Implement a deque Using a circular array:
Deque or Double Ended Queue is a generalized version of the Queue data structure that allows insert and delete at both ends
Operations on Deque:
Mainly the following four basic operations are performed on queue:
- insertFront(): Adds an item at the front of Deque.
- insertRear(): Adds an item at the rear of Deque.
- deleteFront(): Deletes an item from front of Deque.
- deleteRear(): Deletes an item from rear of Deque.
In addition to above operations, following operations are also supported
- getFront(): Gets the front item from queue.
- getRear(): Gets the last item from queue.
- isEmpty(): Checks whether Deque is empty or not.
- isFull(): Checks whether Deque is full or not.
Circular array implementation of Deque:
For implementing deque, we need to keep track of two indices, front, and rear. We enqueue(push) an item at the rear or the front end of the dequeue and dequeue(pop) an item from both the rear and the front end.
Working:
Create an empty array ‘arr’ of size N
initialize front = -1 , rear = 0
Inserting the First element in the deque, at either front or rear will lead to the same result:
Note: After inserting Front Points at 0 and Rear points at 0
Insert Elements at the Rear end of Deque:
a). First we check deque if Full or Not
b). IF Rear == Size-1
then reinitialize Rear = 0 ;
Else increment Rear by ‘1’
and push current key into Arr[ rear ] = key
Front remain same.
Insert Elements at the Front end of Deque:
a). First we check deque if Full or Not
b). IF Front == 0 || initial position, move Front
to points last index of array
front = size – 1
Else decremented front by ‘1’ and push
current key into Arr[ Front] = key
Rear remain same
Delete Element From Rear end of Deque:
First Check deque is Empty or Not
If deque has only one element
front = -1 ; rear =-1;Else IF Rear points to the first index of array
it’s means we have to move rear to points
last index [ now first inserted element at
front end become rear end ]rear = size-1;
Else || decrease rear by ‘1’ rear = rear-1;
Delete Element From the Front end of Deque:
a). first Check deque is Empty or Not
b). If deque has only one element
front = -1 ; rear =-1 ;Else IF front points to the last index of the array
it’s means we have no more elements in array so
we move front to points first index of array
front = 0 ;Else || increment Front by ‘1’
front = front+1;
Below is the implementation of the above methods:
C++
// C++ implementation of De-queue using circular// array#include <iostream>using namespace std;// Maximum size of array or Dequeue#define MAX 100// A structure to represent a Dequeclass Deque { int arr[MAX]; int front; int rear; int size;public: Deque(int size) { front = -1; rear = 0; this->size = size; } // Operations on Deque: void insertfront(int key); void insertrear(int key); void deletefront(); void deleterear(); bool isFull(); bool isEmpty(); int getFront(); int getRear();};// Checks whether Deque is full or not.bool Deque::isFull(){ return ((front == 0 && rear == size - 1) || front == rear + 1);}// Checks whether Deque is empty or not.bool Deque::isEmpty() { return (front == -1); }// Inserts an element at frontvoid Deque::insertfront(int key){ // check whether Deque if full or not if (isFull()) { cout << "Overflow\n" << endl; return; } // If queue is initially empty if (front == -1) { front = 0; rear = 0; } // front is at first position of queue else if (front == 0) front = size - 1; else // decrement front end by '1' front = front - 1; // insert current element into Deque arr[front] = key;}// function to inset element at rear end// of Deque.void Deque ::insertrear(int key){ if (isFull()) { cout << " Overflow\n " << endl; return; } // If queue is initially empty if (front == -1) { front = 0; rear = 0; } // rear is at last position of queue else if (rear == size - 1) rear = 0; // increment rear end by '1' else rear = rear + 1; // insert current element into Deque arr[rear] = key;}// Deletes element at front end of Dequevoid Deque ::deletefront(){ // check whether Deque is empty or not if (isEmpty()) { cout << "Queue Underflow\n" << endl; return; } // Deque has only one element if (front == rear) { front = -1; rear = -1; } else // back to initial position if (front == size - 1) front = 0; else // increment front by '1' to remove current // front value from Deque front = front + 1;}// Delete element at rear end of Dequevoid Deque::deleterear(){ if (isEmpty()) { cout << " Underflow\n" << endl; return; } // Deque has only one element if (front == rear) { front = -1; rear = -1; } else if (rear == 0) rear = size - 1; else rear = rear - 1;}// Returns front element of Dequeint Deque::getFront(){ // check whether Deque is empty or not if (isEmpty()) { cout << " Underflow\n" << endl; return -1; } return arr[front];}// function return rear element of Dequeint Deque::getRear(){ // check whether Deque is empty or not if (isEmpty() || rear < 0) { cout << " Underflow\n" << endl; return -1; } return arr[rear];}// Driver codeint main(){ Deque dq(5); // Function calls cout << "Insert element at rear end : 5 \n"; dq.insertrear(5); cout << "insert element at rear end : 10 \n"; dq.insertrear(10); cout << "get rear element " << " " << dq.getRear() << endl; dq.deleterear(); cout << "After delete rear element new rear" << " become " << dq.getRear() << endl; cout << "inserting element at front end \n"; dq.insertfront(15); cout << "get front element " << " " << dq.getFront() << endl; dq.deletefront(); cout << "After delete front element new " << "front become " << dq.getFront() << endl; return 0;} |
Java
// Java implementation of De-queue using circular// array// A structure to represent a Dequeclass Deque { static final int MAX = 100; int arr[]; int front; int rear; int size; public Deque(int size) { arr = new int[MAX]; front = -1; rear = 0; this.size = size; } /*// Operations on Deque: void insertfront(int key); void insertrear(int key); void deletefront(); void deleterear(); bool isFull(); bool isEmpty(); int getFront(); int getRear();*/ // Checks whether Deque is full or not. boolean isFull() { return ((front == 0 && rear == size - 1) || front == rear + 1); } // Checks whether Deque is empty or not. boolean isEmpty() { return (front == -1); } // Inserts an element at front void insertfront(int key) { // check whether Deque if full or not if (isFull()) { System.out.println("Overflow"); return; } // If queue is initially empty if (front == -1) { front = 0; rear = 0; } // front is at first position of queue else if (front == 0) front = size - 1; else // decrement front end by '1' front = front - 1; // insert current element into Deque arr[front] = key; } // function to inset element at rear end // of Deque. void insertrear(int key) { if (isFull()) { System.out.println(" Overflow "); return; } // If queue is initially empty if (front == -1) { front = 0; rear = 0; } // rear is at last position of queue else if (rear == size - 1) rear = 0; // increment rear end by '1' else rear = rear + 1; // insert current element into Deque arr[rear] = key; } // Deletes element at front end of Deque void deletefront() { // check whether Deque is empty or not if (isEmpty()) { System.out.println("Queue Underflow\n"); return; } // Deque has only one element if (front == rear) { front = -1; rear = -1; } else // back to initial position if (front == size - 1) front = 0; else // increment front by '1' to remove current // front value from Deque front = front + 1; } // Delete element at rear end of Deque void deleterear() { if (isEmpty()) { System.out.println(" Underflow"); return; } // Deque has only one element if (front == rear) { front = -1; rear = -1; } else if (rear == 0) rear = size - 1; else rear = rear - 1; } // Returns front element of Deque int getFront() { // check whether Deque is empty or not if (isEmpty()) { System.out.println(" Underflow"); return -1; } return arr[front]; } // function return rear element of Deque int getRear() { // check whether Deque is empty or not if (isEmpty() || rear < 0) { System.out.println(" Underflow\n"); return -1; } return arr[rear]; } // Driver code public static void main(String[] args) { Deque dq = new Deque(5); // Function calls System.out.println( "Insert element at rear end : 5 "); dq.insertrear(5); System.out.println( "insert element at rear end : 10 "); dq.insertrear(10); System.out.println("get rear element : " + dq.getRear()); dq.deleterear(); System.out.println( "After delete rear element new rear become : " + dq.getRear()); System.out.println( "inserting element at front end"); dq.insertfront(15); System.out.println("get front element: " + dq.getFront()); dq.deletefront(); System.out.println( "After delete front element new front become : " + +dq.getFront()); }} |
Python3
