Needle is a standalone extensive data structure library in JavaScript.
Installation
You can install Needle inside your Node environment with NPM, and it's as easy as:
$ npm install --save node-needle
If you prefer to use Needle on the client side, just download the minified file of the latest version and include it in your webpage:
<script src="path/to/needle.min.js"></script>
Usage
When you have Needle installed, you can use it on the server in Node like so:
const Needle = require('node-needle');
var map = Needle.Hashmap();
or you can just use it on the client side like so:
var bst = new Needle.BinarySearchTree();
API Reference
Needle has a variety of different data structures at its disposal. Here is a reference to all of the currently available data structures that Needle supports. Some data structures have not been added yet and they will appear unavailable.
If you feel that there should be additional data structures added to this library, send me a message and let me know your ideas.
Note: In the API, *
refers to any type. This is commonly used when specifying the type of data; since all types of data are supported when inserting custom data into a data structure.
Arrays
Lists
Heaps
Binary Trees
Trees
Multiway Trees
Hashes
Graphs
- Adjacency Matrix
- Directed Graph
- Multigraph
root - Node - The root node of the binary tree.
compare - function - Compares two elements to each other to determine the ordering of the heap.
Note: The default compare
function is defined as
function defaultCompare(a, b){
return (a < b);
}
- (constructor)([< function >compare]) - object - Creates a Binary Search Tree and if a function is passed in, it overrides the default compare function with the function defined by
compare
. - hasRight(< Node >node) - boolean - Returns true if the given
Node
has a right component. - hasLeft(< Node >node) - boolean - Returns true if the given
Node
has a left component. - isLeaf(< Node >node) - boolean - Returns true if the given
Node
is a leaf. - emptySubtree(< Node >node) - void - Empties the subtree of the given
Node
. - emptyTree() - void - Empties the entire tree.
- heightSubtree(< Node >node) - number - Returns the height of the subtree derived from
Node
. - numNodesSubtree(< Node >node) - number - Returns the number of nodes of the subtree derived from
Node
. - numLeavesSubtree(< Node >node) - number - Returns the number of leaves of the subtree derived from
Node
. - insert(< * >data [, < Node >node]) - void - Inserts a node into the binary search tree given by
data
. The Node
argument will determine which subtree to attempt to insert the node at. Inserting at the root subtree is selected by default if this parameter is left blank (recommended). - search(< * >data [, < Node >node]) - Node || false - Searched for the node given by
data
in the binary search tree. The Node
argument will determine which subtree to attempt to search for the node. Searching at the root subtree is selected by default if this parameter is left blank (recommended).
heap - Array - The array based heap acting as a binary heap.
compare - function - Compares two elements to each other to determine the ordering of the heap.
Note: The default compare
function is defined as
function defaultCompare(a, b){
return (a < b);
}
- (constructor)([< function >compare]) - object - Creates a Binary Heap and if a function is passed in, it overrides the default compare function with the function defined by
compare
. - peek() - element - Returns the root or top element of the heap.
- size() - number - Returns the amount of elements stored in the heap.
- insert(< * >data) - void - Inserts the element given by
data
into the heap and adjusts the heap accordingly. - delete() - void - Removes the root or top element from the heap and adjusts the heap accordingly.
- heapify(< array >arr) - void - Converts the input array into a legal binary heap.
data - Array - The array of bit sequences.
- (constructor)([< number >size = 0]) - object - Creates a Bit Array and allocates memory for the
size
if argument is given. - get(< number >index) - number - Returns the bit in the BitArray at location
index
. - set(< number >index, < boolean >value) - void -
- size(< number >size) - void -
- resize() - void - Adjusts the BitArray size to the given argument
size
. - complement() - BitArray - Resolves the complement of the calling BitArray.
- union(< BitArray >bitarray) - BitArray - Resolves the union between the calling BitArray and the argument
bitarray
. - intersection(< BitArray >bitarray) - BitArray - Resolves the intersection between the calling BitArray and the argument
bitarray
. - difference(< BitArray >bitarray) - BitArray - Resolves the difference between the calling BitArray and the argument
bitarray
.
head - Node - The first node in the linked list.
tail - Node - The last node in the linked list.
size - number - The number of nodes in the linked list.
- (constructor)([< * >data]) - object - Creates a Doubly Linked List and inserts a node at the head of the newly created list if
data
is given. - insertFront(< * >data) - void - Create a node from
data
and inserts at the front of the list. - insertNth(< number >index, < * >data) - boolean - Create a node from
data
and insert in the location of the linked list specified by index
. - insertAfter(< * >targetData, < * >data) - boolean - Create a node from
data
and insert after the node which has the data specified by targetData
and returns true
if the element was successfully added to the linked list. - insertBack(< * >data) - void - Create a node from
data
and inserts at the back of the list. - remove(< * >data) - boolean - Removes the element specified by
data
and returns true
if the element was successfully found and removed from the linked list. - removeNth(< number >index) - void - Removes the element in the location of the linked list specified by
index
. - find(< * >data) - Node || false - Finds the element specified by
data
and returns that Node
if the element was successfully found but returns false
if the node was not found. - findNth(< number >index) - Node - Finds the element in the location of the linked list specified by
index
and returns that Node
.
state - number - Holds the current hash of the internal window.
