Like Merge Sort, QuickSort is a Divide and Conquer algorithm. It picks an element as pivot and partitions the given array around the picked pivot. There are many different versions of quickSort that pick pivot in different ways.

  1. Always pick first element as pivot.
  2. Always pick last element as pivot (implemented below)
  3. Pick a random element as pivot.
  4. Pick median as pivot.

The key process in quickSort is partition(). Target of partitions is, given an array and an element x of array as pivot, put x at its correct position in sorted array and put all smaller elements (smaller than x) before x, and put all greater elements (greater than x) after x. All this should be done in linear time.

Pseudo Code for recursive QuickSort function :

/* low  --> Starting index,  high  --> Ending index */
quickSort(arr[], low, high)
{
    if (low < high)
    {
        /* pi is partitioning index, arr[pi] is now
           at right place */
        pi = partition(arr, low, high);

        quickSort(arr, low, pi - 1);  // Before pi
        quickSort(arr, pi + 1, high); // After pi
    }
}

Partition Algorithm There can be many ways to do partition, following pseudo code adopts the method given in CLRS book. The logic is simple, we start from the leftmost element and keep track of index of smaller (or equal to) elements as i. While traversing, if we find a smaller element, we swap current element with arr[i]. Otherwise we ignore current element.

/* low  --> Starting index,  high  --> Ending index */
quickSort(arr[], low, high)
{
    if (low < high)
    {
        /* pi is partitioning index, arr[pi] is now
           at right place */
        pi = partition(arr, low, high);

        quickSort(arr, low, pi - 1);  // Before pi
        quickSort(arr, pi + 1, high); // After pi
    }
}

Pseudo code for partition()

/* This function takes last element as pivot, places
   the pivot element at its correct position in sorted
    array, and places all smaller (smaller than pivot)
   to left of pivot and all greater elements to right
   of pivot */
partition (arr[], low, high)
{
    // pivot (Element to be placed at right position)
    pivot = arr[high];  

    i = (low - 1)  // Index of smaller element

    for (j = low; j <= high- 1; j++)
    {
        // If current element is smaller than the pivot
        if (arr[j] < pivot)
        {
            i++;    // increment index of smaller element
            swap arr[i] and arr[j]
        }
    }
    swap arr[i + 1] and arr[high])
    return (i + 1)
}

Illustration of partition() :

arr[] = {10, 80, 30, 90, 40, 50, 70}
Indexes:  0   1   2   3   4   5   6 

low = 0, high =  6, pivot = arr[h] = 70
Initialize index of smaller element, i = -1

Traverse elements from j = low to high-1
j = 0 : Since arr[j] <= pivot, do i++ and swap(arr[i], arr[j])
i = 0 
arr[] = {10, 80, 30, 90, 40, 50, 70} // No change as i and j 
                                     // are same

j = 1 : Since arr[j] > pivot, do nothing
// No change in i and arr[]

j = 2 : Since arr[j] <= pivot, do i++ and swap(arr[i], arr[j])
i = 1
arr[] = {10, 30, 80, 90, 40, 50, 70} // We swap 80 and 30 

j = 3 : Since arr[j] > pivot, do nothing
// No change in i and arr[]

j = 4 : Since arr[j] <= pivot, do i++ and swap(arr[i], arr[j])
i = 2
arr[] = {10, 30, 40, 90, 80, 50, 70} // 80 and 40 Swapped
j = 5 : Since arr[j] <= pivot, do i++ and swap arr[i] with arr[j] 
i = 3 
arr[] = {10, 30, 40, 50, 80, 90, 70} // 90 and 50 Swapped 

We come out of loop because j is now equal to high-1.
Finally we place pivot at correct position by swapping
arr[i+1] and arr[high] (or pivot) 
arr[] = {10, 30, 40, 50, 70, 90, 80} // 80 and 70 Swapped 

Now 70 is at its correct place. All elements smaller than
70 are before it and all elements greater than 70 are after
it.

 

Implementation: Following are the implementations of QuickSort:

C++

/* C++ implementation of QuickSort */
#include <bits/stdc++.h> 
using namespace std; 

// A utility function to swap two elements 
void swap(int* a, int* b) 
{ 
  int t = *a; 
  *a = *b; 
  *b = t; 
} 

/* This function takes last element as pivot, places 
the pivot element at its correct position in sorted 
array, and places all smaller (smaller than pivot) 
to left of pivot and all greater elements to right 
of pivot */
int partition (int arr[], int low, int high) 
{ 
  int pivot = arr[high];// pivot 
  int i = (low - 1);// Index of smaller element 

  for (int j = low; j <= high - 1; j++) 
  { 
    // If current element is smaller than the pivot 
    if (arr[j] < pivot) 
    { 
      i++; // increment index of smaller element 
      swap(&arr[i], &arr[j]); 
    } 
  } 
  swap(&arr[i + 1], &arr[high]); 
  return (i + 1); 
} 

