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I believe there's a way to find the kth largest element in an unsorted array of length n in O(n). Or perhaps it's "expected" O(n) or something. How can we do this?

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24  
By the way, pretty much every algorithm described here turns into O(n^2) or O(n log n) when k==n. That is, I don't think a single one of them is O(n) for all values of k. I got modded down for pointing this out but thought you should know anyway. –  Kirk Strauser Nov 4 '08 at 22:09
11  
Selection algorithms can be O(n) for any fixed value of k. That is, you can have a selection algorithm for k=25 that is O(n) for any value of n, and you can do this for any particular value of k that is unrelated to n. The case in which the algorithm is no longer O(n) is when the value of k has some dependency on the value of n, such as k=n or k=n/2. This doesn't, however, mean that if you happen to run the k=25 algorithm on a list of 25 items that it is suddenly no longer O(n) because the O-notation describes a property of the algorithm, not a particular run of it. –  Tyler McHenry Jul 31 '09 at 16:58
1  
I was asked this question in an amazon interview as a general case of finding the second greatest element. By the way the interviewer lead the interview I didn't ask if I could destroy the original array (i.e. sorting it), so I came up with a complicated solution. –  Sambatyon May 9 '11 at 17:43
2  
This is Question 9 in Column 11 (Sorting) of Programming Pearls by Jon Bentley. –  Qiang Xu Sep 13 '12 at 20:08

22 Answers 22

up vote 89 down vote accepted

This is called finding the k-th order statistic. There's a very simple randomized algorithm (called quickselect) taking O(n) average time, and a pretty complicated non-randomized algorithm taking O(n) worst case time. There's some info on Wikipedia, but it's not very good.

Everything you need is in these powerpoint slides. Just to extract the basic algorithm of the O(n) worst-case algorithm:

Select(A,n,i):
    Divide input into ⌈n/5⌉ groups of size 5.

    /* Partition on median-of-medians */
    medians = array of each group’s median.
    pivot = Select(medians, ⌈n/5⌉, ⌈n/10⌉)
    Left Array L and Right Array G = partition(A, pivot)

    /* Find ith element in L, pivot, or G */
    k = |L| + 1
    If i = k, return pivot
    If i < k, return Select(L, k-1, i)
    If i > k, return Select(G, n-k, i-k)

It's also very nicely detailed in the Introduction to Algorithms book by Cormen et al.

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1  
Thank you for the slides. –  Kshitij Banerjee Jun 24 at 7:33

If you want a true O(n) algorithm, as opposed to O(kn) or something like that, then you should use quickselect (it's basically quicksort where you throw out the partition that you're not interested in). My prof has a great writeup, with the runtime analysis: (reference)

The QuickSelect algorithm quickly finds the k-th smallest element of an unsorted array of n elements. It is a RandomizedAlgorithm, so we compute the worst-case expected running time.

Here is the algorithm.

QuickSelect(A, k)
  let r be chosen uniformly at random in the range 1 to length(A)
  let pivot = A[r]
  let A1, A2 be new arrays
  # split into a pile A1 of small elements and A2 of big elements
  for i = 1 to n
    if A[i] < pivot then
      append A[i] to A1
    else if A[i] > pivot then
      append A[i] to A2
    else
      # do nothing
  end for
  if k <= length(A1):
    # it's in the pile of small elements
    return QuickSelect(A1, k)
  else if k > length(A) - length(A2)
    # it's in the pile of big elements
    return QuickSelect(A2, k - (length(A) - length(A2))
  else
    # it's equal to the pivot
    return pivot

What is the running time of this algorithm? If the adversary flips coins for us, we may find that the pivot is always the largest element and k is always 1, giving a running time of

T(n) = Theta(n) + T(n-1) = Theta(n2)

But if the choices are indeed random, the expected running time is given by

T(n) i=1 to nT(max(i, n-i-1))

where we are making the not entirely reasonable assumption that the recursion always lands in the larger of A1 or A2.

