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Binary Heap

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A Binary Heap is a complete binary tree that stores data efficiently, allowing quick access to the maximum or minimum element, depending on the type of heap. It can either be a Min Heap or a Max Heap. In a Min Heap, the key at the root must be the smallest among all the keys in the heap, and this property must hold true recursively for all nodes. Similarly, a Max Heap follows the same principle, but with the largest key at the root.

Valid and Invalid examples of heaps

How is Binary Heap represented? 

A Binary Heap is a Complete Binary Tree. A binary heap is typically represented as an array.

  • The root element will be at arr[0].
  • The below table shows indices of other nodes for the ith node, i.e., arr[i]:
arr[(i-1)/2]Returns the parent node
arr[(2*i)+1]Returns the left child node
arr[(2*i)+2]Returns the right child node

The traversal method use to achieve Array representation is Level Order Traversal. Please refer to Array Representation Of Binary Heap for details.

Representation-of-a-Binary-Heap
Representation of Binary Heap

Operations on Heap


Refer Introduction to Min-Heap – Data Structure and Algorithm Tutorials for more

C++ 
// A C++ program to demonstrate common Binary Heap Operations
#include<iostream>
#include<climits>
using namespace std;

// Prototype of a utility function to swap two integers
void swap(int *x, int *y);

// A class for Min Heap
class MinHeap
{
    int *harr; // pointer to array of elements in heap
    int capacity; // maximum possible size of min heap
    int heap_size; // Current number of elements in min heap
public:
    // Constructor
    MinHeap(int capacity);

    // to heapify a subtree with the root at given index
    void MinHeapify(int i);

    int parent(int i) { return (i-1)/2; }

    // to get index of left child of node at index i
    int left(int i) { return (2*i + 1); }

    // to get index of right child of node at index i
    int right(int i) { return (2*i + 2); }

    // to extract the root which is the minimum element
    int extractMin();

    // Decreases key value of key at index i to new_val
    void decreaseKey(int i, int new_val);

    // Returns the minimum key (key at root) from min heap
    int getMin() { return harr[0]; }

    // Deletes a key stored at index i
    void deleteKey(int i);

    // Inserts a new key 'k'
    void insertKey(int k);
};

// Constructor: Builds a heap from a given array a[] of given size
MinHeap::MinHeap(int cap)
{
    heap_size = 0;
    capacity = cap;
    harr = new int[cap];
}

// Inserts a new key 'k'
void MinHeap::insertKey(int k)
{
    if (heap_size == capacity)
    {
        cout << "\nOverflow: Could not insertKey\n";
        return;
    }

    // First insert the new key at the end
    heap_size++;
    int i = heap_size - 1;
    harr[i] = k;

    // Fix the min heap property if it is violated
    while (i != 0 && harr[parent(i)] > harr[i])
    {
       swap(&harr[i], &harr[parent(i)]);
       i = parent(i);
    }
}

// Decreases value of key at index 'i' to new_val.  It is assumed that
// new_val is smaller than harr[i].
void MinHeap::decreaseKey(int i, int new_val)
{
    harr[i] = new_val;
    while (i != 0 && harr[parent(i)] > harr[i])
    {
       swap(&harr[i], &harr[parent(i)]);
       i = parent(i);
    }
}

// Method to remove minimum element (or root) from min heap
int MinHeap::extractMin()
{
    if (heap_size <= 0)
        return INT_MAX;
    if (heap_size == 1)
    {
        heap_size--;
        return harr[0];
    }

    // Store the minimum value, and remove it from heap
    int root = harr[0];
    harr[0] = harr[heap_size-1];
    heap_size--;
    MinHeapify(0);

    return root;
}


// This function deletes key at index i. It first reduced value to minus
// infinite, then calls extractMin()
void MinHeap::deleteKey(int i)
{
    decreaseKey(i, INT_MIN);
    extractMin();
}

// A recursive method to heapify a subtree with the root at given index
// This method assumes that the subtrees are already heapified
void MinHeap::MinHeapify(int i)
{
    int l = left(i);
    int r = right(i);
    int smallest = i;
    if (l < heap_size && harr[l] < harr[i])
        smallest = l;
    if (r < heap_size && harr[r] < harr[smallest])
        smallest = r;
    if (smallest != i)
    {
        swap(&harr[i], &harr[smallest]);
        MinHeapify(smallest);
    }
}

// A utility function to swap two elements
void swap(int *x, int *y)
{
    int temp = *x;
    *x = *y;
    *y = temp;
}

