HashArray

HashArray is a data structure that combines the best feature of a hash (O(1) retrieval) and an array (length and ordering). Think of it as a super-lightweight, extensible, self-indexing set database in memory.

Install

npm install hasharray

Simplest Use Case

So as not to scare the faint of heart with all the technical goodness contained therein:

var HashArray = require('hasharray'), ha = new HashArray('id'); ha.add({id: 'someId0', name: 'Josh'}, {id: 'someId1', name: 'Joseph'}, {id: 'someId2', name: 'Kuba'}, {id: 'someId3', name: 'Ty'}); console.log(ha.get('someId0').name); // 'Kuba'

API

Constructor

HashArray(keyfields, callback, options)

keyfields

var HashArray = require('HashArray'); new HashArray('firstname'); // one key, depth of 1 (e.g. `item.firstname`) new HashArray(['firstname']); // same as above // one key, depth of 2 (e.g. `item.first.name`) new HashArray([['first', 'name']]); // two keys, depth of 1 (e.g. `item.firstname` AND `item.lastname`) new HashArray(['firstname', 'lastname']); // multiple keys, depth of 2 (e.g. `item.name.first` AND `item.name.last`) new HashArray([['name', 'first'], ['name', 'last']]);

callback

A callback function can be specified to monitor changes to the HashArray as they occur:

var ha = new HashArray('someKey', function(type, whatChanged) { // type will be 'add', 'addMap', 'remove', 'removeByKey', or 'construct' // whatChanged will be the items that were changed });

options

{ ignoreDuplicates: false; // When true, any attempt to add items that collide // with any items in the HashArray will be ignored. // default is false. }

Insertion

add(...items) : insert all arguments.

: insert all arguments. addAll(Array of items) : insert all items in the passed in Array.

: insert all items in the passed in Array. addMap(key, item) : adds a single mapping from a key to a item.

: adds a single mapping from a key to a item. addOne(item) : adds a single item, skipping dispatch of event.

Retrieval

get(key) : if a single item exists for key , returns that item. If no item exists, returns undefined . If multiple items exist for the key, returns an Array .

: if a single item exists for , returns that item. If no item exists, returns . If multiple items exist for the key, returns an . getAll(keys) : unions all items for all provided keys and returns an Array. Ensures no duplicates even if keys independently return sets that intersect.

: unions all items for all provided keys and returns an Array. Ensures no duplicates even if independently return sets that intersect. getAsArray(key) : like get() except if no item exists, returns an empty Array .

: like except if no item exists, returns an empty . sample(count, keys) : samples all items in the HashArray, returning a random Array of size count . If count is larger than the HashArray , returns all items in the the HashArray

Removal

remove(...items) : removes all items in arguments.

: removes all items in arguments. removeByKey(...keys) : removes all items that match the keys provided.

: removes all items that match the provided. removeAll() : clears out all items in the HashArray

Set

intersection(HashArray) : returns a cloned HashArray whose items are the intersection between this and the passed in HashArray ( this ^ argument ).

: returns a cloned whose items are the intersection between and the passed in ( ^ ). complement(HashArray) : returns a cloned HashArray whose items are the complement between this and the passed in HashArray ( this \ argument ).

Peeking

has(key) : returns true if any items exist for the provided key.

: returns if any items exist for the provided key. hasMultiple(key) : returns true if multiple items exist for the provided key (e.g. get(key) would return an Array )

: returns if multiple items exist for the provided key (e.g. would return an ) collides(item) : returns true if the argument would collide with any other item in this HashArray for any key in the HashArray .

Iteration

forEach(keys, callback) : iterates through a union of all items that match the provided keys argument and calls the callback passing in each item as an argument.

: iterates through a union of all items that match the provided keys argument and calls the callback passing in each item as an argument. forEachDeep(keys, key, callback) : iterates through a union of all items that match the provided keys argument and passes the value (at the provided key argument) as an argument to the callback.

Mathematical

sum(keys, key, weightKey) : sums all values for a union of all objects found for the keys argument provided at the key you provide. Weights the summation by item[weightKey] or by 1.0 if no weightKey is provided.

: sums all values for a union of all objects found for the argument provided at the you provide. Weights the summation by or by if no is provided. average(keys, key, weightKey) : similar to sum() except returns the average.

Filtering

filter(keys, callbackOrKey) : returns a new HashArray that is a clone of the current one but filtered by the provided keys .

Utility

objectAt(item, key) : internally used to find a value on item at key . For example, objectAt(obj, 'firstname') would return obj['firstname'] . objectAt(obj, ['first', 'name']) would return obj['first']['name'] . Returns undefined if the key does not map properly to the provided object.

: internally used to find a value on at . For example, would return . would return . Returns undefined if the key does not map properly to the provided object. clone(callback, ignoreItems) : shallow clones the HashArray . If ignoreItems is true, does not clone the items just the settings.

Purpose

My goal with this data structure was to attempt to get the ordered features of an Array while keeping lookup O(1) for any arbitrary keys. The cost is a small loss of memory.

In addition HashArray works with deep keys. Consider the following array of customer objects:

var customers = [{ id: 1337, name: { first: 'Bob', last: 'Winkle', }, dob: new Date(1985, 1, 4), address: { city: 'Chicago', zip: 60616 } }...]

If we had multiple people who lived in the zip code 60616 , ideally we would want to index the data by zip code so that if we had to rapidly retrieve all those people we could do so.

With HashArray, we could index the above data for O(1) retrieval by id , ['name', 'first'] , and ['name', 'last] like so:

var HashArray = require('hasharray'), ha = new HashArray(['id', ['name', 'first'], ['name', 'last']]); ha.addAll(customers); // At this point we have indexed everything by ['name', 'first'] so there is already an array built internal to `ha` that // contains all the 'Bob' customers. So this operation is O(1). var bobs = ha.get('Bob');

Note: the order of the bobs array above will be the order in which they were inserted.

