# Most suitable sorting algorithm

I have to sort a large array of doubles of size 100000.

The point is that I do not want to sort the whole array but only find the largest 20000 elements in descending order.

Currently I am using selection sort. Any way to improve the performance?

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merge sort is more stable –  Balaswamy Vaddeman Jan 31 '12 at 4:41
@Balaswamy What does a stable sort buy you here, exactly? –  Nick Barnes Jan 31 '12 at 4:49
Are you asking for something substantially different from taking the first 20,000 elements and sorting them into descending order? –  Jerry Coffin Jan 31 '12 at 4:59
You want to find the Top 20K items, or any run of 20K items ? –  wildplasser Jan 31 '12 at 13:52
Must be the top 20K, nothing else really makes sense. Plus the asker mentioned somewhere below that they're running selection sort 20,000 times, and top 20K is what that'll give you. –  Nick Barnes Jan 31 '12 at 22:30

100,000 is not a very large array on most modern devices. Are you sure you can't just sort all of them using a standard library sorting function?

You can avoid a full sort by using a variation of heapsort. Normally in a heapsort you build a heap of the entire data set (100,000 elements in your case). Instead, only allow the heap to grow to 20,000 elements. Keep the largest element at the top of the heap. Once the heap is full (20,000 elements), you compare each subsequent element of the data set to the top of the heap. If the next data set element is larger than the top of the heap, just skip it. If it's smaller than the top of the heap, pop the top of the heap and insert the element from the data set.

Once you've gone through the entire data set, you have a heap of the 20,000 smallest elements of the data set. You can pop them one-by-one into an array to have a sorted array.

This algorithm runs in O(N log K) time, where N is the size of the data set (100,000 in your example) and K is the number of elements you want to keep (20,000 in your example).

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I think you can improve this a bit. You're building the heap in O(NlogK) and retrieving the values in O(KlogK). Instead, you can build the entire 100,000-element heap in O(N), and just pull 20,000 values from it in O(KlogN). KlogN < NlogK, so you might come out in front (though the constants could easily change that). –  Nick Barnes Jan 31 '12 at 5:27
That could definitely be faster. Note that if you can't modify the original array (or you receive the data as a stream) you will need O(N) storage instead of O(K) storage. –  rob mayoff Jan 31 '12 at 5:30

you can improve by using Quick sort algorithm to improve its efficiency, or you can use merge sort that will do this in nlog(n) time. calculate boths running time and find which is suitable for your snario.

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I tried quick sort first. But quick sort takes more time than selection since I have to quicksort the whole array and not just 20000 elements –  mihsathe Jan 31 '12 at 4:52
so check about MERGE SORT algorithm that will be better otherwise it is because of your element values are not suitable for nlog(n) running time –  AqEeL Jan 31 '12 at 14:29
It's not a matter of how "suitable" the data is. The selection sort is faster here because, if you only need the first 20,000 elements, you can terminate it after 20,000 iterations. We're looking for a faster sort with the same property. Mergesort doesn't have it. Quicksort does, but you haven't explained how. –  Nick Barnes Jan 31 '12 at 22:16
in quick sort algorithm first it calculates length of array then it do partition, so make length of array as you need to sort there –  AqEeL Feb 3 '12 at 5:43

I'd suggest starting with bucket sort and then using some of the simpler algorithms to sort each bucket. If any of them is still too big, you can either use bucket sort again or another nlog(n) method (such as mergesort or quicksort). Otherwise, selection (or better, insertion) will do just fine.

Just for comparison: selection/insertion/quicksort is O(n*n), mergesort is O(nlog(n)), bucket sort is O(n*k), where k is the number of buckets. Choose k < log(n) and you'll get a better performance than the alternatives.

Note: quicksort's worst case scenario is O(n*n), but in practice it is much faster.

Update O(n*k) is the average performance for bucket sort, not the worst case, so the same note above applies.

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If you use bubble sort algorithm and move to left smaller number, after 20.000th iteration there will be smallest numbers in the end of the array in descending order.
For example 3 7 2 5 1 4 8 array:
1 iteration: 7 3 5 2 4 8 1
2 iteration: 7 5 3 4 8 2 1
3 iteration: 7 5 4 8 3 2 1

After 3rd iteration there are 3 smallest elements in the end in descending order.
I recommend this because in this case complexity depends from number of elements you want to sort. And if you want to get small number of elements your program will work fast. Complexity is O(k*n) where k is number of elements you want to get.

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no, because he wants only some of the elements. Complexity is O(k*n) where k is number of elements he want to get. If he want to get only one element, this algorithm has O(n) complexity –  shift66 Jan 31 '12 at 4:56
But that is pretty much what I am doing. Running selection sort 20000 times. –  mihsathe Jan 31 '12 at 7:29

You can get the first K sorted elements with a modified quicksort. The key is to realise that, once you've reordered your list around the pivot, you can forget about sorting the right-hand side if your pivot is ≥K.

In short, just replace the "right-hand" recursive call to `quicksort()` with

``````if (pivot >= k) quicksort(...)
``````

Alternatively, you could follow the standard heapsort algorithm, but stop after pulling K elements from the heap.

Both of these approaches take O(N + KlogN) time, O(N) space, and can be done in-place.

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