// Driver program to test above functions
int main()
{
    MinHeap h(11);
    h.insertKey(3);
    h.insertKey(2);
    h.deleteKey(1);
    h.insertKey(15);
    h.insertKey(5);
    h.insertKey(4);
    h.insertKey(45);
    cout << h.extractMin() << " ";
    cout << h.getMin() << " ";
    h.decreaseKey(2, 1);
    cout << h.getMin();
    return 0;
}
Java 
// Java program for the above approach
import java.util.*;

// A class for Min Heap 
class MinHeap {
    
    // To store array of elements in heap
    private int[] heapArray;
    
    // max size of the heap
    private int capacity;
    
    // Current number of elements in the heap
    private int current_heap_size;

    // Constructor 
    public MinHeap(int n) {
        capacity = n;
        heapArray = new int[capacity];
        current_heap_size = 0;
    }
    
    // Swapping using reference 
    private void swap(int[] arr, int a, int b) {
        int temp = arr[a];
        arr[a] = arr[b];
        arr[b] = temp;
    }
    
    
    // Get the Parent index for the given index
    private int parent(int key) {
        return (key - 1) / 2;
    }
    
    // Get the Left Child index for the given index
    private int left(int key) {
        return 2 * key + 1;
    }
    
    // Get the Right Child index for the given index
    private int right(int key) {
        return 2 * key + 2;
    }
    
    
    // Inserts a new key
    public boolean insertKey(int key) {
        if (current_heap_size == capacity) {
            
            // heap is full
            return false;
        }
    
        // First insert the new key at the end 
        int i = current_heap_size;
        heapArray[i] = key;
        current_heap_size++;
        
        // Fix the min heap property if it is violated 
        while (i != 0 && heapArray[i] < heapArray[parent(i)]) {
            swap(heapArray, i, parent(i));
            i = parent(i);
        }
        return true;
    }
    
    // Decreases value of given key to new_val. 
    // It is assumed that new_val is smaller 
    // than heapArray[key]. 
    public void decreaseKey(int key, int new_val) {
        heapArray[key] = new_val;

        while (key != 0 && heapArray[key] < heapArray[parent(key)]) {
            swap(heapArray, key, parent(key));
            key = parent(key);
        }
    }
    
    // Returns the minimum key (key at
    // root) from min heap 
    public int getMin() {
        return heapArray[0];
    }
    
    
    // Method to remove minimum element 
    // (or root) from min heap 
    public int extractMin() {
        if (current_heap_size <= 0) {
            return Integer.MAX_VALUE;
        }

        if (current_heap_size == 1) {
            current_heap_size--;
            return heapArray[0];
        }
        
        // Store the minimum value, 
        // and remove it from heap 
        int root = heapArray[0];

        heapArray[0] = heapArray[current_heap_size - 1];
        current_heap_size--;
        MinHeapify(0);

        return root;
    }
        
    // This function deletes key at the 
    // given index. It first reduced value 
    // to minus infinite, then calls extractMin()
    public void deleteKey(int key) {
        decreaseKey(key, Integer.MIN_VALUE);
        extractMin();
    }
    
    // A recursive method to heapify a subtree 
    // with the root at given index 
    // This method assumes that the subtrees
    // are already heapified
    private void MinHeapify(int key) {
        int l = left(key);
        int r = right(key);

        int smallest = key;
        if (l < current_heap_size && heapArray[l] < heapArray[smallest]) {
            smallest = l;
        }
        if (r < current_heap_size && heapArray[r] < heapArray[smallest]) {
            smallest = r;
        }

        if (smallest != key) {
            swap(heapArray, key, smallest);
            MinHeapify(smallest);
        }
    }
    
    // Increases value of given key to new_val.
    // It is assumed that new_val is greater 
    // than heapArray[key]. 
    // Heapify from the given key
    public void increaseKey(int key, int new_val) {
        heapArray[key] = new_val;
        MinHeapify(key);
    }
    
    // Changes value on a key
    public void changeValueOnAKey(int key, int new_val) {
        if (heapArray[key] == new_val) {
            return;
        }
        if (heapArray[key] < new_val) {
            increaseKey(key, new_val);
        } else {
            decreaseKey(key, new_val);
        }
    }
}

// Driver Code
class MinHeapTest {
    public static void main(String[] args) {
        MinHeap h = new MinHeap(11);
        h.insertKey(3);
        h.insertKey(2);
        h.deleteKey(1);
        h.insertKey(15);
        h.insertKey(5);
        h.insertKey(4);
        h.insertKey(45);
        System.out.print(h.extractMin() + " ");
        System.out.print(h.getMin() + " ");
        
        h.decreaseKey(2, 1);
        System.out.print(h.getMin());
    }
}

// This code is contributed by rishabmalhdijo
Python 
# A Python program to demonstrate common binary heap operations

