Question

As made clear in update 3 on this answer, this notation:

var hash = {};
hash[X]

does not actually hash the object X; it actually just converts X to a string (via .toString() if it's an object, or some other built-in conversions for various primitive types) and then looks that string up, without hashing it, in "hash". Object equality is also not checked - if two different objects have the same string conversion, they will just overwrite each other.

Given this - are there any efficient implementations of hashmaps in javascript? (For example, the 2nd Google result of javascript hashmap yields an implementation which is O(n) for any operation. Various other results ignore the fact that different objects with equivalent string representations overwrite each other.

Answer 1

Why not hash your objects yourself, and use the resulting strings as keys for a regular JavaScript dictionary? After all you are in the best position to know what makes your objects unique. That's what I do.

Example:

var hash = function(obj){
  // some cool hashing
  return obj.lastName + obj.firstName; // just an example
};

var dict = {};

dict[hash(obj1)] = obj1;
dict[hash(obj2)] = obj2;

This way you can control hashing done by JavaScript without heavy lifting of memory allocation, and overflow handling.

Of course, if you truly want the "industrial-grade solution", you can build a class parameterized by the hash function, and with all necessary API of the container, but … we use JavaScript, and trying to be simple and lightweight, so this functional solution is simple and fast.

The hash function can be as simple as selecting right attributes of the object, e.g., a "key", or a set of keys, which are already unique, or as complex as using some cryptographic hashes like in DojoX Encoding, or DojoX UUID.

Answer 2

You'd have to store in some internal state couplets of object/value pairs

HashMap = function(){
  this._dict = [];
}
HashMap.prototype._get = function(key){
  for(var i=0, couplet; couplet = this._dict[i]; i++){
    if(couplet[0] === key){
      return couplet;
    }
  }
}
HashMap.prototype.put = function(key, value){
  var couplet = this._get(key);
  if(couplet){
    couplet[1] = value;
  }else{
    this._dict.push([key, value]);
  }
  return this; // for chaining
}
HashMap.prototype.get = function(key){
  var couplet = this._get(key);
  if(couplet){
    return couplet[1];
  }
}

And use it as such:

var color = {}; // unique object instance
var shape = {}; // unique object instance
var map = new HashMap();
map.put(color, "blue");
map.put(shape, "round");
console.log("Item is", map.get(color), "and", map.get(shape));

Of course, this implementation is also somewhere along the lines of O(n). Eugene's examples above are the only way to get a hash that works with any sort of speed you'd expect from a real hash.

Update:

Another approach, along the lines of Eugene's answer is to somehow attach a unique ID to all objects. One of my favorite approaches is to take one of the built-in methods inherited from the Object superclass, replace it with a custom function passthrough and attach properties to that function object. If you were to rewrite my HashMap method to do this, it would look like:

HashMap = function(){
  this._dict = {};
}
HashMap.prototype._shared = {id: 1};
HashMap.prototype.put = function put(key, value){
  if(typeof key == "object"){
    if(!key.hasOwnProperty._id){
      key.hasOwnProperty = function(key){
        return Object.prototype.hasOwnProperty.call(this, key);
      }
      key.hasOwnProperty._id = this._shared.id++;
    }
    this._dict[key.hasOwnProperty._id] = value;
  }else{
    this._dict[key] = value;
  }
  return this; // for chaining
}
HashMap.prototype.get = function get(key){
  if(typeof key == "object"){
    return this._dict[key.hasOwnProperty._id];
  }
  return this._dict[key];
}

This version appears to be only slightly faster, but in theory it will be significantly faster for large data sets.

Answer 3

Problem description

JavaScript has no built-in general map type (sometimes called associative array or dictionary) which allows to access arbitrary values by arbitrary keys. JavaScript's fundamental data structure is the object, a special type of map which only accepts strings as keys and has special semantics like prototypical inheritance, getters and setters and some further voodoo.

When usings objects as maps, you have to remember that the key will be converted to a string value via toString(), which results in mapping 5 and '5' to the same value and all objects which don't overwrite the toString() method to the value indexed by '[object Object]'. You might also involuntarily access its inherited properties if you don't check hasOwnProperty().

JavaScript's built-in array type does not help one bit: JavaScript arrays are not associative arrays, but just objects with a few more special properties. If you want to know why they can't be used as maps, look here.