- (constructor)() - object - Creates and instatiates a Hashmap object.
- put(< * >key, < * >value) - void - Inserts an entry into the hashmap, which maps the given
key
to its respective value
. - get(< * >key) - value - Returns the value that is paired with the given
key
. - delete(< * >key) - boolean - Deletes the entry that is associated with the given
key
, returns true
if deletion was successful and false
if the entry was not found. - iterator() - key - Resets the internal iterator
Node
to the first entry and returns the unhashed key. - next() - key - Iterates to the next
Node
and returns an the unhashed key. - size() - number - Returns the amount of unique entries within the hashmap.
state - number - The internal hash value of the current window.
- (constructor)(< number >base) - object - Creates and instatiates a rolling hash object and an argument is passed in which assigns the
base
of the rolling hash. - set(< string || Array >arg) - void - Sets the internal window of the rolling hash given
arg
in the relative base. - slide(< string || number >old, < string || number >new) - number - Shifts the internal window a single rotation by removing the
old
segment and appending on the new
segment, then returns the newly updates state
of the internal window. - skip(< string || number >old) - void - Disjoins the
old
segment from the internal window. - append(< string || number >new) - void - Appends a
new
segment onto the internal window. - hash(< number || string || Arrayarg>) - number - Takes in either a
string
, number
(assumed in the relative base
), or Array
of elements in the relative base, and returns the hash of the argument.
head - Node - The first node in the linked list.
size - number - The number of nodes in the linked list.
- (constructor)([< * >data]) - object - Creates a Singly Linked List and inserts a node at the head of the newly created list if
data
is given. - insertFront(< * >data) - void - Create a node from
data
and inserts at the front of the list. - insertNth(< number >index, < * >data) - boolean - Create a node from
data
and insert in the location of the linked list specified by index
. - insertAfter(< * >targetData, < * >data) - boolean - Create a node from
data
and insert after the node which has the data specified by targetData
and returns true
if the element was successfully added to the linked list. - insertBack(< * >data) - void - Create a node from
data
and inserts at the back of the list. - remove(< * >data) - boolean - Removes the element specified by
data
and returns true
if the element was successfully found and removed from the linked list. - removeNth(< number >index) - void - Removes the element in the location of the linked list specified by
index
. - find(< * >data) - Node || false - Finds the element specified by
data
and returns that Node
if the element was successfully found but returns false
if the node was not found. - findNth(< number >index) - Node - Finds the element in the location of the linked list specified by
index
and returns that Node
.
top - Node - The top node in the stack.
size - number - The number of nodes in the stack.
- (constructor)([< * >data]) - object - Creates a Stack and if data is passed given, the top element of the queue, defined by
data
, is created and inserted. - peek() - Node - Returns the top
Node
of the stack. - push(< * >data) - void - Adds and element, defined by
data
, to the top of the stack. - pop() - Node - Removes the top element of the stack and returns the
Node
that was previously the top, and just deleted.
front - Node - The first node in the queue.
back - Node - The last node in the queue.
size - number - The number of nodes in the queue.
- (constructor)([< * >data]) - object - Creates a Queue and if data is passed given, the first element of the queue, defined by
data
, is created and inserted. - enqueue(< * >data) - void - Adds and element, defined by
data
, to the queue. - dequeue() - void - Removes the first element of the queue.
Examples
Here are an assortment of examples using various data structures provided by Needle. If you wish there to be examples of a data structure in particular, feel free to let me know what you have in mind.
const Needle = require('node-needle');
var Level = function(key, value){
this.key = key;
this.value = value;
}
var priorityQueue = new Needle.BinaryHeap(function(a, b){
return a.key < b.key;
});
priorityQueue.insert(new Level(3, "Level 3"));
priorityQueue.insert(new Level(1, "Level 1"));
priorityQueue.insert(new Level(2, "Level 2"));
priorityQueue.peek();
priorityQueue.size();
priorityQueue.delete();
priorityQueue.peek();
priorityQueue.size();
const Needle = require('node-needle');
var map = new Needle.Hashmap();
map.put(1, "Level 1");
map.put("2", "Level 2");
map.put({key: "three"}, "Level 3");
for(var it = map.iterator(); it !== null; it = map.next()){
console.log(it);
console.log(map.get(it));
}
License
MIT
Copyright (c) 2015 Nick Zuber