Let's guess that T(n) <= an for some a. Then we get

T(n) 
 i=1 to nT(max(i-1, n-i))
 = cn + (1/n) ∑i=1 to floor(n/2) T(n-i) + (1/n) ∑i=floor(n/2)+1 to n T(i)
 i=floor(n/2) to n T(i)
 i=floor(n/2) to n ai

and now somehow we have to get the horrendous sum on the right of the plus sign to absorb the cn on the left. If we just bound it as 2(1/n) ∑i=n/2 to n an, we get roughly 2(1/n)(n/2)an = an. But this is too big - there's no room to squeeze in an extra cn. So let's expand the sum using the arithmetic series formula:

i=floor(n/2) to n i  
 = ∑i=1 to n i - ∑i=1 to floor(n/2) i  
 = n(n+1)/2 - floor(n/2)(floor(n/2)+1)/2  
 2/2 - (n/4)2/2  
 = (15/32)n2

where we take advantage of n being "sufficiently large" to replace the ugly floor(n/2) factors with the much cleaner (and smaller) n/4. Now we can continue with

cn + 2 (1/n) ∑i=floor(n/2) to n ai,
 2
 = n (c + (15/16)a)
 

provided a > 16c.

This gives T(n) = O(n). It's clearly Omega(n), so we get T(n) = Theta(n).

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1  
+1, very detailed explanation indeed –  Matthieu M. Oct 19 '09 at 10:52
    
+1, Jim Aspnes FTW –  viksit Mar 8 '10 at 22:38
1  
Nice pseudo-code, clear explanation. Thanks for providing the link. –  Qiang Xu Sep 13 '12 at 20:08
3  
Quickselect is only O(n) in the average case. The median-of-medians algorithm can be used to solve the problem in O(n) time in the worst case. –  John Kurlak Jan 19 '13 at 5:01
1  
@MrROY Given that we splitted A into A1 and A2 around the pivot, we know that length(A) == length(A1)+length(A2)+1. So, k > length(A)-length(A2) is equivalent to k > length(A1)+1, which is true when k is somewhere in A2. –  Filipe Gonçalves Aug 17 at 19:28

The keywords you are looking for are selection algorithm: Wikipedia lists a number of different ways of doing this.

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A quick Google on that ('kth largest element array') returned this: http://discuss.joelonsoftware.com/default.asp?interview.11.509587.17

"Make one pass through tracking the three largest values so far." (it was specifically for 3d largest)

and..

Build a heap/priority queue.  O(n)
Pop top element.  O(log n)
Pop top element.  O(log n)
Pop top element.  O(log n)

Total = O(n) + 3 O(log n) = O(n)
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5  
well, its actually O(n)+ O( k log n) which doesn't reduce for significant values of K –  Jimmy Oct 30 '08 at 21:19
    
right - Big-O is all about approximations :) –  warren Oct 30 '08 at 21:21
    
also note: I quoted the site :) –  warren Oct 30 '08 at 21:22
2  
But finding the insertion point in that doubly-linked list is O(k). –  Kirk Strauser Oct 30 '08 at 23:25
1  
And if k is fixed, O(k) = O(1) –  Tyler McHenry Jul 31 '09 at 17:00

A Programmer's Companion to Algorithm Analysis gives a version that is O(n), although the author states that the constant factor is so high, you'd probably prefer the naive sort-the-list-then-select method.

I answered the letter of your question :)

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1  
Not really true in all cases. I have implemented median-of-medians and compared it to built-in Sort method in .NET and custom solution really ran faster by order of magnitude. Now the real question is: does that matter to you in given circumstances. Writing and debugging 100 lines of code compared to one liner pays off only if that code is going to be executed so many times that user starts noticing the difference in running time and feel discomfort waiting for the operation to complete. –  Zoran Horvat Jul 19 '13 at 9:14

You do like quicksort. Pick an element at random and shove everything either higher or lower. At this point you'll know which element you actually picked, and if it is the kth element you're done, otherwise you repeat with the bin (higher or lower), that the kth element would fall in. Statistically speaking, the time it takes to find the kth element grows with n, O(n).

