8

In my application, I need to sort large arrays (between 100,000 and 1,000,000) of random numbers.

I've been using the built in array.sort(comparisonFunction) where comparisonFunction looks like this:

function comparisonFunction(a,b) {
    return a-b;
}

This works just fine, but I've read (e.g., Native JavaScript sort performing slower than implemented mergesort and quicksort) that there are faster options, especially if your requirements meet certain conditions:

  1. I only need to sort numbers (e.g., not objects, or alphanumeric data)
  2. The data is random (no chance that it's already ordered)
  3. The sort doesn't need to be stable

So - what is the fastest (or close enough) sort algorithm available under those circumstances?

And, is there a canonical (or at least a relatively ideal) JavaScript implementation?

[UPDATE]

Yikes... two down votes within 30 seconds of posting! So, a quick clarification - in the linked question, the OP required a stable sort. Since I don't - I'm wondering if that would change the answer (i.e., perhaps there's a faster sort option available if you know in advance that your data will not be pre-sorted, and you don't need a stable sort).

Perhaps the answer is "no", but that's why I'm asking.

[UPDATE #2]

Here's an implementation of quicksort that, unless I've made a mistake - beats the native sort function handily:

function comparisonFunction(a, b) {
  return a - b;
}

function quickSort(arr, leftPos, rightPos, arrLength) {
  let initialLeftPos = leftPos;
  let initialRightPos = rightPos;
  let direction = true;
  let pivot = rightPos;
  while ((leftPos - rightPos) < 0) {
    if (direction) {
      if (arr[pivot] < arr[leftPos]) {
        quickSort.swap(arr, pivot, leftPos);
        pivot = leftPos;
        rightPos--;
        direction = !direction;
      } else
        leftPos++;
    } else {
      if (arr[pivot] <= arr[rightPos]) {
        rightPos--;
      } else {
        quickSort.swap(arr, pivot, rightPos);
        leftPos++;
        pivot = rightPos;
        direction = !direction;
      }
    }
  }
  if (pivot - 1 > initialLeftPos) {
    quickSort(arr, initialLeftPos, pivot - 1, arrLength);
  }
  if (pivot + 1 < initialRightPos) {
    quickSort(arr, pivot + 1, initialRightPos, arrLength);
  }
}
quickSort.swap = (arr, el1, el2) => {
  let swapedElem = arr[el1];
  arr[el1] = arr[el2];
  arr[el2] = swapedElem;
}

var
  i,
  arr1, arr2,
  length;

length = 1000000;


arr1 = [];
arr2 = [];
for (i = 0; i < length; i++) {
  arr1.push(Math.random());
  arr2.push(Math.random());
}

console.time("nativeSort");
arr1.sort(comparisonFunction);
console.timeEnd("nativeSort");


console.time("quickSort");
quickSort(arr2, 0, length - 1, length);
console.timeEnd("quickSort");

  • 6
    "...I've read that there are much faster options..." Where? – T.J. Crowder Nov 21 '16 at 13:50
  • 2
    Note that the native JavaScript .sort() is not required to be stable. I would be surprised if a JavaScript sort were faster than the native sort for an array of any significant size, though with certain input constraints a radix sort might be worth a try. – Pointy Nov 21 '16 at 13:51
  • 1
    @Liam: Except that the above clearly says it doesn't need a stable sort. (Mind you, if you're sorting numbers, stable vs. unstable is a distinction without a difference...) – T.J. Crowder Nov 21 '16 at 13:51
  • 2
    @mattstuehler - I can post a C++ example of quicksort that ends up running faster as the number of duplicates increase. After doing a Hoare like partition, there are two 2 line loops used to exclude all middle values == pivot value. Almost no impact in the average case, and O(n) running time if all values are the same. You could easily modify an existing javascript quicksort or introsort to follow the same logic. – rcgldr Nov 21 '16 at 18:36
  • 2
    Your quicksort implementation is flawed. You will get call stack overflow (maximum call stack exceeded error) if you have too many repeating items in the input array such as filling the 1M size input array with random integers among 1-100. I would recommend you to switch to while loops instead of recursive calls. Or.. i would say implement tail call optimized recursive functions alas as of today the TCO is a joke in JS engines. It doesn't work at all. – Redu Feb 17 '17 at 10:37
11

