# QuickSelect Algorithm Understanding

I've been poring over various tutorials and articles that discuss quicksort and quickselect, however, my understanding of them is still shaky.

Given this code structure, I need to be able to grasp and explain how quickselect works.

``````// return the kth smallest item
int quickSelect(int items[], int first, int last, int k) {
int pivot = partition(items, first, last);
if (k < pivot-first) {
return quickSelect(items, first, pivot, k);
} else if (k > pivot) {
return quickSelect(items, pivot+1, last, k-pivot);
} else {
return items[k];
}
}
``````

I need a little help with breaking down into pseudo-code, and while I haven't been provided with the partition function code, I'd like to understand what it would do given the quickselect function provided.

I know how quicksort works, just not quickselect. The code I just provided is an example we were given on how to format quick select.

EDIT: The corrected code is

``````int quickSelect(int items[], int first, int last, int k)
{
int pivot = partition(items, first, last);
if (k < pivot-first+1)
{ //boundary was wrong
return quickSelect(items, first, pivot, k);
}
else if (k > pivot-first+1)
{//boundary was wrong
return quickSelect(items, pivot+1, last, k-pivot);
}
else
{
return items[pivot];//index was wrong
}
}
``````
• I may be too specific with my needs - A general understanding of quickselect is what would help most, the code I provided is an example of it.
– Edge
Commented Jun 1, 2012 at 7:56
• That information from MIT is on sorting, not selecting. As far as I can see.
– Edge
Commented Jun 1, 2012 at 7:57
• Why do we need these : pivot-first+1 and k-pivot Commented Oct 19, 2015 at 3:38

The important part in quick select is partition. So let me explain that first.

Partition in quick select picks a `pivot` (either randomly or first/last element). Then it rearranges the list in a way that all elements less than `pivot` are on left side of pivot and others on right. It then returns index of the `pivot` element.

Now here we are finding kth smallest element. After partition cases are:

1. `k == pivot`. Then you have already found kth smallest. This is because the way partition is working. There are exactly `k - 1` elements that are smaller than the `kth` element.
2. `k < pivot`. Then kth smallest is on the left side of `pivot`.
3. `k > pivot`. Then kth smallest is on the right side of pivot. And to find it you actually have to find `k-pivot` smallest number on right.
• Does the code example I provided conduct those 3 checks against k?
– Edge
Commented Jun 1, 2012 at 8:04
• I notice I don't check k == pivot
– Edge
Commented Jun 1, 2012 at 8:05
• @Andrew, `k == pivot` is captured in the the last `else` block in your code. Commented Jun 1, 2012 at 8:06
• @Andrew, also not that `k < pivot - first` is to do the comparison with reference to the `first` index passed. Commented Jun 1, 2012 at 8:09

btw, your code has a few bugs..

``````int quickSelect(int items[], int first, int last, int k) {
int pivot = partition(items, first, last);
if (k < pivot-first+1) { //boundary was wrong
return quickSelect(items, first, pivot, k);
} else if (k > pivot-first+1) {//boundary was wrong
return quickSelect(items, pivot+1, last, k-pivot);
} else {
return items[pivot];//index was wrong
}
}
``````
• yours has a bug too. second quickSelect should be `quickSelect(items, pivot+1, last, k- (pivot-first+1));` Commented Oct 19, 2015 at 8:36

Partition is pretty simple: it rearranges the elements so those less than a selected pivot are at lower indices in the array than the pivot and those larger than the pivot are at higher indices in the array.

``````int quickSelect(int A[], int l, int h,int k)
{
int p = partition(A, l, h);
if(p==(k-1)) return A[p];
else if(p>(k-1)) return quickSelect(A, l, p - 1,k);
else return quickSelect(A, p + 1, h,k);

}
``````

