A skew heap (or self – adjusting heap) is a heap data structure implemented as a binary tree. Skew heaps are advantageous because of their ability to merge more quickly than binary heaps. In contrast with binary heaps, there are no structural constraints, so there is no guarantee that the height of the tree is logarithmic. Only two conditions must be satisfied :
- The general heap order must be there (root is minimum and same is recursively true for subtrees), but balanced property (all levels must be full except the last) is not required.
- Main operation in Skew Heaps is Merge. We can implement other operations like insert, extractMin(), etc using Merge only.
Example :
1. Consider the skew heap 1 to be
2. The second heap to be considered
4. And we obtain the final merged tree as
Recursive Merge Process :
merge(h1, h2)
- Let h1 and h2 be the two min skew heaps to be merged. Let h1’s root be smaller than h2’s root (If not smaller, we can swap to get the same).
- We swap h1->left and h1->right.
- h1->left = merge(h2, h1->left)
Examples :
Let h1 be 10 / \ 20 30 / / 40 50 Let h2 be 15 / \ 25 35 / \ 45 55 After swapping h1->left and h1->right, we get 10 / \ 30 20 / / 50 40 Now we recursively Merge 30 / AND 50 15 / \ 25 35 / \ 45 55 After recursive merge, we get (Please do it using pen and paper). 15 / \ 30 25 / \ / \ 35 50 45 55 We make this merged tree as left of original h1 and we get following result. 10 / \ 15 20 / \ / 30 25 40 / \ / \ 35 40 45 55
For visualization : https://www.cs.usfca.edu/~galles/JavascriptVisual/LeftistHeap.html
Implementation:
// CPP program to implement Skew Heap // operations. #include <bits/stdc++.h> using namespace std;
struct SkewHeap
{ int key;
SkewHeap* right;
SkewHeap* left;
// constructor to make a new
// node of heap
SkewHeap()
{
key = 0;
right = NULL;
left = NULL;
}
// the special merge function that's
// used in most of the other operations
// also
SkewHeap* merge(SkewHeap* h1, SkewHeap* h2)
{
// If one of the heaps is empty
if (h1 == NULL)
return h2;
if (h2 == NULL)
return h1;
// Make sure that h1 has smaller
// key.
if (h1->key > h2->key)
swap(h1, h2);
// Swap h1->left and h1->right
swap(h1->left, h1->right);
// Merge h2 and h1->left and make
// merged tree as left of h1.
h1->left = merge(h2, h1->left);
return h1;
}
// function to construct heap using
// values in the array
SkewHeap* construct(SkewHeap* root,
int heap[], int n)
{
SkewHeap* temp;
for ( int i = 0; i < n; i++) {
temp = new SkewHeap;
temp->key = heap[i];
root = merge(root, temp);
}
return root;
}
// function to print the Skew Heap,
// as it is in form of a tree so we use
// tree traversal algorithms
void inorder(SkewHeap* root)
{
if (root == NULL)
return ;
else {
inorder(root->left);
cout << root->key << " " ;
inorder(root->right);
}
return ;
}
}; // Driver Code int main()
{ // Construct two heaps
SkewHeap heap, *temp1 = NULL,
*temp2 = NULL;
/*
5
/ \
/ \
10 12 */
int heap1[] = { 12, 5, 10 };
/*
3
/ \
/ \
7 8
/
/
14 */
int heap2[] = { 3, 7, 8, 14 };
int n1 = sizeof (heap1) / sizeof (heap1[0]);
int n2 = sizeof (heap2) / sizeof (heap2[0]);
temp1 = heap.construct(temp1, heap1, n1);
temp2 = heap.construct(temp2, heap2, n2);
// Merge two heaps
temp1 = heap.merge(temp1, temp2);
/*
3
/ \
/ \
5 7
/ \ /
8 10 14
/
12 */
cout << "Merged Heap is: " << endl;
heap.inorder(temp1);
} |
// Java program to implement Skew Heap operations. import java.util.*;
class SkewHeap {
int key;
SkewHeap right;
SkewHeap left;
// constructor to make a new
// node of heap
SkewHeap()
{
key = 0 ;
right = null ;
left = null ;
}
// the special merge function that's
// used in most of the other operations
// also
SkewHeap merge(SkewHeap h1, SkewHeap h2)
{
// If one of the heaps is empty
if (h1 == null )
return h2;
if (h2 == null )
return h1;
// Make sure that h1 has smaller
// key.