# Import the heap functions from python library
from heapq import heappush, heappop, heapify 

# heappop - pop and return the smallest element from heap
# heappush - push the value item onto the heap, maintaining
#             heap invarient
# heapify - transform list into heap, in place, in linear time

# A class for Min Heap
class MinHeap:
    
    # Constructor to initialize a heap
    def __init__(self):
        self.heap = [] 

    def parent(self, i):
        return (i-1)/2
    
    # Inserts a new key 'k'
    def insertKey(self, k):
        heappush(self.heap, k)           

    # Decrease value of key at index 'i' to new_val
    # It is assumed that new_val is smaller than heap[i]
    def decreaseKey(self, i, new_val):
        self.heap[i]  = new_val 
        while(i != 0 and self.heap[self.parent(i)] > self.heap[i]):
            # Swap heap[i] with heap[parent(i)]
            self.heap[i] , self.heap[self.parent(i)] = (
            self.heap[self.parent(i)], self.heap[i])
            
    # Method to remove minimum element from min heap
    def extractMin(self):
        return heappop(self.heap)

    # This function deletes key at index i. It first reduces
    # value to minus infinite and then calls extractMin()
    def deleteKey(self, i):
        self.decreaseKey(i, float("-inf"))
        self.extractMin()

    # Get the minimum element from the heap
    def getMin(self):
        return self.heap[0]

# Driver pgoratm to test above function
heapObj = MinHeap()
heapObj.insertKey(3)
heapObj.insertKey(2)
heapObj.deleteKey(1)
heapObj.insertKey(15)
heapObj.insertKey(5)
heapObj.insertKey(4)
heapObj.insertKey(45)

print heapObj.extractMin(),
print heapObj.getMin(),
heapObj.decreaseKey(2, 1)
print heapObj.getMin()

# This code is contributed by Nikhil Kumar Singh(nickzuck_007)
C# 
// C# program to demonstrate common 
// Binary Heap Operations - Min Heap
using System;

// A class for Min Heap 
class MinHeap{
    
// To store array of elements in heap
public int[] heapArray{ get; set; }

// max size of the heap
public int capacity{ get; set; }

// Current number of elements in the heap
public int current_heap_size{ get; set; }

// Constructor 
public MinHeap(int n)
{
    capacity = n;
    heapArray = new int[capacity];
    current_heap_size = 0;
}

// Swapping using reference 
public static void Swap<T>(ref T lhs, ref T rhs)
{
    T temp = lhs;
    lhs = rhs;
    rhs = temp;
}

// Get the Parent index for the given index
public int Parent(int key) 
{
    return (key - 1) / 2;
}

// Get the Left Child index for the given index
public int Left(int key)
{
    return 2 * key + 1;
}

// Get the Right Child index for the given index
public int Right(int key)
{
    return 2 * key + 2;
}

// Inserts a new key
public bool insertKey(int key)
{
    if (current_heap_size == capacity)
    {
        
        // heap is full
        return false;
    }

    // First insert the new key at the end 
    int i = current_heap_size;
    heapArray[i] = key;
    current_heap_size++;

    // Fix the min heap property if it is violated 
    while (i != 0 && heapArray[i] < 
                     heapArray[Parent(i)])
    {
        Swap(ref heapArray[i],
             ref heapArray[Parent(i)]);
        i = Parent(i);
    }
    return true;
}

// Decreases value of given key to new_val. 
// It is assumed that new_val is smaller 
// than heapArray[key]. 
public void decreaseKey(int key, int new_val)
{
    heapArray[key] = new_val;

    while (key != 0 && heapArray[key] < 
                       heapArray[Parent(key)])
    {
        Swap(ref heapArray[key], 
             ref heapArray[Parent(key)]);
        key = Parent(key);
    }
}

// Returns the minimum key (key at
// root) from min heap 
public int getMin()
{
    return heapArray[0];
}

// Method to remove minimum element 
// (or root) from min heap 
public int extractMin()
{
    if (current_heap_size <= 0)
    {
        return int.MaxValue;
    }

    if (current_heap_size == 1)
    {
        current_heap_size--;
        return heapArray[0];
    }

    // Store the minimum value, 
    // and remove it from heap 
    int root = heapArray[0];

    heapArray[0] = heapArray[current_heap_size - 1];
    current_heap_size--;
    MinHeapify(0);

    return root;
}

// This function deletes key at the 
// given index. It first reduced value 
// to minus infinite, then calls extractMin()
public void deleteKey(int key)
{
    decreaseKey(key, int.MinValue);
    extractMin();
}

