# Algorithm to find k smallest numbers in array of n items

I'm trying to write an algorithm which can print the k smallest numbers in an n-size-array in O(n) time, but I cannot reduce the time complexity to n. How can I do this?

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I think some clarification is in order. Are you looking for the K smallest numbers in an array of N numbers? – Jerry Coffin Mar 21 '11 at 16:33
nop that's all explanations written in exercise...... i think i have to show all k small numbers in array.... :( – Jessica Mar 21 '11 at 16:58

you will need to find the k'th smallest element using 'selection algorithm', which is O(n), and then iterate the array again and return each element which is smaller/equals it.
selection algorithm: http://en.wikipedia.org/wiki/Selection_algorithm
you will have to pay attention if you have repeats: you will need to make sure you are not returning more then k elements (it is possible if for instance you have 1,2,...,k,k,k,...)

EDIT :
the full algorithm, and returning a list, as requested: let the array be `A`

`````` 1. find the k'th element in A using 'selection algorithm', let it be 'z'
2. initialize an empty list 'L'
3. initialize counter<-0
4. for each element in A:
4.1. if element < z:
4.1.1. counter<-counter + 1 ; L.add(element)
5. for each element in A:
5.1. if element == z AND count < k:
5.1.1. counter<-counter + 1 ; L.add(element)
6. return L
``````

note here that a 3rd iteration is required if your list might have duplicates. if it can't - it is needless, just change the condition in 4.1 to <=.
also note: L.add is inserting an element to a linked list and thus is O(1).

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the exercise asks me to show all k small numbers in list...... – Jessica Mar 21 '11 at 16:56
I'll edit with a full solution with a list. – amit Mar 21 '11 at 17:00
@Jessica, I updated the solution – amit Mar 21 '11 at 19:45
A small optimization to your 5th step: 5. while ( counter <= k ): 5.1 L.add(z); 5.2 counter <- counter + 1;. This will ensure that you don't go over the entire array again since you know the only element that will be added to the list L in step 5 is z and only (k - counter) iterations are required instead of N. – srikanta Mar 24 '11 at 2:18
@srikfreak: I decided not to make this optimization since it's clearly HW question, so I wanted to keep it simple and easy to understand, by avoiding adding conditions. In the case of implementing this algorithm to a real software - of course you are right, and this optimization must be done. – amit Mar 24 '11 at 7:05

I've done this in an interview before, and the fastest way to do this is

``````O(n log k).
with space: O(k) (thanks, @Nzbuu)
``````

Basically you're going to use a max-heap of size limited to k. For each item in the array, check to see if it's smaller than the max (only O(1)). If it is, put that in the heap (O(log k)) and remove the max. If its bigger, go to the next item.

Of course, the heap doesn't yield a sorted list of k items, but that can be done in O(k log k) which is easy.

Similarly, you can do the same for finding the largest k items, in which case you would use a min-heap.

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+1. This is what I would do. It's also easy to implement and only requires O(k) space. – Nzbuu Oct 12 '11 at 20:27
@Chet how do you start the loop ? What is in the root of the tree before the first iteration and how many child nodes does each node have in this case ...I know it can have atmost two nodes but what about in this case ? – Geek Jul 26 '12 at 15:14
@Geek The heap is initialized as empty and then you want to iterate over the first k items in your array to fill it up. Then proceed as I described, and your code will maintain the heap's size at a constant k. A heap is a standard tree data structure which usually has two children per node (see: en.wikipedia.org/wiki/Heap_(data_structure)) – Chet Jul 26 '12 at 17:05
Blum et al.'s selection algorithm takes `O(n)` time and `O(1)` space in the worst case. Even if you want to report the items sorted, you can do it in `O(n + k log(k))` time/`O(1)` space. – Yves Daoust Feb 28 '14 at 8:56

Assuming you're trying to show the K smallest numbers, you can use Hoare's Select algorithm to find the kth smallest number. That partitions the array into the smaller numbers, the kth number, and the larger numbers.

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+1, although beware that Hoare's quickselect algorithm isn't O(n), it has bad worst cases. The fixed version is called the "median-of-medians" method, and was not by Hoare. – Steve Jessop Mar 21 '11 at 17:29

This can be done in expected linear time(O(n)). First find the `kth` smallest element of the array (using pivot partition method for finding `kth` order statistic) and then simply iterate through the loop to check which elements are less than the `kth` smallest element. Note that this works correctly only for distinct element.