There are sort implementations that consistently beat the stock .sort (V8 at least), node-timsort being one of them. Example:

var SIZE = 1 << 20;

var a = [], b = [];

for(var i = 0; i < SIZE; i++) {
    var r = (Math.random() * 10000) >>> 0;
    a.push(r);
    b.push(r);
}

console.log(navigator.userAgent);

console.time("timsort");
timsort.sort(a, (x, y) => x - y);
console.timeEnd("timsort");

console.time("Array#sort");
b.sort((x, y) => x - y);
console.timeEnd("Array#sort");
<script src="https://rawgithub.com/mziccard/node-timsort/master/build/timsort.js"></script>

Here are some timings from different browsers I have around (Chakra anyone?):

Mozilla/5.0 (Macintosh; Intel Mac OS X 10_11_6) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/53.0.2785.113 Safari/537.36
timsort: 256.120ms
Array#sort: 341.595ms

Mozilla/5.0 (Macintosh; Intel Mac OS X 10_11_6) AppleWebKit/602.2.14 (KHTML, like Gecko) Version/10.0.1 Safari/602.2.14
timsort: 189.795ms
Array#sort: 245.725ms

Mozilla/5.0 (Macintosh; Intel Mac OS X 10.11; rv:51.0) Gecko/20100101 Firefox/51.0
timsort: 402.230ms
Array#sort: 187.900ms

So, the FF engine is very different from Chrome/Safari.

  • I'm using iceweasel and I get 227.418ms for timsort and 172.212ms for Array#Sort – acontell Nov 21 '16 at 14:43
  • 2
    @acontell: yep, strongly depends on the engine, see the update. – georg Nov 21 '16 at 17:26
  • I put together this Fiddle (jsfiddle.net/uqq54ho8/2), which compares the native sort with that timsort and the quick sort I posted above. For 5,000,000 random numbers, the results were: timsort: 1050ms native: 2536ms quick: 754ms. [Mozilla/5.0 (Macintosh; Intel Mac OS X 10_12_1) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/54.0.2840.98 Safari/537.36] – mattstuehler Nov 21 '16 at 18:09
2

No need to mark this as an answer, since it's not javascript, and doesn't have introsort's depth check to switch to heapsort.

Example C++ quicksort. It uses median of 3 to choose pivot value, Hoare partition scheme, then excludes middle values == pivot (at least one of these), and only uses recursion on the smaller partition, looping back on the larger partition to limit stack complexity to O(log2(n)) worst case. The worst case time complexity is still O(n^2), but this would require median of 3 to repeatedly choose small or large values, an unusual pattern. Sorted, or reverse sorted arrays are not an issue. If all values are the same, then time complexity is O(n). Adding a depth check to switch to heapsort (making this an introsort) would limit time complexity to O(n log(n)), but with a higher constant factor depending on how much heapsort path is used.

void QuickSort(uint32_t a[], size_t lo, size_t hi) {
    while(lo < hi){
        size_t i = lo, j = (lo+hi)/2, k = hi;
        uint32_t p;
        if (a[k] < a[i])            // median of 3
            std::swap(a[k], a[i]);
        if (a[j] < a[i])
            std::swap(a[j], a[i]);
        if (a[k] < a[j])
            std::swap(a[k], a[j]);
        p = a[j];
        i--;                        // Hoare partition
        k++;
        while (1) {
            while (a[++i] < p);
            while (a[--k] > p);
            if (i >= k)
                break;
            std::swap(a[i], a[k]);
        }
        i = k++;
        while(i > lo && a[i] == p)  // exclude middle values == pivot
            i--;
        while(k < hi && a[k] == p)
            k++;
        // recurse on smaller part, loop on larger part
        if((i - lo) <= (hi - k)){
            QuickSort(a, lo, i);
            lo = k;
        } else {
            QuickSort(a, k, hi);
            hi = i;
        }
    }
}

If space isn't an issue, then the merge sorts here may be better:

Native JavaScript sort performing slower than implemented mergesort and quicksort

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