Eugene's Solution

Eugene Lazutkin already described the basic idea of using a custom hash function to generate unique strings which can be used to look up the associated values as properties of a dictionary object. This will most likely be the fastest solution, because objects are internally implemented as hash tables.

• Note: Hash tables (sometimes called hash maps) are a particular implementation of the map concept using a backing array and lookup via numeric hash values. The runtime environment might use other structures (such as search trees or skip lists) to implement JavaScript objects, but as objects are the fundamental data structure, they should be sufficiently optimised.

In order to get a unique hash value for arbitrary objects, one possibility is to use a global counter and cache the hash value in the object itself (eg in a property named __hash).

A hash function which does this is and works for both primitive values and objects is:

function hash(value) {
    return (typeof value) + ' ' + (value instanceof Object ?
        (value.__hash || (value.__hash = ++arguments.callee.current)) :
        value.toString());
}

hash.current = 0;

This function can be used as described by Eugene. For convenience, we will further wrap it in a Map class.

My Map implementation

The following implementation will additionally store the key-value-pairs in a doubly linked list in order to allow fast iteration over both keys and values. To supply your own hash function, you can overwrite the instance's hash() method after creation.

// linking the key-value-pairs is optional
// if no argument is provided, linkItems === undefined, i.e. !== false
// --> linking will be enabled
function Map(linkItems) {
    this.current = undefined;
    this.size = 0;

    if(linkItems === false)
        this.disableLinking();
}

Map.noop = function() {
    return this;
};

Map.illegal = function() {
    throw new Error("illegal operation for maps without linking");
};

// map initialisation from existing object
// doesn't add inherited properties if not explicitly instructed to:
// omitting foreignKeys means foreignKeys === undefined, i.e. == false
// --> inherited properties won't be added
Map.from = function(obj, foreignKeys) {
    var map = new Map;

    for(var prop in obj) {
        if(foreignKeys || obj.hasOwnProperty(prop))
            map.put(prop, obj[prop]);
    }

    return map;
};

Map.prototype.disableLinking = function() {
    this.link = Map.noop;
    this.unlink = Map.noop;
    this.disableLinking = Map.noop;
    this.next = Map.illegal;
    this.key = Map.illegal;
    this.value = Map.illegal;
    this.removeAll = Map.illegal;

    return this;
};

// overwrite in Map instance if necessary
Map.prototype.hash = function(value) {
    return (typeof value) + ' ' + (value instanceof Object ?
        (value.__hash || (value.__hash = ++arguments.callee.current)) :
        value.toString());
};

Map.prototype.hash.current = 0;

// --- mapping functions

Map.prototype.get = function(key) {
    var item = this[this.hash(key)];
    return item === undefined ? undefined : item.value;
};

Map.prototype.put = function(key, value) {
    var hash = this.hash(key);

    if(this[hash] === undefined) {
        var item = { key : key, value : value };
        this[hash] = item;

        this.link(item);
        ++this.size;
    }
    else this[hash].value = value;

    return this;
};

Map.prototype.remove = function(key) {
    var hash = this.hash(key);
    var item = this[hash];

    if(item !== undefined) {
        --this.size;
        this.unlink(item);

        delete this[hash];
    }

    return this;
};

// only works if linked
Map.prototype.removeAll = function() {
    while(this.size)
        this.remove(this.key());

    return this;
};

// --- linked list helper functions

Map.prototype.link = function(item) {
    if(this.size == 0) {
        item.prev = item;
        item.next = item;
        this.current = item;
    }
    else {
        item.prev = this.current.prev;
        item.prev.next = item;
        item.next = this.current;
        this.current.prev = item;
    }
};

Map.prototype.unlink = function(item) {
    if(this.size == 0)
        this.current = undefined;
    else {
        item.prev.next = item.next;
        item.next.prev = item.prev;
        if(item === this.current)
            this.current = item.next;
    }
};

// --- iterator functions - only work if map is linked

Map.prototype.next = function() {
    this.current = this.current.next;
};

Map.prototype.key = function() {
    return this.current.key;
};

Map.prototype.value = function() {
    return this.current.value;
};

