One option is to sort the two arrays, then traverse both, comparing elements. If an element in the sub-bag candidate is not found in the super-bag, the former is not a sub-bag. Sorting is generally O(n*log(n)) and the comparison is O(max(s,t)), where *s* and *t* are the array sizes, for a total time complexity of O(m*log(m)), where m=max(s,t).

```
function superbag(sup, sub) {
sup.sort();
sub.sort();
var i, j;
for (i=0,j=0; i<sup.length && j<sub.length;) {
if (sup[i] < sub[j]) {
++i;
} else if (sup[i] == sub[j]) {
++i; ++j;
} else {
// sub[j] not in sup, so sub not subbag
return false;
}
}
// make sure there are no elements left in sub
return j == sub.length;
}
```

If the elements in the actual code are integers, you can use a special-purpose integer sorting algorithm (such as radix sort) for an overall O(max(s,t)) time complexity, though if the bags are small, the built-in `Array.sort`

will likely run faster than a custom integer sort.

A solution with potentially lesser time-complexity is to create a bag type. Integer bags are particularly easy. Flip the existing arrays for the bags: create an object or an array with the integers as keys and a repeat count for values. Using an array won't waste space by creating as arrays are sparse in Javascript. You can use bag operations for sub-bag or super-bag checks. For example, subtract the super from the sub candidate and test if the result non-empty. Alternatively, the `contains`

operation should be O(1) (or possibly O(log(n))), so looping over the sub-bag candidate and testing if the super-bag containment exceeds the sub-bag's containment for each sub-bag element should be O(n) or O(n*log(n)).

The following is untested. Implementation of `isInt`

left as an exercise.

```
function IntBag(from) {
if (from instanceof IntBag) {
return from.clone();
} else if (from instanceof Array) {
for (var i=0; i < from.length) {
this.add(from[i]);
}
} else if (from) {
for (p in from) {
/* don't test from.hasOwnProperty(p); all that matters
is that p and from[p] are ints
*/
if (isInt(p) && isInt(from[p])) {
this.add(p, from[p]);
}
}
}
}
IntBag.prototype=[];
IntBag.prototype.size=0;
IntBag.prototype.clone = function() {
var clone = new IntBag();
this.each(function(i, count) {
clone.add(i, count);
});
return clone;
};
IntBag.prototype.contains = function(i) {
if (i in this) {
return this[i];
}
return 0;
};
IntBag.prototype.add = function(i, count) {
if (!count) {
count = 1;
}
if (i in this) {
this[i] += count;
} else {
this[i] = count;
}
this.size += count;
};
IntBag.prototype.remove = function(i, count) {
if (! i in this) {
return;
}
if (!count) {
count = 1;
}
this[i] -= count;
if (this[i] > 0) {
// element is still in bag
this.size -= count;
} else {
// remove element entirely
this.size -= count + this[i];
delete this[i];
}
};
IntBag.prototype.each = function(f) {
var i;
foreach (i in this) {
f(i, this[i]);
}
};
IntBag.prototype.find = function(p) {
var result = [];
var i;
foreach (i in this.elements) {
if (p(i, this[i])) {
return i;
}
}
return null;
};
IntBag.prototype.sub = function(other) {
other.each(function(i, count) {
this.remove(i, count);
});
return this;
};
IntBag.prototype.union = function(other) {
var union = this.clone();
other.each(function(i, count) {
if (union.contains(i) < count) {
union.add(i, count - union.contains(i));
}
});
return union;
};
IntBag.prototype.intersect = function(other) {
var intersection = new IntBag();
this.each(function (i, count) {
if (other.contains(i)) {
intersection.add(i, Math.min(count, other.contains(i)));
}
});
return intersection;
};
IntBag.prototype.diff = function(other) {
var mine = this.clone();
mine.sub(other);
var others = other.clone();
others.sub(this);
mine.union(others);
return mine;
};
IntBag.prototype.subbag = function(super) {
return this.size <= super.size
&& null !== this.find(
function (i, count) {
return super.contains(i) < this.contains(i);
}));
};
```

See also "comparing javascript arrays" for an example implementation of a set of objects, should you ever wish to disallow repetition of elements.

`true`

, for two reasons: (1) repetition doesn't matter in sets:`{1,1} = {1}`

. (2) A set is its own subset and superset; if the two aren't supposed to be equal, they're called "proper subset" and "proper superset". – outis Dec 25 '11 at 4:16