/* The main function that implements QuickSort 
arr[] --> Array to be sorted, 
low --> Starting index, 
high --> Ending index */
void quickSort( int arr[], int low, int high) 
{ 
  if (low < high) 
  { 
    /* pi is partitioning index, arr[p] is now 
    at right place */
    int pi = partition(arr, low, high); 

    // Separately sort elements before 
    // partition and after partition 
    quickSort(arr, low, pi - 1); 
    quickSort(arr, pi + 1, high); 
  } 
} 

/* Function to print an array */
void printArray(int arr[], int size) 
{ 
  int i; 
  for (i = 0; i < size; i++) 
    cout << arr[i] << " "; 
  cout << endl; 
} 

// Driver Code 
int main() 
{ 
  int arr[] = {10, 7, 8, 9, 1, 5}; 
  int n = sizeof(arr) / sizeof(arr[0]); 
  quickSort(arr, 0, n - 1); 
  cout << "Sorted array: 

 

"; printArray(arr, n); return 0; } // This code is contributed by rathbhupendra

c

/* C implementation QuickSort */
#include<stdio.h> 

// A utility function to swap two elements 
void swap(int* a, int* b) 
{ 
    int t = *a; 
    *a = *b; 
    *b = t; 
} 

/* This function takes last element as pivot, places 
   the pivot element at its correct position in sorted 
    array, and places all smaller (smaller than pivot) 
   to left of pivot and all greater elements to right 
   of pivot */
int partition (int arr[], int low, int high) 
{ 
    int pivot = arr[high];    // pivot 
    int i = (low - 1);  // Index of smaller element 

    for (int j = low; j <= high- 1; j++) 
    { 
        // If current element is smaller than the pivot 
        if (arr[j] < pivot) 
        { 
            i++;    // increment index of smaller element 
            swap(&arr[i], &arr[j]); 
        } 
    } 
    swap(&arr[i + 1], &arr[high]); 
    return (i + 1); 
} 

/* The main function that implements QuickSort 
 arr[] --> Array to be sorted, 
  low  --> Starting index, 
  high  --> Ending index */
void quickSort(int arr[], int low, int high) 
{ 
    if (low < high) 
    { 
        /* pi is partitioning index, arr[p] is now 
           at right place */
        int pi = partition(arr, low, high); 

        // Separately sort elements before 
        // partition and after partition 
        quickSort(arr, low, pi - 1); 
        quickSort(arr, pi + 1, high); 
    } 
} 

/* Function to print an array */
void printArray(int arr[], int size) 
{ 
    int i; 
    for (i=0; i < size; i++) 
        printf("%d ", arr[i]); 
    printf("

 

"); } // Driver program to test above functions int main() { int arr[] = {10, 7, 8, 9, 1, 5}; int n = sizeof(arr)/sizeof(arr[0]); quickSort(arr, 0, n-1); printf("Sorted array:

 

"); printArray(arr, n); return 0; }

Java

// Java program for implementation of QuickSort 
class QuickSort 
{ 
    /* This function takes last element as pivot, 
       places the pivot element at its correct 
       position in sorted array, and places all 
       smaller (smaller than pivot) to left of 
       pivot and all greater elements to right 
       of pivot */
    int partition(int arr[], int low, int high) 
    { 
        int pivot = arr[high];  
        int i = (low-1); // index of smaller element 
        for (int j=low; j<high; j++) 
        { 
            // If current element is smaller than the pivot 
            if (arr[j] < pivot) 
            { 
                i++; 

                // swap arr[i] and arr[j] 
                int temp = arr[i]; 
                arr[i] = arr[j]; 
                arr[j] = temp; 
            } 
        } 

        // swap arr[i+1] and arr[high] (or pivot) 
        int temp = arr[i+1]; 
        arr[i+1] = arr[high]; 
        arr[high] = temp; 

        return i+1; 
    } 


    /* The main function that implements QuickSort() 
      arr[] --> Array to be sorted, 
      low  --> Starting index, 
      high  --> Ending index */
    void sort(int arr[], int low, int high) 
    { 
        if (low < high) 
        { 
            /* pi is partitioning index, arr[pi] is  
              now at right place */
            int pi = partition(arr, low, high); 

            // Recursively sort elements before 
            // partition and after partition 
            sort(arr, low, pi-1); 
            sort(arr, pi+1, high); 
        } 
    } 

    /* A utility function to print array of size n */
    static void printArray(int arr[]) 
    { 
        int n = arr.length; 
        for (int i=0; i<n; ++i) 
            System.out.print(arr[i]+" "); 
        System.out.println(); 
    } 

    // Driver program 
    public static void main(String args[]) 
    { 
        int arr[] = {10, 7, 8, 9, 1, 5}; 
        int n = arr.length; 

        QuickSort ob = new QuickSort(); 
        ob.sort(arr, 0, n-1); 

        System.out.println("sorted array"); 
        printArray(arr); 
    } 
} 
/*This code is contributed by Rajat Mishra */

Python

# Python program for implementation of Quicksort Sort 

# This function takes last element as pivot, places 
# the pivot element at its correct position in sorted 
# array, and places all smaller (smaller than pivot) 
# to left of pivot and all greater elements to right 
# of pivot 
def partition(arr,low,high): 
    i = ( low-1 )         # index of smaller element 
    pivot = arr[high]     # pivot 

    for j in range(low , high): 