if (h1.key > h2.key) {
SkewHeap temp = h1;
h1 = h2;
h2 = temp;
}
// Swap h1.left and h1.right
SkewHeap temp = h1.left;
h1.left = h1.right;
h1.right = temp;
// Merge h2 and h1.left and make
// merged tree as left of h1.
h1.left = merge(h2, h1.left);
return h1;
}
// function to construct heap using
// values in the array
SkewHeap construct(SkewHeap root, int [] heap, int n)
{
SkewHeap temp;
for ( int i = 0 ; i < n; i++) {
temp = new SkewHeap();
temp.key = heap[i];
root = merge(root, temp);
}
return root;
}
// function to print the Skew Heap,
// as it is in form of a tree so we use
// tree traversal algorithms
void inorder(SkewHeap root)
{
if (root == null )
return ;
else {
inorder(root.left);
System.out.print(root.key + " " );
inorder(root.right);
}
return ;
}
} // Driver Code public class Main {
public static void main(String[] args)
{
// Construct two heaps
SkewHeap heap = new SkewHeap(), temp1 = null ,
temp2 = null ;
/*
5
/
/
10 12 /
/
3
/
/
7 8
/
/
14 */
int [] heap1 = { 12 , 5 , 10 };
int [] heap2 = { 3 , 7 , 8 , 14 };
int n1 = heap1.length;
int n2 = heap2.length;
temp1 = heap.construct(temp1, heap1, n1);
temp2 = heap.construct(temp2, heap2, n2);
// Merge two heaps
temp1 = heap.merge(temp1, temp2);
/*
3
/ \
/ \
5 7
/ \ /
8 10 14
/
12 */
System.out.println( "Merged Heap is: " );
heap.inorder(temp1);
}
} |
# Python code implementation class SkewHeap:
def __init__( self ):
self .key = 0
self .right = None
self .left = None
# the special merge function that's used
# in most of the other operations also
def merge( self , h1, h2):
# If one of the heaps is empty
if h1 is None :
return h2
if h2 is None :
return h1
# Make sure that h1 has smaller key.
if h1.key > h2.key:
h1, h2 = h2, h1
# Swap h1.left and h1.right
h1.left, h1.right = h1.right, h1.left
# Merge h2 and h1.left and make
# merged tree as left of h1.
h1.left = self .merge(h2, h1.left)
return h1
# function to construct heap using values in the array
def construct( self , root, heap, n):
for i in range (n):
temp = SkewHeap()
temp.key = heap[i]
root = self .merge(root, temp)
return root
# function to print the Skew Heap, as it is
# in form of a tree so we use
# tree traversal algorithms
def inorder( self , root):
if root is None :
return
else :
self .inorder(root.left)
print (root.key, end = " " )
self .inorder(root.right)
# Driver Code if __name__ = = "__main__" :
# Construct two heaps
heap, temp1, temp2 = SkewHeap(), None , None
heap1 = [ 12 , 5 , 10 ]
heap2 = [ 3 , 7 , 8 , 14 ]
n1 = len (heap1)
n2 = len (heap2)
temp1 = heap.construct(temp1, heap1, n1)
temp2 = heap.construct(temp2, heap2, n2)
# Merge two heaps
temp1 = heap.merge(temp1, temp2)
print ( "The heap obtained after merging is:" )
heap.inorder(temp1)
# This code is contributed by karthik. |
using System;
class SkewHeap {
int key;
SkewHeap right;
SkewHeap left;
// constructor to make a new
// node of heap
public SkewHeap()
{
key = 0;
right = null ;
left = null ;
}
// the special merge function that's
// used in most of the other operations
// also
public SkewHeap merge(SkewHeap h1, SkewHeap h2)
{
// If one of the heaps is empty
if (h1 == null )
return h2;
if (h2 == null )
return h1;
// Make sure that h1 has smaller
// key.