Example

The following script

var map = new Map;

map.put('spam', 'eggs').
    put('foo', 'bar').
    put('foo', 'baz').
    put({}, 'an object').
    put({}, 'another object').
    put(5, 'five').
    put(5, 'five again').
    put('5', 'another five');

for(var i = 0; i++ < map.size; map.next())
    document.writeln(map.hash(map.key()) + ' : ' + map.value());

generates this output:

string spam : eggs
string foo : baz
object 1 : an object
object 2 : another object
number 5 : five again
string 5 : another five

Further considerations

PEZ suggested to overwrite the toString() method, presumably with our hash function. This is not feasible because it doesn't work for primitive values (changing toString() for primitives is a very bad idea). If we want toString() to return meaningful values for arbitrary objects, we would have to modify Object.prototype, which some people (myself not included) consider verboten.

---

Edit: The current version of my Map implementation as well as other JavaScript goodies can be obtained from here.

Answer 4

Is overriding toString() feasible?

Answer 5

Javascript does not build-in Map/hashmap. It should be called associative array.

hash["X"] is equals to hash.X, but allow "X" as a string variable. In other words, hash[x] is functionally equals to eval("hash."+x.toString())

It is more similar as object.properties rather then key-value mapping. If you are looking for a better Key/value mapping in Javascript, please use Map object which you can find on the web.

Answer 6

In www.smoo.com.ar you have a example for this functionally

Answer 7

Try my JavaScript hash table implementation: http://www.timdown.co.uk/jshashtable

It looks for a hashCode() method of key objects, or you can supply a hashing function when creating a Hashtable object.

Answer 8

I've implemented javascript HashMap which code can be obtained from http://github.com/lambder/HashMapJS/tree/master

Here is the code:

/*
 =====================================================================
 @license MIT
 @author Daniel Kwiecinski <daniel.kwiecinski@lambder.com>
 @copyright 2009 Daniel Kwiecinski.
 @end
 =====================================================================
 */
var HashMap = function() {
  this.initialize();
}

HashMap.prototype = {
  hashkey_prefix: "<#HashMapHashkeyPerfix>",
  hashcode_field: "<#HashMapHashkeyPerfix>",

  initialize: function() {
    this.backing_hash = {};
    this.code = 0;
  },
  /*
   maps value to key returning previous assocciation
   */
  put: function(key, value) {
    var prev;
    if (key && value) {
      var hashCode = key[this.hashcode_field];
      if (hashCode) {
        prev = this.backing_hash[hashCode];
      } else {
        this.code += 1;
        hashCode = this.hashkey_prefix + this.code;
        key[this.hashcode_field] = hashCode;
      }
      this.backing_hash[hashCode] = value;
    }
    return prev;
  },
  /*
   returns value associated with given key
   */
  get: function(key) {
    var value;
    if (key) {
      var hashCode = key[this.hashcode_field];
      if (hashCode) {
        value = this.backing_hash[hashCode];
      }
    }
    return value;
  },
  /*
   deletes association by given key.
   Returns true if the assocciation existed, false otherwise
   */
  del: function(key) {
    var success = false;
    if (key) {
      var hashCode = key[this.hashcode_field];
      if (hashCode) {
        var prev = this.backing_hash[hashCode];
        this.backing_hash[hashCode] = undefined;
        if(prev !== undefined)
          success = true;
      }
    }
    return success;
  }
}

//// Usage

// creation

var my_map = new HashMap();

// insertion

var a_key = {};
var a_value = {struct: "structA"};
var b_key = {};
var b_value = {struct: "structB"};
var c_key = {};
var c_value = {struct: "structC"};

my_map.put(a_key, a_value);
my_map.put(b_key, b_value);
var prev_b = my_map.put(b_key, c_value);

// retrieval

if(my_map.get(a_key) !== a_value){
  throw("fail1")
}
if(my_map.get(b_key) !== c_value){
  throw("fail2")
}
if(prev_b !== b_value){
  throw("fail3")
}

// deletion

var a_existed = my_map.del(a_key);
var c_existed = my_map.del(c_key);
var a2_existed = my_map.del(a_key);

if(a_existed !== true){
  throw("fail4")
}
if(c_existed !== false){
  throw("fail5")
}
if(a2_existed !== false){
  throw("fail6")
}

Bon Appétit, Daniel Kwiecinski