// A recursive method to heapify a subtree 
// with the root at given index 
// This method assumes that the subtrees
// are already heapified
public void MinHeapify(int key)
{
    int l = Left(key);
    int r = Right(key);

    int smallest = key;
    if (l < current_heap_size && 
        heapArray[l] < heapArray[smallest])
    {
        smallest = l;
    }
    if (r < current_heap_size && 
        heapArray[r] < heapArray[smallest])
    {
        smallest = r;
    }
    
    if (smallest != key)
    {
        Swap(ref heapArray[key], 
             ref heapArray[smallest]);
        MinHeapify(smallest);
    }
}

// Increases value of given key to new_val.
// It is assumed that new_val is greater 
// than heapArray[key]. 
// Heapify from the given key
public void increaseKey(int key, int new_val)
{
    heapArray[key] = new_val;
    MinHeapify(key);
}

// Changes value on a key
public void changeValueOnAKey(int key, int new_val)
{
    if (heapArray[key] == new_val)
    {
        return;
    }
    if (heapArray[key] < new_val)
    {
        increaseKey(key, new_val);
    } else
    {
        decreaseKey(key, new_val);
    }
}
}

static class MinHeapTest{
    
// Driver code
public static void Main(string[] args)
{
    MinHeap h = new MinHeap(11);
    h.insertKey(3);
    h.insertKey(2);
    h.deleteKey(1);
    h.insertKey(15);
    h.insertKey(5);
    h.insertKey(4);
    h.insertKey(45);
    
    Console.Write(h.extractMin() + " ");
    Console.Write(h.getMin() + " ");
    
    h.decreaseKey(2, 1);
    Console.Write(h.getMin());
}
}

// This code is contributed by 
// Dinesh Clinton Albert(dineshclinton)
JavaScript 
// A class for Min Heap
class MinHeap
{
    // Constructor: Builds a heap from a given array a[] of given size
    constructor()
    {
        this.arr = [];
    }

    left(i) {
        return 2*i + 1;
    }

    right(i) {
        return 2*i + 2;
    }

    parent(i){
        return Math.floor((i - 1)/2)
    }
    
    getMin()
    {
        return this.arr[0]
    }
    
    insert(k)
    {
        let arr = this.arr;
        arr.push(k);
    
        // Fix the min heap property if it is violated
        let i = arr.length - 1;
        while (i > 0 && arr[this.parent(i)] > arr[i])
        {
            let p = this.parent(i);
            [arr[i], arr[p]] = [arr[p], arr[i]];
            i = p;
        }
    }

    // Decreases value of key at index 'i' to new_val. 
    // It is assumed that new_val is smaller than arr[i].
    decreaseKey(i, new_val)
    {
        let arr = this.arr;
        arr[i] = new_val;
        
        while (i !== 0 && arr[this.parent(i)] > arr[i])
        {
           let p = this.parent(i);
           [arr[i], arr[p]] = [arr[p], arr[i]];
           i = p;
        }
    }

    // Method to remove minimum element (or root) from min heap
    extractMin()
    {
        let arr = this.arr;
        if (arr.length == 1) {
            return arr.pop();
        }
        
        // Store the minimum value, and remove it from heap
        let res = arr[0];
        arr[0] = arr[arr.length-1];
        arr.pop();
        this.MinHeapify(0);
        return res;
    }


    // This function deletes key at index i. It first reduced value to minus
    // infinite, then calls extractMin()
    deleteKey(i)
    {
        this.decreaseKey(i, this.arr[0] - 1);
        this.extractMin();
    }

    // A recursive method to heapify a subtree with the root at given index
    // This method assumes that the subtrees are already heapified
    MinHeapify(i)
    {
        let arr = this.arr;
        let n = arr.length;
        if (n === 1) {
            return;
        }
        let l = this.left(i);
        let r = this.right(i);
        let smallest = i;
        if (l < n && arr[l] < arr[i])
            smallest = l;
        if (r < n && arr[r] < arr[smallest])
            smallest = r;
        if (smallest !== i)
        {
            [arr[i], arr[smallest]] = [arr[smallest], arr[i]]
            this.MinHeapify(smallest);
        }
    }
}

let h = new MinHeap();
    h.insert(3); 
    h.insert(2);
    h.deleteKey(1);
    h.insert(15);
    h.insert(5);
    h.insert(4);
    h.insert(45);
    
    console.log(h.extractMin() + " ");
    console.log(h.getMin() + " ");
    
    h.decreaseKey(2, 1); 
    console.log(h.extractMin());

Output
2 4 1

Applications of Heaps

Related Links:


Binary Heap Operations | DSA Problem
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Analysis of Algorithms

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