Inorder Predecessor and Successor of Binary Search Tree
In a given Binary Search Tree need to find the predecessor and Successor of a given node.
What is Predecessor and Successor ?
In a given Binary Search Tree highest element on the left subtree is the Predecessor and lowest element on the right subtree is the Successor of the given node. For example in a below given binary search tree if we need to find Predecessor and Successor of node 28
then, node 20 will be the Predecessor and node 36 will be the Successor.
Lets see simple example as how to find Inorder Predecessor and Successor for any given binary tree.
OUTPUT:
What is Predecessor and Successor ?
In a given Binary Search Tree highest element on the left subtree is the Predecessor and lowest element on the right subtree is the Successor of the given node. For example in a below given binary search tree if we need to find Predecessor and Successor of node 28
then, node 20 will be the Predecessor and node 36 will be the Successor.
Lets see simple example as how to find Inorder Predecessor and Successor for any given binary tree.
public class PredecessorSuccessor { class BST { BST left; // Left subtree BST right; // Right subtree int data; // Element public BST(int data) { this.data = data; } } private int predecessor = -1; private int successor = -1; private int previous = -1; public static void main(String[] args) { int val[] = new int[] { 28, 15, 40, 19, 10, 36, 45, 20, 5, 50 }; int findPreSuc = 28; PredecessorSuccessor obj = new PredecessorSuccessor(); BST root = obj.createBST(val); obj.getPredecessorSuccessor(root, findPreSuc); System.out.println("Given node element : "+findPreSuc); if(obj.predecessor == -1) { System.out.println("No Predecessor for the given node "); }else { System.out.println("Predecessor : " + obj.predecessor); }if(obj.successor == -1) { System.out.println("No Successor for the given node "); }else { System.out.println("Successor : " + obj.successor); } } // BST in-order traversal public void getPredecessorSuccessor(BST root, int findPreSuc) { // Return once we got both Predecessor and Successor if (predecessor != -1 && successor != -1) { return; } // Recursive to left subtree if (root.left != null) { getPredecessorSuccessor(root.left, findPreSuc); } // Getting Predecessor if (root.data == findPreSuc) { predecessor = previous; } // Getting Successor if (findPreSuc == previous) { successor = root.data; previous = root.data; return; } previous = root.data; // Recursive to right subtree if (root.right != null) { getPredecessorSuccessor(root.right, findPreSuc); } } public BST createBST(int[] val) { BST root = new BST(val[0]); // Root node with 1st element BST tmpRoot = root; for (int i = 1; i < val.length; i++) { BST lastNode = getLastNode(tmpRoot, val[i]); if (val[i] > lastNode.data) { BST tmp = new BST(val[i]); lastNode.right = tmp; } else { BST tmp = new BST(val[i]); lastNode.left = tmp; } } return root; } public BST getLastNode(BST root, int val) { if (val > root.data) { if (root.right == null) { return root; } else return getLastNode(root.right, val); } else { if (root.left == null) { return root; } else return getLastNode(root.left, val); } } }
OUTPUT:
Given node element : 28 Predecessor : 20 Successor : 36