An adaptive and stable sort algorithm based on merging that requires fewer than nlog(n)
comparisons when run on partially sorted arrays. The algorithm uses O(n) memory and still runs in O(nlogn)
(worst case) on random arrays.
This implementation is based on the original
TimSort developed
by Tim Peters for Python's lists (code here).
TimSort has been also adopted in Java starting from version 7.
- @novacrazy: ported the module to ES6/ES7 and made it available via bower
- @kasperisager: implemented faster lexicographic comparison of small integers
Install the package with npm:
npm install --save timsort
And use it:
var TimSort = require('timsort');
var arr = [...];
TimSort.sort(arr);You can also install it with bower:
bower install timsort
As array.sort() by default the timsort module sorts according to
lexicographical order.
You can also provide your own compare function (to sort any object) as:
function numberCompare(a,b) {
return a-b;
}
var arr = [...];
var TimSort = require('timsort');
TimSort.sort(arr, numberCompare);You can also sort only a specific subrange of the array:
TimSort.sort(arr, 5, 10);
TimSort.sort(arr, numberCompare, 5, 10);A benchmark is provided in benchmark/index.js. It compares the timsort module against
the default array.sort method in the numerical sorting of different types of integer array
(as described here):
- Random array
- Descending array
- Ascending array
- Ascending array with 3 random exchanges
- Ascending array with 10 random numbers in the end
- Array of equal elements
- Random Array with many duplicates
- Random Array with some duplicates
For any of the array types the sorting is repeated several times and for different array sizes, average execution time is then printed. I run the benchmark on Node v6.3.1 (both pre-compiled and compiled from source, results are very similar), obtaining the following values:
| Execution Time (ns) | Speedup | |||
|---|---|---|---|---|
| Array Type | Length | TimSort.sort | array.sort | |
| Random | 10 | 404 | 1583 | 3.91 |
| 100 | 7147 | 4442 | 0.62 | |
| 1000 | 96395 | 59979 | 0.62 | |
| 10000 | 1341044 | 6098065 | 4.55 | |
| Descending | 10 | 180 | 1881 | 10.41 |
| 100 | 682 | 19210 | 28.14 | |
| 1000 | 3809 | 185185 | 48.61 | |
| 10000 | 35878 | 5392428 | 150.30 | |
| Ascending | 10 | 173 | 816 | 4.69 |
| 100 | 578 | 18147 | 31.34 | |
| 1000 | 2551 | 331993 | 130.12 | |
| 10000 | 22098 | 5382446 | 243.57 | |
| Ascending + 3 Rand Exc | 10 | 232 | 927 | 3.99 |
| 100 | 1059 | 15792 | 14.90 | |
| 1000 | 3525 | 300708 | 85.29 | |
| 10000 | 27455 | 4781370 | 174.15 | |
| Ascending + 10 Rand End | 10 | 378 | 1425 | 3.77 |
| 100 | 1707 | 23346 | 13.67 | |
| 1000 | 5818 | 334744 | 57.53 | |
| 10000 | 38034 | 4985473 | 131.08 | |
| Equal Elements | 10 | 164 | 766 | 4.68 |
| 100 | 520 | 3188 | 6.12 | |
| 1000 | 2340 | 27971 | 11.95 | |
| 10000 | 17011 | 281672 | 16.56 | |
| Many Repetitions | 10 | 396 | 1482 | 3.74 |
| 100 | 7282 | 25267 | 3.47 | |
| 1000 | 105528 | 420120 | 3.98 | |
| 10000 | 1396120 | 5787399 | 4.15 | |
| Some Repetitions | 10 | 390 | 1463 | 3.75 |
| 100 | 6678 | 20082 | 3.01 | |
| 1000 | 104344 | 374103 | 3.59 | |
| 10000 | 1333816 | 5474000 | 4.10 | |
TimSort.sort is faster than array.sort on almost of the tested array types.
In general, the more ordered the array is the better TimSort.sort performs with respect to array.sort (up to 243 times faster on already sorted arrays).
And also, in general, the bigger the array the more we benefit from using
the timsort module.
These data strongly depend on Node.js version and the machine on which the benchmark is run. I strongly encourage you to run the benchmark on your own setup with:
npm run benchmark
Please also notice that:
- This benchmark is far from exhaustive. Several cases are not considered and the results must be taken as partial
- inlining is surely playing an active role in
timsortmodule's good performance - A more accurate comparison of the algorithms would require implementing
array.sortin pure javascript and counting element comparisons
TimSort is stable which means that equal items maintain their relative order after sorting. Stability is a desirable property for a sorting algorithm. Consider the following array of items with an height and a weight.
[
{ height: 100, weight: 80 },
{ height: 90, weight: 90 },
{ height: 70, weight: 95 },
{ height: 100, weight: 100 },
{ height: 80, weight: 110 },
{ height: 110, weight: 115 },
{ height: 100, weight: 120 },
{ height: 70, weight: 125 },
{ height: 70, weight: 130 },
{ height: 100, weight: 135 },
{ height: 75, weight: 140 },
{ height: 70, weight: 140 }
]Items are already sorted by weight. Sorting the array
according to the item's height with the timsort module
results in the following array:
[
{ height: 70, weight: 95 },
{ height: 70, weight: 125 },
{ height: 70, weight: 130 },
{ height: 70, weight: 140 },
{ height: 75, weight: 140 },
{ height: 80, weight: 110 },
{ height: 90, weight: 90 },
{ height: 100, weight: 80 },
{ height: 100, weight: 100 },
{ height: 100, weight: 120 },
{ height: 100, weight: 135 },
{ height: 110, weight: 115 }
]Items with the same height are still sorted by weight which means they preserved their relative order.
array.sort, instead, is not guarranteed to be stable. In Node v0.12.7
sorting the previous array by height with array.sort results in:
[
{ height: 70, weight: 140 },
{ height: 70, weight: 95 },
{ height: 70, weight: 125 },
{ height: 70, weight: 130 },
{ height: 75, weight: 140 },
{ height: 80, weight: 110 },
{ height: 90, weight: 90 },
{ height: 100, weight: 100 },
{ height: 100, weight: 80 },
{ height: 100, weight: 135 },
{ height: 100, weight: 120 },
{ height: 110, weight: 115 }
]As you can see the sorting did not preserve weight ordering for items with the
same height.