if (h1.key > h2.key) {
SkewHeap temp = h1;
h1 = h2;
h2 = temp;
}
// Swap h1.left and h1.right
SkewHeap temp2 = h1.left;
h1.left = h1.right;
h1.right = temp2;
// Merge h2 and h1.left and make
// merged tree as left of h1.
h1.left = merge(h2, h1.left);
return h1;
}
// function to construct heap using
// values in the array
public SkewHeap construct(SkewHeap root, int [] heap,
int n)
{
SkewHeap temp;
for ( int i = 0; i < n; i++) {
temp = new SkewHeap();
temp.key = heap[i];
root = merge(root, temp);
}
return root;
}
// function to print the Skew Heap,
// as it is in form of a tree so we use
// tree traversal algorithms
public void inorder(SkewHeap root)
{
if (root == null )
return ;
else {
inorder(root.left);
Console.Write(root.key + " " );
inorder(root.right);
}
return ;
}
} // Driver Code class Program {
static void Main( string [] args)
{
// Construct two heaps
SkewHeap heap = new SkewHeap(), temp1 = null ,
temp2 = null ;
/*
5
/
/
10 12 /
/
3
/
/
7 8
/
/
14 */
int [] heap1 = { 12, 5, 10 };
int [] heap2 = { 3, 7, 8, 14 };
int n1 = heap1.Length;
int n2 = heap2.Length;
temp1 = heap.construct(temp1, heap1, n1);
temp2 = heap.construct(temp2, heap2, n2);
// Merge two heaps
temp1 = heap.merge(temp1, temp2);
/*
3
/ \
/ \
5 7
/ \ /
8 10 14
/
12 */
Console.WriteLine( "Merged Heap is: " );
heap.inorder(temp1);
}
} |
// JavaScript code implementation class SkewHeap { constructor() {
this .key = 0;
this .right = null ;
this .left = null ;
}
// the special merge function that's
// used in most of the other operations
// also
merge(h1, h2) {
// If one of the heaps is empty
if (h1 == null ) return h2;
if (h2 == null ) return h1;
// Make sure that h1 has smaller key.
if (h1.key > h2.key) {
[h1, h2] = [h2, h1];
}
// Swap h1.left and h1.right
[h1.left, h1.right] = [h1.right, h1.left];
// Merge h2 and h1.left and make merged tree as left of h1.
h1.left = this .merge(h2, h1.left);
return h1;
}
// function to construct heap using values in the array
construct(root, heap, n) {
let temp;
for (let i = 0; i < n; i++) {
temp = new SkewHeap();
temp.key = heap[i];
root = this .merge(root, temp);
}
return root;
}
// function to print the Skew Heap,
// as it is in form of a tree so we use
// tree traversal algorithms
inorder(root) {
if (root == null ) return ;
else {
this .inorder(root.left);
console.log(root.key + " " );
this .inorder(root.right);
}
return ;
}
} // Driver Code // Construct two heaps let heap = new SkewHeap(),
temp1 = null ,
temp2 = null ;
let heap1 = [12, 5, 10]; let heap2 = [3, 7, 8, 14]; let n1 = heap1.length; let n2 = heap2.length; temp1 = heap.construct(temp1, heap1, n1); temp2 = heap.construct(temp2, heap2, n2); // Merge two heaps temp1 = heap.merge(temp1, temp2); console.log( "The heap obtained after merging is: <br>" );
heap.inorder(temp1); // This code is contributed by sankar. |
The heap obtained after merging is: 12 8 5 10 3 14 7
Time Complexity: O(NlogN)
Auxiliary Space: O(N)