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The C++ standard library has almost exactly that function, although it does modify your data. It has expected linear run-time, O(N), and it also does a partial sort.

const int N = ...;
double a[N];
// ... 
const int m = ...; // m < N
nth_element (a, a + m, a + N);
// a[m] contains the mth element in a
share|improve this answer
    
No, it has an expected average O(n) runtime. For example, quicksort is O(nlogn) on average with a worst case of O(n^2). Wow, something straight up factually wrong! –  Kirk Strauser Oct 30 '08 at 23:30
4  
No, there's nothing factually wrong with this answer. It works and the C++ standard requires an expected linear run time. –  David Nehme Oct 31 '08 at 0:21
    
I was asked in interview to assume space availability of O(k) and 'n' is very huge. I couldn't tell him O(n) solution as I thought nth_element would need space o(n). Am i wrong ?isn't underlying algorithm is quicksort based for nth_element ? –  Manu Sep 13 '11 at 17:27

Read Chapter 9, Medians and Other statistics from Cormen's "Introduction to Algorithms", 2nd Ed. It has an expected linear time algorithm for selection. It's not something that people would randomly come up with in a few minutes.. A heap sort, btw, won't work in O(n), it's O(nlgn).

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I implemented finding kth minimimum in n unsorted elements using dynamic programming, specifically tournament method. The execution time is O(n + klog(n)). The mechanism used is listed as one of methods on Wikipedia page about Selection Algorithm (as indicated in one of the posting above). You can read about the algorithm and also find code (java) on my blog page Finding Kth Minimum. In addition the logic can do partial ordering of the list - return first K min (or max) in O(klog(n)) time.

Though the code provided result kth minimum, similar logic can be employed to find kth maximum in O(klog(n)), ignoring the pre-work done to create tournament tree.

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You can do it in O(n + kn) = O(n) (for constant k) for time and O(k) for space, by keeping track of the k largest elements you've seen.

For each element in the array you can scan the list of k largest and replace the smallest element with the new one if it is bigger.

Warren's priority heap solution is neater though.

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This would have a worst case of O(n^2) where you're asked for the smallest item. –  Elie Oct 30 '08 at 21:23
1  
"Smallest item" means that k=n, so k is no longer constant. –  Tyler McHenry Jul 31 '09 at 17:01

Find the median of the array in linear time, then use partition procedure exactly as in quicksort to divide the array in two parts, values to the left of the median lesser( < ) than than median and to the right greater than ( > ) median, that too can be done in lineat time, now, go to that part of the array where kth element lies, Now recurrence becomes: T(n) = T(n/2) + cn which gives me O (n) overal.

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Although not very sure about O(n) complexity, but it will be sure to be between O(n) and nLog(n). Also sure to be closer to O(n) than nLog(n). Function is written in Java

public int quickSelect(ArrayList<Integer>list, int nthSmallest){
    //Choose random number in range of 0 to array length
    Random random =  new Random();
    //This will give random number which is not greater than length - 1
    int pivotIndex = random.nextInt(list.size() - 1); 

    int pivot = list.get(pivotIndex);

    ArrayList<Integer> smallerNumberList = new ArrayList<Integer>();
    ArrayList<Integer> greaterNumberList = new ArrayList<Integer>();

    //Split list into two. 
    //Value smaller than pivot should go to smallerNumberList
    //Value greater than pivot should go to greaterNumberList
    //Do nothing for value which is equal to pivot
    for(int i=0; i<list.size(); i++){
        if(list.get(i)<pivot){
            smallerNumberList.add(list.get(i));
        }
        else if(list.get(i)>pivot){
            greaterNumberList.add(list.get(i));
        }
        else{
            //Do nothing
        }
    }

    //If smallerNumberList size is greater than nthSmallest value, nthSmallest number must be in this list 
    if(nthSmallest < smallerNumberList.size()){
        return quickSelect(smallerNumberList, nthSmallest);
    }
    //If nthSmallest is greater than [ list.size() - greaterNumberList.size() ], nthSmallest number must be in this list
    //The step is bit tricky. If confusing, please see the above loop once again for clarification.
    else if(nthSmallest > (list.size() - greaterNumberList.size())){
        //nthSmallest will have to be changed here. [ list.size() - greaterNumberList.size() ] elements are already in 
        //smallerNumberList
        nthSmallest = nthSmallest - (list.size() - greaterNumberList.size());
        return quickSelect(greaterNumberList,nthSmallest);
    }
    else{
        return pivot;
    }
}
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Explanation of the median - of - medians algorithm to find the k-th largest integer out of n can be found here: http://cs.indstate.edu/~spitla/presentation.pdf

Implementation in c++ is below:

