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What is Balanced BT ?

Binary tree where the difference between the height of left subtree and right subtree for every node is not more than k(usually k=1). This difference is called balanced factor. bf=|height of LST - height of RST|.

So for every node height of LST - height of RST should be {-1,0,1}.

AVL TREE

AVL Tree is a self-balancing BST (i.e.,basically a BST which remains balanced even though you insert or delete values).

Ways of Balancing AVL Tree

To maintain the balance in AVL Tree(i.e to be AVL tree always) while inserting and deleting, we perform Rotations. Depending on different imbalance cases, we have 4 basic types of rotations –

  • LEFT LEFT Imbalance/case - RIGHT Rotation
  • RIGHT RIGHT Imbalance/case - LEFT Rotation
  • LEFT RIGHT Imbalance/case - LEFT RIGHT Rotation
  • RIGHT LEFT Imbalance/case - RIGHT LEFT Rotation


INSERTION IN AVL TREE

// INSERTION IN AVL TREE STARTS
		public Node insertNodeRECURR(Node r, int key) {

    		// if the root is null, create a new node and return it
            if (r == null)
            	return new Node(key);


            // if the given key is less than the root node,
            // recur for the left subtree
            else if (key < r.data)
            	r.left = insertNodeRECURR(r.left, key);


            // otherwise, recur for the right subtree
            else if(key > r.data)
                r.right = insertNodeRECURR(r.right, key);

            else // key== root.data
            {
            	System.out.println("Dublicate value not allowed");
            	return r;
            }

            // HERE COME'S AVL TREE PART STARTS
            int bf = getBalancedFac(r);
            // Left Case
            if (bf > 1 && key < r.left.data)
              return rightRotate(r);
            // Right Case
            else if(bf < -1 && key > r.right.data)
            	return leftRotate(r);
            // Left-Right Case
            else if(bf > 1 && key > r.left.data)
            {
            	r.left=leftRotate(r.left);
            	return rightRotate(r);
            }
            // Right-Left Case
            else if(bf < -1 && key < r.right.data)
            {
            	r.right=rightRotate(r.right);
            	return leftRotate(r);
            }
            // HERE COME'S AVL TREE PART ENDS


            return r;
    	}
// INSERTION IN AVL TREE ENDS

DELETION IN AVL TREE

// DELETION IN AVL TREE STARTS
		public Node delete(Node r,int val) {
			if(r==null) return null;
			if(val<r.data) {
				r.left=delete(r.left,val);
			}
			else if(val>r.data) {
				r.right=delete(r.right,val);
			}
			else {
				if(r.left!=null && r.right!=null) {
					int lmax=maxLeft(r.left);
					r.data=lmax;
					r.left=delete(r.left,lmax);
				}
				else if(r.left!=null) {
					return  r.left;
				}
				else if(r.right!=null) {
					return  r.right;
				}
				else {
					return null;
				}
			}

			// HERE COME'S AVL TREE DELETION PART STARTS
				int bf=getBalancedFac(r);
				// bf=2 means deletion from right subtree and now remaining is left imbalance OR L-R imbalance

				/*
				 * bf(r.left)=1 means remaing structure in this is:-
				 		30 bf=2
				 	   /
				 	  20   bf=1
				 	 /
				 	10     bf=0



				 * bf(r.left)=0 means remaing structure in this is:-
				 	   30 bf=2
				 	  /
				 	 20   bf=0
				 	/  \
				   10  25   bf=0 for both
			  */
				if(bf==2 && getBalancedFac(r.left)>=0)
					return rightRotate(r);
				else if(bf==2 && getBalancedFac(r.left)==-1 ) {
					r.left=leftRotate(r.left);
					return rightRotate(r);
				}
				// bf=-2 means deletion from left subtree and now remaining is right imbalance OR R-L imbalance

				/*
				 * bf(r.right)=-1 means remaing structure in this is:-
				 		10 bf=-2
				 		  \
				 		  20 bf=-1
				 		    \
				 		    30 bf=0



				 * bf(r.right)=0 means remaing structure in this is:-
				 	   10  bf=-2
				 		 \
				 		 20 bf=0
				 		/  \
				 	  15    30 bf=0 for both
			  */
				else if(bf==-2 && getBalancedFac(r.right)<=0)
					return leftRotate(r);
				else if(bf==-2 && getBalancedFac(r.right)==1 ) {
					r.right=rightRotate(r.right);
					return leftRotate(r);
				}
			// HERE COME'S AVL TREE DELETION PART ENDS
			return r;
		}

		public static int maxLeft(Node node) {
			if(node.right!=null) {
				return maxLeft(node.right);
			}
			else {
				return node.data;
			}
		}
// DELETION IN AVL TREE ENDS



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