Here is the code in c:

``````    /*find the k smallest elements of an array in O(n) time. Using the Kth order
statistic-random pivoting algorithm to find the kth smallest element and then looping
through the array to find the elements smaller than kth smallest element.Assuming
distinct elements*/

#include <stdio.h>
#include <math.h>
#include <time.h>
#define SIZE 10
#define swap(X,Y) {int temp=X; X=Y; Y=temp;}

int partition(int array[], int start, int end)
{
if(start==end)
return start;
if(start>end)
return -1;
int pos=end+1,j;
for(j=start+1;j<=end;j++)
{
if(array[j]<=array[start] && pos!=end+1)
{
swap(array[j],array[pos]);
pos++;
}
else if(pos==end+1 && array[j]>array[start])
pos=j;
}
pos--;
swap(array[start], array[pos]);
return pos;
}

int order_statistic(int array[], int start, int end, int k)
{
if(start>end || (end-start+1)<k)
return -1;                   //return -1
int pivot=rand()%(end-start+1)+start, position, p;
swap(array[pivot], array[start]);
position=partition(array, start, end);
p=position;
position=position-start+1;                  //size of left partition
if(k==position)
return array[p];
else if(k<position)
return order_statistic(array, start,p-1,k);
else
return order_statistic(array,p+1,end,k-position);
}

void main()
{
srand((unsigned int)time(NULL));
int i, array[SIZE],k;
printf("Printing the array...\n");
for(i=0;i<SIZE;i++)
array[i]=abs(rand()%100), printf("%d ",array[i]);
printf("\n\nk=");
scanf("%d",&k);
int k_small=order_statistic(array,0,SIZE-1,k);
printf("\n\n");
if(k_small==-1)
{
printf("Not possible\n");
return ;
}
printf("\nk smallest elements...\n");
for(i=0;i<SIZE;i++)
{
if(array[i]<=k_small)
printf("%d ",array[i]);
}
}
``````
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Just sort the array with Merge Sort and then print the first k number, it will take n*log2(n) in the worst case.

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sorting is O(nlogn) – amit Mar 21 '11 at 16:32
@amit gr: you are right, I was just correcting that while you commented, thanks for commenting anyway. – Tamer Shlash Mar 21 '11 at 16:34
i tried but the exercise on the box suggests to write an algorithm in O(n)....... – Jessica Mar 21 '11 at 16:55
I don't think that's possible. – Roy Dictus Mar 21 '11 at 17:16

How about using a Heap to store the values. This cost is n when you go through each value in the array.

Then go through the Heap to get the smallest k values.

Runtime is O(n) + O(k) = O(n)

Of course, memory space is now O(n + n)

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note that deletion from a heap is O(n), so this solution will result in O(n+klog(n)) which might be bigger then O(n) for large k – amit Apr 18 '11 at 12:16
For this problem, as defined, k is fixed, so O(k log(n)) is o(n). – Nzbuu Oct 12 '11 at 20:25

As mentioned, there are two ways to accomplish such task:

1) You can sort the whole array of `n` elements with quicksort, heapsort or any `O (n log n)` sorting algorithm you want, and then pick the `m` smallest values in your array. This method will work in `O(n log n)`.

2) You can use selection algorithm to fink `m` smallest elements in your array. It will take `O(n)` time to find the kth smallest value, since you will iterate this algorithm m times, the overall time will be `m x O(n) = O(n)` .

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It is possible to find the k smallest of n elements in `O(n)` time (by which I mean true `O(n)` time, not `O(n + some function of k)`). Refer to the Wikipedia article "Selection algorithm", especially the subsections on "unordered partial sorting" and "median selection as pivot strategy", and also to the article "Median of medians" for the essential piece that makes this `O(n)`.

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Best possible solution to the problem is as follows.Use Quick sort to find pivots and discard the part where this kth element doesn't lie, and recursively find the next pivot. (It's kth Max finder , You need to change the if else condition to make it kth Min Finder) .Here is the JavaScript code-

``````  // Complexity is O(n log(n))
var source = [9, 2, 7, 11, 1, 3, 14, 22];

var kthMax = function(minInd, MaxInd, kth) {
// pivotInd stores the pivot position
// for current iteration
var temp, pivotInd = minInd;
if (minInd >= MaxInd) {
return source[pivotInd];
}

for (var i = minInd; i < MaxInd; i++) {
//If an element is greater than chosen pivot (i.e. last element)
//Swap it with pivotPointer element. then increase ponter
if (source[i] > source[MaxInd]) {
temp = source[i];
source[i] = source[pivotInd];
source[pivotInd] = temp;
pivotInd++;
}
}
// we have found position for pivot elem.
// swap it to that position place .
temp = source[pivotInd];
source[pivotInd] = source[MaxInd];
source[MaxInd] = temp;

// Only try to sort the part in which kth index lies.
if (kth > pivotInd) {
return kthMax(pivotInd + 1, MaxInd, kth);
} else if (kth < pivotInd) {
return kthMax(minInd, pivotInd - 1, kth);
} else {
return source[pivotInd];
}

}
// last argument is kth-1 , so if give 2 it will give you,
// 3rd max which is 11

console.log(kthMax(0, source.length - 1, 2));
``````
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