# Python implementation of De-queue using circular# array# A structure to represent a DequeMAX = 100class Deque: def __init__(self, size): self.arr = [0] * MAX self.front = -1 self.rear = 0 self.size = size ''' Operations on Deque: void insertfront(int key); void insertrear(int key); void deletefront(); void deleterear(); bool isFull(); bool isEmpty(); int getFront(); int getRear(); ''' # Checks whether Deque is full or not. def isFull(self): return ((self.front == 0 and self.rear == self.size-1) or self.front == self.rear + 1) # Checks whether Deque is empty or not. def isEmpty(self): return (self.front == -1) # Inserts an element at front def insertfront(self, key): # check whether Deque if full or not if (self.isFull()): print("Overflow") return # If queue is initially empty if (self.front == -1): self.front = 0 self.rear = 0 # front is at first position of queue elif (self.front == 0): self.front = self.size - 1 else: # decrement front end by '1' self.front = self.front-1 # insert current element into Deque self.arr[self.front] = key # function to inset element at rear end # of Deque. def insertrear(self, key): if (self.isFull()): print(" Overflow") return # If queue is initially empty if (self.front == -1): self.front = 0 self.rear = 0 # rear is at last position of queue elif (self.rear == self.size-1): self.rear = 0 # increment rear end by '1' else: self.rear = self.rear+1 # insert current element into Deque self.arr[self.rear] = key # Deletes element at front end of Deque def deletefront(self): # check whether Deque is empty or not if (self.isEmpty()): print("Queue Underflow") return # Deque has only one element if (self.front == self.rear): self.front = -1 self.rear = -1 else: # back to initial position if (self.front == self.size - 1): self.front = 0 else: # increment front by '1' to remove current # front value from Deque self.front = self.front+1 # Delete element at rear end of Deque def deleterear(self): if (self.isEmpty()): print(" Underflow") return # Deque has only one element if (self.front == self.rear): self.front = -1 self.rear = -1 elif (self.rear == 0): self.rear = self.size-1 else: self.rear = self.rear-1 # Returns front element of Deque def getFront(self): # check whether Deque is empty or not if (self.isEmpty()): print(" Underflow") return -1 return self.arr[self.front] # function return rear element of Deque def getRear(self): # check whether Deque is empty or not if(self.isEmpty() or self.rear < 0): print(" Underflow") return -1 return self.arr[self.rear]# Driver codeif __name__ == "__main__": dq = Deque(5) # Function calls print("Insert element at rear end : 5 ") dq.insertrear(5) print("insert element at rear end : 10 ") dq.insertrear(10) print(f"get rear element : {dq.getRear()}") dq.deleterear() print(f"After delete rear element new rear become : {dq.getRear()}") print("inserting element at front end") dq.insertfront(15) print(f"get front element: {dq.getFront()}") dq.deletefront() print(f"After delete front element new front become : {dq.getFront()}")# This code is contributed by _saurabh_jaiswal |
C#
// C# implementation of De-queue using circular// arrayusing System;// A structure to represent a Dequepublic class Deque { static readonly int MAX = 100; int[] arr; int front; int rear; int size; public Deque(int size) { arr = new int[MAX]; front = -1; rear = 0; this.size = size; } /*// Operations on Deque: void insertfront(int key); void insertrear(int key); void deletefront(); void deleterear(); bool isFull(); bool .Count!=0; int getFront(); int getRear();*/ // Checks whether Deque is full or not. bool isFull() { return ((front == 0 && rear == size - 1) || front == rear + 1); } // Checks whether Deque is empty or not. bool isEmpty() { return (front == -1); } // Inserts an element at front void insertfront(int key) { // check whether Deque if full or not if (isFull()) { Console.WriteLine("Overflow"); return; } // If queue is initially empty if (front == -1) { front = 0; rear = 0; } // front is at first position of queue else if (front == 0) front = size - 1; else // decrement front end by '1' front = front - 1; // insert current element into Deque arr[front] = key; } // function to inset element at rear end // of Deque. void insertrear(int key) { if (isFull()) { Console.WriteLine(" Overflow "); return; } // If queue is initially empty if (front == -1) { front = 0; rear = 0; } // rear is at last position of queue else if (rear == size - 1) rear = 0; // increment rear end by '1' else rear = rear + 1; // insert current element into Deque arr[rear] = key; } // Deletes element at front end of Deque void deletefront() { // check whether Deque is empty or not if (isEmpty()) { Console.WriteLine("Queue Underflow\n"); return; } // Deque has only one element if (front == rear) { front = -1; rear = -1; } else // back to initial position if (front == size - 1) front = 0; else // increment front by '1' to remove current // front value from Deque front = front + 1; } // Delete element at rear end of Deque void deleterear() { if (isEmpty()) { Console.WriteLine(" Underflow"); return; } // Deque has only one element if (front == rear) { front = -1; rear = -1; } else if (rear == 0) rear = size - 1; else rear = rear - 1; } // Returns front element of Deque int getFront() { // check