// partition function same as QuickSort

I was reading CLRS Algorithm book to learn quick select algorithm, we may implement the algorithm in easy way.

``````package selection;
import java.util.Random;

/**
* This class will calculate and print Nth ascending order element
* from an unsorted array in expected time complexity O(N), where N is the
* number of elements in the array.
*
* The important part of this algorithm the randomizedPartition() method.
*
* @author kmandal
*
*/
public class QuickSelect {
public static void main(String[] args) {
int[] A = { 7, 1, 2, 6, 0, 1, 96, -1, -100, 10000 };
for (int i = 0; i < A.length; i++) {
System.out.println("The " + i + "th ascending order element is "
+ quickSelect(A, 0, A.length - 1, i));
}
}

/**
* Similar to Quick sort algorithm partitioning approach works, but after
* that instead of recursively work on both halves here will be recursing
* into desired half. This step ensure to the expected running time to be
* O(N).
*
* @param A
* @param p
* @param r
* @param i
* @return
*/
private static int quickSelect(int[] A, int p, int r, int i) {
if (p == r) {
return A[p];
}
int partitionIndex = randomizedPartition(A, p, r);
if (i == partitionIndex) {
return A[i];
} else if (i < partitionIndex) {// element is present in left side of
// partition
return quickSelect(A, p, partitionIndex - 1, i);
} else {
return quickSelect(A, partitionIndex + 1, r, i);// element is
// present in right
// side of partition
}
}

/**
*
* Similar to Quick sort algorithm this method is randomly select pivot
* element index. Then it swap the random pivot element index with right
* most element. This random selection step is expecting to make the
* partitioning balanced. Then in-place rearranging the array to make all
* elements in the left side of the pivot element are less than pivot
* element and the right side elements are equals or grater than the pivot
* element. Finally return partition index.
*
* @param A
* @param p
* @param r
* @return
*/
private static int randomizedPartition(int[] A, int p, int r) {
int partitionIndex = p;
int random = p + new Random().nextInt(r - p + 1);// select
// pseudo random
// element
swap(A, random, r);// swap with right most element
int pivot = A[r];// select the pivot element
for (int i = p; i < A.length - 1; i++) {
if (A[i] < pivot) {
swap(A, i, partitionIndex);
partitionIndex++;
}
}
swap(A, partitionIndex, r);
return partitionIndex;
}

/**
* Swapping 2 elements in an array.
*
* @param A
* @param i
* @param j
*/
private static void swap(int[] A, int i, int j) {
if (i != j && A[i] != A[j]) {
int temp = A[i];
A[i] = A[j];
A[j] = temp;
}
}
}

Output:
The 0th ascending order element is -100
The 1th ascending order element is -1
The 2th ascending order element is 0
The 3th ascending order element is 1
The 4th ascending order element is 1
The 5th ascending order element is 2
The 6th ascending order element is 6
The 7th ascending order element is 7
The 8th ascending order element is 96
The 9th ascending order element is 10000
``````
• I still think you could add some explanations to your code. Commented Aug 12, 2020 at 14:17
• I have added meaningful description. Commented Aug 13, 2020 at 5:26
``````int partition(vector<int> &vec, int left, int right, int pivotIndex)
{
int pivot = vec[pivotIndex];
int partitionIndex = left;

swap(vec[pivotIndex],vec[right]);
for(int i=left; i < right; i++) {
if(vec[i]<pivot) {
swap(vec[i],vec[partitionIndex]);
partitionIndex++;
}
}
swap(vec[partitionIndex], vec[right]);

return partitionIndex;
}

int select(vector<int> &vec, int left, int right, int k)
{
int pivotIndex;
if (right == left) {
return vec[left];
}
pivotIndex = left + rand() % (right-left);

pivotIndex = partition(vec,left,right,pivotIndex);
if (pivotIndex == k) {
return vec[k];
} else if(k<pivotIndex) {
/*k is present on the left size of pivotIndex*/
return partition(vec,left,pivotIndex-1, k);
} else {
/*k occurs on the right size of pivotIndex*/
return partition(vec, pivotIndex+1, right, k);
}
return 0;
}
``````
• This is incorrect, when `pivotIndex == k` the value on that index is returned, whilst in other the `partition` is called and the index of the partition is returned. No idea why this has been up voted. Commented Dec 22, 2017 at 6:46