is also simple. It doesn't store any arcane information in the nodes. ...

13

Yes. The number of steps required to find an item depends on the distance between the item and the root. Since the AVL tree is packed tighter (i.e. it has a lower max height) it means more items are closer to the root than in the red-black case. The extra tight packing also means the AVL tree requires more work when inserting elements. The best choice for ...

11

AVL trees are intended for in-memory use, where random access is relatively cheap. B-trees are better suited for disk-backed storage, because they group a larger number of keys into each node to minimize the number of seeks required by a read or write operation. (This is why B-trees are often used in file systems and databases, such as SQLite.)

10

I don't think it's good to post complete codes for node balancing algorithms here since they get quite big. However, the Wikipedia article on red-black trees contains a complete C implementation of the algorithm and the article on AVL trees has several links to high-quality implementations as well. These two implementations are enough for most ...

10

Wait, wait, wait. You aren't really going to check the "height" of every branch each time you're inserting something, are you? Measuring the height means transversing all the sub-branch. Means - every insert into such a tree will cost O(N). If so - what do you need such a tree? You may use a sorted array as well: it gives O(N) insertion/deletion and O(log ...

9

To be balanced, every node in the tree must, either, have no children, (be a "leaf" node) Have two children. Or, if it has only one child, that child must be a leaf. In the chart you post, 9, 54 & 76 violate the last rule. Properly balanced, the tree would look like: Root: 23 (23) -> 14 & 67 (14) -> 12 & 17 (12) -> 9 (17) -> 19 ...

8

I think B+ trees are a good general-purpose ordered container data structure, even in main memory. Even when virtual memory isn't an issue, cache-friendliness often is, and B+ trees are particularly good for sequential access - the same asymptotic performance as a linked list, but with cache-friendliness close to a simple array. All this and O(log n) search, ...

8

If you want to make a maximally lopsided AVL tree, you are looking for a Fibonacci tree, which is defined inductively as follows: A Fibonacci tree of order 0 is empty. A Fibonacci tree of order 1 is a single node. A Fibonacci tree of order n + 2 is a node whose left child is a Fibonacci tree of order n and whose right child is a Fibonacci tree of order n + ...

8

The general idea behind this construction is to take an existing BST and augment each node by storing the number of nodes in the left subtree. Once you have done this, you can look up the nth node in the tree by using the following recursive algorithm: To look up the nth element in a BST whose root node has k elements in its left subtree: If k = 0, ...

8

The implementation is missing a lot of stuff still, you should go read up a bit more on what is needed (even wikipedia has a nice description, but many other pages will show up if you do a search.) The trickiest part of writing any (self-balancing) tree is in the balancing code.... Just creating a tree in Haskell is very easy, as you have done above, but ...

7

You can save the balance factor as a part of the information each node saves. Specifically, you can save the height of the left and right subtrees, and update the values with every insertion/deletion on the insertion/deletion path. Example: class Node { public: // stuff... int GetBF() { return lHeight - rHeight; } private: int data; ...

7

An AVL tree is a self-balancing binary search tree, balanced to maintain O(log n) height. A B-tree is a balanced tree, but it is not a binary tree. Nodes have more children, which increases per-node search time but decreases the number of nodes the search needs to visit. This makes them good for disk-based trees. For more details, see the Wikipedia ...

7

On a 64-bit machine, pointers are usually aligned to be at word boundaries, which are at multiples of eight bytes. As a result, the lowest three bits of a pointer will be zero. Consequently, if a data structure needs three bits of information, it can pack them into the lowest three bits of a pointer. That way: To follow the pointer, clear the lowest ...

6

No, AVL trees are certainly not evil in any respect. They are a completely valid self balancing tree structure. They have different performance characteristics than Red-Black trees certainly and typically these differences lead to people choosing a red-black tree over an AVL tree. But this does not make them evil.

6

The code below works for me. It is based on your code, with the changes 1) use the tikz library trees and 2) change of the formatting of a single node (node 7) For more information see the tikz manual \documentclass{article} \usepackage{tikz} \usetikzlibrary{trees} \begin{document} \begin{tikzpicture}[level/.style={sibling distance=60mm/#1}] \node ...

6

The tricky part is indeed the *& part. That declares it as a reference to a pointer (here's a link or two to some similar sample code, but I fear they may be more confusing than helpful). By changing out the node to which the pointer points with pos = b, you can swap the contents to the different node without having to know the parent. The original ...

6

In AVL trees you can see the maximal height difference as a tweakable parameter. They must have chosen 2 to tradeoff between the rebalancing cost on insertion/removal and the lookup cost. Since you seem to be interested in these things I suggest you have a look at this this paper that has formal proof of correctness of OCaml's Set's module which uses the ...

6

Basic Solution Fibonacci trees have several properties that can be used to form a compact Fibonacci tree: Every node in a Fibonacci tree is itself a Fibonacci tree. The number of nodes in a Fibonacci tree of height n is equal to Fn+2 - 1. The number of nodes in between a node and its left child is equal to the number of nodes in the node's left child's ...

5

A good hashtable is almost always faster than a tree. The great advantage of the tree is that you can use it to query ranges and for ordering. So if you don't need these features I'd rather look into optimizing your hash based solution. And AFAIK SortedDictionary<K,V> is tree based.

5

Convert your trees T1 and T2 to sorted lists L1 and L2 Merge L1 and L2 into a sorted list L Convert L into a tree T again. IIRC all this operations are O(N), so the full merge will also be O(N). If your representation of AVL trees allows to iterate over them efficiently (for instance, using backpointers, continuations, lazy evaluation, etc.) you should ...

5

The presented scenario conforms to the Right-Left case from this description. Your mistake is that you rotate the imbalanced node (5) at once, without first performing a rotation of its sub-tree. In general having P as the unbalanced node, L as its left sub-tree and R as its right sub-tree the following rules should be followed at insertion: balance(N) = ...

4

You didn't specified what kind of balanced tree you want. For example you can use AVL tree If you count node highs then you will get that node 13 is disbalanced with worth -2 and 18 with 1 so you have to do right rotation in node 18 and left rotation in node 13. After that node become balanced. After right rotation: 13 ...

4

I've been doing some work with AVL trees lately. The best help I was able to find on how to balance them was through searching google. I just coded around this pseudo code (if you understand how to do rotations it is pretty easy to implement). IF tree is right heavy { IF tree's right subtree is left heavy { Perform Double Left rotation } ...

Only top voted, non community-wiki answers of a minimum length are eligible