AVL-tree: fast(non-recursive) and simple(< 500 lines of code)
Operation | Average | Worst case |
---|---|---|
Space | O(n) | O(n) |
Search | O(log n) | O(log n) |
Insert | O(log n) | O(log n) |
Delete | O(log n) | O(log n) |
npm i -S avl
import AVLTree from 'avl';
const tree = new AVLTree();
Or get it from CDN
<script src="https://unpkg.com/avl"></script>
<script>
var tree = new AVLTree();
...
</script>
Or use the compiled version 'dist/avl.js'.
new AVLTree([comparator], [noDuplicates:Boolean])
, wherecompare
is optional comparison functiontree.insert(key:any, [data:any])
- Insert itemtree.remove(key:any)
- Remove itemtree.find(key):Node|Null
- Return node by its keytree.at(index:Number):Node|Null
- Return node by its index in sorted order of keystree.contains(key):Boolean
- Whether a node with the given key is in the treetree.forEach(function(node) {...}):Tree
In-order traversaltree.range(lo, high, function(node) {} [, context]):Tree
- Walks the range of keys in order. Stops, if the visitor function returns a non-zero value.tree.keys():Array<key>
- Returns the array of keys in ordertree.values():Array<*>
- Returns the array of data fields in ordertree.pop():Node
- Removes smallest nodetree.min():key
- Returns min keytree.max():key
- Returns max keytree.minNode():Node
- Returns the node with smallest keytree.maxNode():Node
- Returns the node with highest keytree.prev(node):Node
- Predecessor nodetree.next(node):Node
- Successor nodetree.load(keys:Array<*>, [values:Array<*>]):Tree
- Bulk-load itemstree.destroy():Tree, tree.clear():Tree
- Empty the tree
Comparator
function(a:key,b:key):Number
- Comparator function between two keys, it returns
0
if the keys are equal<0
ifa < b
>0
ifa > b
The comparator function is extremely important, in case of errors you might end
up with a wrongly constructed tree or would not be able to retrieve your items.
It is crucial to test the return values of your comparator(a,b)
and comparator(b,a)
to make sure it's working correctly, otherwise you may have bugs that are very
unpredictable and hard to catch.
Duplicate keys
By default, tree allows duplicate keys. You can disable that by passing true
as a second parameter to the tree constructor. In that case if you would try to
instert an item with the key, that is already present in the tree, it will not
be inserted.
However, the default behavior allows for duplicate keys, cause there are cases
where you cannot predict that the keys would be unique (example: overlapping
points in 2D).
import Tree from 'avl';
const t = new Tree();
t.insert(5);
t.insert(-10);
t.insert(0);
t.insert(33);
t.insert(2);
console.log(t.keys()); // [-10, 0, 2, 5, 33]
console.log(t.size); // 5
console.log(t.min()); // -10
console.log(t.max()); // -33
t.remove(0);
console.log(t.size); // 4
Custom comparator (reverse sort)
import Tree from 'avl';
const t = new Tree((a, b) => b - a);
t.insert(5);
t.insert(-10);
t.insert(0);
t.insert(33);
t.insert(2);
console.log(t.keys()); // [33, 5, 2, 0, -10]
Bulk insert
import Tree from 'avl';
const t = new Tree();
t.load([3,2,-10,20], ['C', 'B', 'A', 'D']);
console.log(t.keys()); // [-10, 2, 3, 20]
console.log(t.values()); // ['A', 'B', 'C', 'D']
npm run benchmark
Insert (x1000)
Bintrees x 3,742 ops/sec ±0.89% (90 runs sampled)
Functional red black tree x 1,880 ops/sec ±4.02% (78 runs sampled)
Google Closure library AVL x 622 ops/sec ±4.22% (81 runs sampled)
AVL (current) x 6,151 ops/sec ±8.50% (72 runs sampled)
- Fastest is AVL (current)
Random read (x1000)
Bintrees x 7,371 ops/sec ±2.69% (83 runs sampled)
Functional red black tree x 13,010 ops/sec ±2.93% (83 runs sampled)
Google Closure library AVL x 27.63 ops/sec ±1.04% (49 runs sampled)
AVL (current) x 12,921 ops/sec ±1.83% (86 runs sampled)
- Fastest is AVL (current)
Remove (x1000)
Bintrees x 106,837 ops/sec ±0.74% (86 runs sampled)
Functional red black tree x 25,368 ops/sec ±0.89% (88 runs sampled)
Google Closure library AVL x 31,719 ops/sec ±1.21% (89 runs sampled)
AVL (current) x 108,131 ops/sec ±0.70% (88 runs sampled)
- Fastest is AVL (current)
Adding google closure library to the benchmark is, of course, unfair, cause the node.js version of it is not optimised by the compiler, but in this case it plays the role of straight-forward robust implementation.
npm i
npm t
npm run build
The MIT License (MIT)
Copyright (c) 2017 Alexander Milevski [email protected]
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.