#include <iostream>
#include <vector>
#include <algorithm>
using namespace std;

int findMedian(vector<int> vec){
//    Find median of a vector
    int median;
    size_t size = vec.size();
    median = vec[(size/2)];
    return median;
}

int findMedianOfMedians(vector<vector<int> > values){
    vector<int> medians;

    for (int i = 0; i < values.size(); i++) {
        int m = findMedian(values[i]);
        medians.push_back(m);
    }

    return findMedian(medians);
}

void selectionByMedianOfMedians(const vector<int> values, int k){
//    Divide the list into n/5 lists of 5 elements each
    vector<vector<int> > vec2D;

    int count = 0;
    while (count != values.size()) {
        int countRow = 0;
        vector<int> row;

        while ((countRow < 5) && (count < values.size())) {
            row.push_back(values[count]);
            count++;
            countRow++;
        }
        vec2D.push_back(row);
    }

    cout<<endl<<endl<<"Printing 2D vector : "<<endl;
    for (int i = 0; i < vec2D.size(); i++) {
        for (int j = 0; j < vec2D[i].size(); j++) {
            cout<<vec2D[i][j]<<" ";
        }
        cout<<endl;
    }
    cout<<endl;

//    Calculating a new pivot for making splits
    int m = findMedianOfMedians(vec2D);
    cout<<"Median of medians is : "<<m<<endl;

//    Partition the list into unique elements larger than 'm' (call this sublist L1) and
//    those smaller them 'm' (call this sublist L2)
    vector<int> L1, L2;

    for (int i = 0; i < vec2D.size(); i++) {
        for (int j = 0; j < vec2D[i].size(); j++) {
            if (vec2D[i][j] > m) {
                L1.push_back(vec2D[i][j]);
            }else if (vec2D[i][j] < m){
                L2.push_back(vec2D[i][j]);
            }
        }
    }

//    Checking the splits as per the new pivot 'm'
    cout<<endl<<"Printing L1 : "<<endl;
    for (int i = 0; i < L1.size(); i++) {
        cout<<L1[i]<<" ";
    }

    cout<<endl<<endl<<"Printing L2 : "<<endl;
    for (int i = 0; i < L2.size(); i++) {
        cout<<L2[i]<<" ";
    }

//    Recursive calls
    if ((k - 1) == L1.size()) {
        cout<<endl<<endl<<"Answer :"<<m;
    }else if (k <= L1.size()) {
        return selectionByMedianOfMedians(L1, k);
    }else if (k > (L1.size() + 1)){
        return selectionByMedianOfMedians(L2, k-((int)L1.size())-1);
    }

}

int main()
{
    int values[] = {2, 3, 5, 4, 1, 12, 11, 13, 16, 7, 8, 6, 10, 9, 17, 15, 19, 20, 18, 23, 21, 22, 25, 24, 14};

    vector<int> vec(values, values + 25);

    cout<<"The given array is : "<<endl;
    for (int i = 0; i < vec.size(); i++) {
        cout<<vec[i]<<" ";
    }

    selectionByMedianOfMedians(vec, 8);

    return 0;
}
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iterate through the list. if the current value is larger than the stored largest value, store it as the largest value and bump the 1-4 down and 5 drops off the list. If not,compare it to number 2 and do the same thing. Repeat, checking it against all 5 stored values. this should do it in O(n)

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That "bump" is O(n) if you're using an array, or down to O(log n) (I think) if you use a better structure. –  Kirk Strauser Oct 30 '08 at 21:11
    
It needn't be O(log k) - if the list is a linked list then adding the new element to the top and dropping the last element is more like O(2) –  Alnitak Oct 30 '08 at 21:14
    
The bump would be O(k) for an array-backed list, O(1) for an appropriately-linked list. Either way, this sort of question generally assumes it to be of minimal impact compared to n and it introduces no more factors of n. –  bobince Oct 30 '08 at 21:16
    
it would also be O(1) if the bump uses a ring-buffer –  Alnitak Oct 30 '08 at 21:18
    