whether Deque is empty or not if (isEmpty()) { Console.WriteLine(" Underflow"); return -1; } return arr[front]; } // function return rear element of Deque int getRear() { // check whether Deque is empty or not if (isEmpty() || rear < 0) { Console.WriteLine(" Underflow\n"); return -1; } return arr[rear]; } // Driver code public static void Main(String[] args) { Deque dq = new Deque(5); // Function calls Console.WriteLine( "Insert element at rear end : 5 "); dq.insertrear(5); Console.WriteLine( "insert element at rear end : 10 "); dq.insertrear(10); Console.WriteLine("get rear element : " + dq.getRear()); dq.deleterear(); Console.WriteLine( "After delete rear element new rear become : " + dq.getRear()); Console.WriteLine("inserting element at front end"); dq.insertfront(15); Console.WriteLine("get front element: " + dq.getFront()); dq.deletefront(); Console.WriteLine( "After delete front element new front become : " + +dq.getFront()); }}// This code is contributed by aashish1995 |
Javascript
<script>// Javascript implementation of De-queue using circular// array // A structure to represent a Dequelet MAX = 100;class Deque{ constructor(size) { this.arr = new Array(MAX); this.front = -1; this.rear = 0; this.size = size; } /*// Operations on Deque: void insertfront(int key); void insertrear(int key); void deletefront(); void deleterear(); bool isFull(); bool isEmpty(); int getFront(); int getRear();*/ // Checks whether Deque is full or not. isFull() { return ((this.front == 0 && this.rear == this.size-1)|| this.front == this.rear+1); } // Checks whether Deque is empty or not. isEmpty () { return (this.front == -1); } // Inserts an element at front insertfront(key) { // check whether Deque if full or not if (this.isFull()) { document.write("Overflow<br>"); return; } // If queue is initially empty if (this.front == -1) { this.front = 0; this.rear = 0; } // front is at first position of queue else if (this.front == 0) this.front = this.size - 1 ; else // decrement front end by '1' this.front = this.front-1; // insert current element into Deque this.arr[this.front] = key ; } // function to inset element at rear end // of Deque. insertrear(key) { if (this.isFull()) { document.write(" Overflow <br>"); return; } // If queue is initially empty if (this.front == -1) { this.front = 0; this.rear = 0; } // rear is at last position of queue else if (this.rear == this.size-1) this.rear = 0; // increment rear end by '1' else this.rear = this.rear+1; // insert current element into Deque this.arr[this.rear] = key ; } // Deletes element at front end of Deque deletefront() { // check whether Deque is empty or not if (this.isEmpty()) { document.write("Queue Underflow<br>"); return ; } // Deque has only one element if (this.front == this.rear) { this.front = -1; this.rear = -1; } else // back to initial position if (this.front == this.size -1) this.front = 0; else // increment front by '1' to remove current // front value from Deque this.front = this.front+1; } // Delete element at rear end of Deque deleterear() { if (this.isEmpty()) { document.write(" Underflow<br>"); return ; } // Deque has only one element if (this.front == this.rear) { this.front = -1; this.rear = -1; } else if (this.rear == 0) this.rear = this.size-1; else this.rear = this.rear-1; } // Returns front element of Deque getFront() { // check whether Deque is empty or not if (this.isEmpty()) { document.write(" Underflow<br>"); return -1 ; } return this.arr[this.front]; } // function return rear element of Deque getRear() { // check whether Deque is empty or not if(this.isEmpty() || this.rear < 0) { document.write(" Underflow<br>"); return -1 ; } return this.arr[this.rear]; } }// Driver program to test above functionlet dq = new Deque(5); document.write("Insert element at rear end : 5 <br>");dq.insertrear(5);document.write("insert element at rear end : 10 <br>");dq.insertrear(10);document.write("get rear element : "+ dq.getRear()+"<br>");dq.deleterear();document.write("After delete rear element new rear become : " + dq.getRear()+"<br>");document.write("inserting element at front end<br>");dq.insertfront(15);document.write("get front element: " +dq.getFront()+"<br>");dq.deletefront();document.write("After delete front element new front become : " + + dq.getFront()+"<br>");// This code is contributed by avanitrachhadiya2155</script> |
Output
Insert element at rear end : 5 insert element at rear end : 10 get rear element 10 After delete rear element new rear become 5 inserting element at front end get front element 15 After delete front element new front become 5
Time Complexity: O(N)
Auxiliary Space: O(N)
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