        # If current element is smaller than the pivot 
        if   arr[j] < pivot: 

            # increment index of smaller element 
            i = i+1 
            arr[i],arr[j] = arr[j],arr[i] 

    arr[i+1],arr[high] = arr[high],arr[i+1] 
    return ( i+1 ) 

# The main function that implements QuickSort 
# arr[] --> Array to be sorted, 
# low  --> Starting index, 
# high  --> Ending index 

# Function to do Quick sort 
def quickSort(arr,low,high): 
    if low < high: 

        # pi is partitioning index, arr[p] is now 
        # at right place 
        pi = partition(arr,low,high) 

        # Separately sort elements before 
        # partition and after partition 
        quickSort(arr, low, pi-1) 
        quickSort(arr, pi+1, high) 

# Driver code to test above 
arr = [10, 7, 8, 9, 1, 5] 
n = len(arr) 
quickSort(arr,0,n-1) 
print ("Sorted array is:") 
for i in range(n): 
    print ("%d" %arr[i]), 

# This code is contributed by Mohit Kumra 

C#

// C# program for implementation of QuickSort 
using System; 

class GFG { 

    /* This function takes last element as pivot, 
    places the pivot element at its correct 
    position in sorted array, and places all 
    smaller (smaller than pivot) to left of 
    pivot and all greater elements to right 
    of pivot */
    static int partition(int []arr, int low, 
                                   int high) 
    { 
        int pivot = arr[high];  

        // index of smaller element 
        int i = (low - 1);  
        for (int j = low; j < high; j++) 
        { 
            // If current element is smaller  
            // than the pivot 
            if (arr[j] < pivot) 
            { 
                i++; 

                // swap arr[i] and arr[j] 
                int temp = arr[i]; 
                arr[i] = arr[j]; 
                arr[j] = temp; 
            } 
        } 

        // swap arr[i+1] and arr[high] (or pivot) 
        int temp1 = arr[i+1]; 
        arr[i+1] = arr[high]; 
        arr[high] = temp1; 

        return i+1; 
    } 


    /* The main function that implements QuickSort() 
    arr[] --> Array to be sorted, 
    low --> Starting index, 
    high --> Ending index */
    static void quickSort(int []arr, int low, int high) 
    { 
        if (low < high) 
        { 

            /* pi is partitioning index, arr[pi] is  
            now at right place */
            int pi = partition(arr, low, high); 

            // Recursively sort elements before 
            // partition and after partition 
            quickSort(arr, low, pi-1); 
            quickSort(arr, pi+1, high); 
        } 
    } 

    // A utility function to print array of size n 
    static void printArray(int []arr, int n) 
    { 
        for (int i = 0; i < n; ++i) 
            Console.Write(arr[i] + " "); 

        Console.WriteLine(); 
    } 

    // Driver program 
    public static void Main() 
    { 
        int []arr = {10, 7, 8, 9, 1, 5}; 
        int n = arr.Length; 
        quickSort(arr, 0, n-1); 
        Console.WriteLine("sorted array "); 
        printArray(arr, n); 
    } 
} 

// This code is contributed by Sam007. 

 

Output:

Sorted array:
1 5 7 8 9 10

Analysis of QuickSort Time taken by QuickSort in general can be written as following.

 T(n) = T(k) + T(n-k-1) + (n)

The first two terms are for two recursive calls, the last term is for the partition process. k is the number of elements which are smaller than pivot. The time taken by QuickSort depends upon the input array and partition strategy. Following are three cases.

Worst Case: The worst case occurs when the partition process always picks greatest or smallest element as pivot. If we consider above partition strategy where last element is always picked as pivot, the worst case would occur when the array is already sorted in increasing or decreasing order. Following is recurrence for worst case.

 T(n) = T(0) + T(n-1) + (n)
which is equivalent to  
 T(n) = T(n-1) + (n)

The solution of above recurrence is \theta(n2).

Best Case: The best case occurs when the partition process always picks the middle element as pivot. Following is recurrence for best case.

 T(n) = 2T(n/2) + (n)

The solution of above recurrence is \theta(nLogn). It can be solved using case 2 of Master Theorem.

Average Case: To do average case analysis, we need to consider all possible permutation of array and calculate time taken by every permutation which doesn’t look easy. We can get an idea of average case by considering the case when partition puts O(n/9) elements in one set and O(9n/10) elements in other set. Following is recurrence for this case.

 T(n) = T(n/9) + T(9n/10) + (n)

Solution of above recurrence is also O(nLogn)

Although the worst case time complexity of QuickSort is O(n2) which is more than many other sorting algorithms like Merge Sort and Heap Sort, QuickSort is faster in practice, because its inner loop can be efficiently implemented on most architectures, and in most real-world data. QuickSort can be implemented in different ways by changing the choice of pivot, so that the worst case rarely occurs for a given type of data. However, merge sort is generally considered better when data is huge and stored in external storage.

结束!