Normally when you use a standard JavaScript Object to map keys to values, the only way to retrieve the count of objects is to loop over all the keys which is O(n). However, with HashArray if you want to determine the length of all customers in O(1), it is as simple as:

ha.all.length; // in addition, ha.all is an ordered array of all customers in the order in which they were added!

At this time, I am also working on adding functions for statistical analysis, like sum(...) . See the tests for more information. I'll be adding more to this documentation as I go.

Examples

Basic Examples

var HashArray = require ('hasharray'); // Create new hasharray with two key mappings. var ha = new HashArray(['name', 'zip']); // Add 2 objects to the hash. var item1 = {name: 'Josh', zip: '54321'}; var item2 = {name: 'Josh', zip: '12345'}; ha.add(item1, item2); if (ha.has('Josh')) console.log(ha.get('Josh')); // Will output two objects to the console // Display the number of unique objects. In this case, 2. console.log(ha.all.length); // Remove an element by one of the keys ha.removeByKey('54321'); // This removes item1 // Remove item2 directly ha.remove(item2);

Deep Keys

var HashArray = require ('hasharray'); var ha = new HashArray([ ['name', 'last'], // Internally maps obj.name.last -> obj ['name', 'first'], // Internally maps obj.name.first -> obj 'zip' ]); ha.add({ name: { first: 'Josh', last: 'Jung' }, zip: 60616 }); console.log(ha.get(60616) === ha.get('Josh') == ha.get('Jung')); // true

getAsArray(...): Retrieving Multiples of a Single Key

var ha = new HashArray(['firstName', 'lastName']); var person1 = {firstName: 'Bill', lastName: 'William'}, person2 = {firstName: 'Bob', lastName: 'William'}; ha.add(person1, person2); console.log(ha.getAsArray('William')); // [person1, person2]

getAll(...): Retrieving Sets by Multiple Keys

var ha = new HashArray(['firstName', 'lastName']); var person1 = {firstName: 'Victor', lastName: 'Victor'}, person2 = {firstName: 'Victor', lastName: 'Manning'}, person3 = {firstName: 'Manning', lastName: 'Victor'}; person4 = {firstName: 'John', lastName: 'Smith'}; ha.add(person1, person2, person3, person4); console.log(ha.getAll(['Victor', 'Smith'])); // [person1, person2, person3, person4] console.log(ha.getAll(['John', 'Smith'])); // [person4]

Key Duplicates

If two items contain the same key, they are appended to an array at that key location.

var HashArray = require ('hasharray'); var ha = new HashArray([ ['name', 'last'], ['name', 'first'] ]); ha.add({ name: { first: 'Josh', last: 'Jung' } }, { name: { first: 'Josh', last: 'Mills' } }, { name: { first: 'Josh', last: 'Willis' } }); console.log(ha.get('Josh').length); // Will be 3 console.log(ha.get('Willis')); // Will be {name: {first: 'Josh', last: 'Willis'} }

has(...): duplicate check

If you need to check if an item already exists for a given key, simply use has(...) :

ha.has('someKeyValue');

forEach(keys, callback): looping over sets of items

// Here we index by item.type and item.data.speed var ha = new HashArray(['type', ['data', 'speed']]); var a = {type: 'airplane', data: {speed: 100, weight: 10000}}, b = {type: 'airplane', data: {speed: 100, weight: 20000}}, c = {type: 'airplane', data: {speed: 25, weight: 50000}}; d = {type: 'boat', data: {speed: 10, weight: 100000}}; e = {type: 'boat', data: {speed: 5, weight: 200000}}; ha.add(a, b, c, d, e); // Loop through just airplanes ha.forEach('airplane', function (airplane) {console.log(airplane);}); // Loop through airplanes AND boats ha.forEach(['airplane', 'boat'], function (airplane) {console.log(airplane);}); // Loop through all items that have a speed of 100 ha.forEach(100, function (airplane) {console.log(airplane);});

forEachDeep() differs from forEach() in that it passes a value by key you specify to the callback :

// Here we index by item.type and item.data.speed var ha = new HashArray(['type', ['data', 'speed']]); var a = {type: 'airplane', data: {speed: 100, weight: 10000}}, b = {type: 'airplane', data: {speed: 100, weight: 20000}}, c = {type: 'airplane', data: {speed: 25, weight: 50000}}; d = {type: 'boat', data: {speed: 10, weight: 100000}}; e = {type: 'boat', data: {speed: 5, weight: 200000}}; ha.add(a, b, c, d, e); // Loop through all items that have a speed of 100 and only pass the speed to the callback ha.forEachDeep(100, ['data', 'speed'], function (speed) { console.log('Speed is: ' + speed); });

Cloning

Cloning makes a new HashArray clone of the original, ensuring that no Array objects are shared.

Keep in mind that cloning does deep clone objects in the collection. Therefore if you clone an object with three Object items, the clonee will be a new HashArray but will contain references to the original objects.

var HashArray = require ('hasharray'); ... var ha = new HashArray(['someKey']); ... var clonee = ha.clone();

Extending

HashArray uses jclass, which is an implementation of John Resig's simple inheritance model.

You can easily extend HashArray:

var MyCustomHashArray = HashArray._extend({ ... init: function init(keyFields) { console.log('My custom hash array!'); init._super(keyFields); } ... }); var myCustomHashArray = new MyCustomHashArray();

See the jclass documentation for more information.

Testing

>mocha START ․․․․․․․․․․․․․․․․․․․․․․․․․․․․․․․․․․․ 76 passing (25ms)

License

The MIT License (MIT)

Copyright (c) 2014 Joshua Jung

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.