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A Typescript implementation of an AVL tree, which is a self-balancing binary search tree.

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quick-avl

A Typescript implementation of an AVL tree, which is a self-balancing binary search tree.

Implements the Map interface.

Named after the inventors Adelson-Velsky and Landis, an AVL tree enforces an invariant where the heights of the subtrees of a node differ by at most one. Rebalancing is performed after each insert or remove operation, if that operation made the tree imbalanced.

Installation

npm install quick-avl

Performance

The main reason of using an AVL tree is performance. Because of its self-balancing property, worst case lookup is O(log(n)), compared to the plain binary search trees where this is O(n).

Operation Average time complexity Worst case complexity
find O(log n) O(log n)
insert O(log n) O(log n)
remove O(log n) O(log n)
traversal O(n) O(n)

Usage

This AVL tree implementation acts like a map to store key-value pairs in.

import { AvlTree } from 'quick-avl';

const users = new AvlTree<number, string>();

users.set(100, 'Bob').set(200, 'Carol').set(0, 'Alice');

users.get(100); // --> 'Bob'
users.has(100); // --> true

users.delete(200); // --> true

users.valueList(); // --> ['Alice', 'Carol']

for (const [key, value] of users) {
  console.log(`Key: ${key}, value: ${value}`);
}

Why another AVL library

While there are some excellent AVL libraries available within NPM, these libraries swap out tree node values while performing tree balancing. I required an AVL library that does not replace keys or values within a node. That way, a reference to a tree node will always keep the same value.

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A Typescript implementation of an AVL tree, which is a self-balancing binary search tree.

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