Anyhow, the comment's algorithm is incomplete, it fails to consider an element of n coming in which is the new (eg) second-largest. Worst case behaviour, where each element in n must be compared with each in the highscore table, is O(kn) - but that still probably means O(n) in terms of the question. –  bobince Oct 30 '08 at 21:21

i would like to suggest one answer

if we take the first k elements and sort them into a linked list of k values

now for every other value even for the worst case if we do insertion sort for rest n-k values even in the worst case number of comparisons will be k*(n-k) and for prev k values to be sorted let it be k*(k-1) so it comes out to be (nk-k) which is o(n)

cheers

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sorting takes nlogn time... the algorithm should run in linear time –  MrDatabase Nov 13 '09 at 19:55

Below is the link to full implementation with quite an extensive explanation how the algorithm for finding Kth element in an unsorted algorithm works. Basic idea is to partition the array like in QuickSort. But in order to avoid extreme cases (e.g. when smallest element is chosen as pivot in every step, so that algorithm degenerates into O(n^2) running time), special pivot selection is applied, called median-of-medians algorithm. The whole solution runs in O(n) time in worst and in average case.

Here is link to the full article (it is about finding Kth smallest element, but the principle is the same for finding Kth largest):

Finding Kth Smallest Element in an Unsorted Array

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This is an implementation in Javascript.

If you release the constraint that you cannot modify the array, you can prevent the use of extra memory using two indexes to identify the "current partition" (in classic quicksort style - http://www.nczonline.net/blog/2012/11/27/computer-science-in-javascript-quicksort/).

function kthMax(a, k){
    var size = a.length;

    var pivot = a[ parseInt(Math.random()*size) ]; //Another choice could have been (size / 2) 

    //Create an array with all element lower than the pivot and an array with all element higher than the pivot
    var i, lowerArray = [], upperArray = [];
    for (i = 0; i  < size; i++){
        var current = a[i];

        if (current < pivot) {
            lowerArray.push(current);
        } else if (current > pivot) {
            upperArray.push(current);
        }
    }

    //Which one should I continue with?
    if(k <= upperArray.length) {
        //Upper
        return kthMax(upperArray, k);
    } else {
        var newK = k - (size - lowerArray.length);

        if (newK > 0) {
            ///Lower
            return kthMax(lowerArray, newK);
        } else {
            //None ... it's the current pivot!
            return pivot;
        }   
    }
}  

If you want to test how it perform, you can use this variation:

    function kthMax (a, k, logging) {
         var comparisonCount = 0; //Number of comparison that the algorithm uses
         var memoryCount = 0;     //Number of integers in memory that the algorithm uses
         var _log = logging;

         if(k < 0 || k >= a.length) {
            if (_log) console.log ("k is out of range"); 
            return false;
         }      

         function _kthmax(a, k){
             var size = a.length;
             var pivot = a[parseInt(Math.random()*size)];
             if(_log) console.log("Inputs:", a,  "size="+size, "k="+k, "pivot="+pivot);

             // This should never happen. Just a nice check in this exercise
             // if you are playing with the code to avoid never ending recursion            
             if(typeof pivot === "undefined") {
                 if (_log) console.log ("Ops..."); 
                 return false;
             }

             var i, lowerArray = [], upperArray = [];
             for (i = 0; i  < size; i++){
                 var current = a[i];
                 if (current < pivot) {
                     comparisonCount += 1;
                     memoryCount++;
                     lowerArray.push(current);
                 } else if (current > pivot) {
                     comparisonCount += 2;
                     memoryCount++;
                     upperArray.push(current);
                 }
             }
             if(_log) console.log("Pivoting:",lowerArray, "*"+pivot+"*", upperArray);

             if(k <= upperArray.length) {
                 comparisonCount += 1;
                 return _kthmax(upperArray, k);
             } else if (k > size - lowerArray.length) {
                 comparisonCount += 2;
                 return _kthmax(lowerArray, k - (size - lowerArray.length));
             } else {
                 comparisonCount += 2;
                 return pivot;
             }
     /* 
      * BTW, this is the logic for kthMin if we want to implement that... ;-)
      * 

             if(k <= lowerArray.length) {
                 return kthMin(lowerArray, k);
             } else if (k > size - upperArray.length) {
                 return kthMin(upperArray, k - (size - upperArray.length));
             } else 
                 return pivot;
     */            
         }

         var result = _kthmax(a, k);
         return {result: result, iterations: comparisonCount, memory: memoryCount};
     }

The rest of the code is just to create some playground:

    function getRandomArray (n){
        var ar = [];
        for (var i = 0, l = n; i < l; i++) {
            ar.push(Math.round(Math.random() * l))
        }

        return ar;
    }

    //Create a random array of 50 numbers
    var ar = getRandomArray (50);   

Now, run you tests a few time. Because of the Math.random() it will produce every time different results:

    kthMax(ar, 2, true);
    kthMax(ar, 2);
    kthMax(ar, 2);
    kthMax(ar, 2);
    kthMax(ar, 2);
    kthMax(ar, 2);
    kthMax(ar, 34, true);
    kthMax(ar, 34);
    kthMax(ar, 34);
    kthMax(ar, 34);
    kthMax(ar, 34);
    kthMax(ar, 34);

If you test it a few times you can see even empirically that the number of iterations is, on average, O(n) ~= constant * n and the value of k does not affect the algorithm.

share|improve this answer

Sexy quickselect in Python

def quickselect(arr, k):
''' k = 1 returns first element in ascending order'''

r = random.randrange(0, len(arr))

a1 = [i for i in arr if i < arr[r]] '''partition'''
a2 = [i for i in arr if i > arr[r]]

if k <= len(a1):
    return quickselect(a1, k)
elif k > len(arr)-len(a2):
    return quickselect(a2, k - (len(arr) - len(a2)))
else:
    return arr[r]
share|improve this answer

What I would do is this:

initialize empty doubly linked list l
for each element e in array
    if e larger than head(l)
        make e the new head of l
        if size(l) > k
            remove last element from l

the last element of l should now be the kth largest element

You can simply store pointers to the first and last element in the linked list. They only change when updates to the list are made.

Update:

initialize empty sorted tree l
for each element e in array
    if e between head(l) and tail(l)
        insert e into l // O(log k)
        if size(l) > k
            remove last element from l

the last element of l should now be the kth largest element
share|improve this answer
    
What if e is smaller than head(l)? It could still be larger than the kth largest element, but would never get added to that list. You will need to sort the list of items in order for this to work, in ascending order. –  Elie Oct 30 '08 at 21:22
    
You are right, guess I'll need to think this through some more. :-) –  Jasper Bekkers Oct 30 '08 at 21:27
    
The solution would be to check if e is between head(l) and tail(l) and insert it at the correct position if it is. Making this O(kn). You could make it O(n log k) when using a binary tree that keeps track of the min and max elements. –  Jasper Bekkers Oct 30 '08 at 21:30

First we can build a BST from unsorted array which takes O(n) time and from the BST we can find the kth smallest element in O(log(n)) which over all counts to an order of O(n).

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There is also Wirth's selection algorithm, which has a simpler implementation than QuickSelect. Wirth's selection algorithm is slower than QuickSelect, but with some improvements it becomes faster.

In more detail. Using Vladimir Zabrodsky's MODIFIND optimization and the median-of-3 pivot selection and paying some attention to the final steps of the partitioning part of the algorithm, i've came up with the following algorithm (imaginably named "LefSelect"):

#define F_SWAP(a,b) { float temp=(a);(a)=(b);(b)=temp; }

# Note: The code needs more than 2 elements to work
float lefselect(float a[], const int n, const int k) {
    int l=0, m = n-1, i=l, j=m;
    float x;

    while (l<m) {
        if( a[k] < a[i] ) F_SWAP(a[i],a[k]);
        if( a[j] < a[i] ) F_SWAP(a[i],a[j]);
        if( a[j] < a[k] ) F_SWAP(a[k],a[j]);

        x=a[k];
        while (j>k & i<k) {
            do i++; while (a[i]<x);
            do j--; while (a[j]>x);

            F_SWAP(a[i],a[j]);
        }
        i++; j--;

        if (j<k) {
            while (a[i]<x) i++;
            l=i; j=m;
        }
        if (k<i) {
            while (x<a[j]) j--;
            m=j; i=l;
        }
    }
    return a[k];
}

In benchmarks that i did here, LefSelect is 20-30% faster than QuickSelect.

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For very small values of k (i.e. when k << n), we can get it done in ~O(n) time. Otherwise, if k is comparable to n, we get it in O(nlogn).

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2  
You aren't providing anything that hasn't been said already. –  Austin Henley Oct 5 '12 at 21:00

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