Dado un árbol binario y una clave ‘k’, encuentre la distancia de la hoja más cercana a ‘k’.
Ejemplos:
A / \ B C / \ E F / \ G H / \ / I J K Closest leaf to 'H' is 'K', so distance is 1 for 'H' Closest leaf to 'C' is 'B', so distance is 2 for 'C' Closest leaf to 'E' is either 'I' or 'J', so distance is 2 for 'E' Closest leaf to 'B' is 'B' itself, so distance is 0 for 'B'
El punto principal a tener en cuenta aquí es que una clave más cercana puede ser un descendiente de una clave dada o se puede alcanzar a través de uno de los antepasados.
La idea es recorrer el árbol dado en preorden y realizar un seguimiento de los antepasados en una array. Cuando alcanzamos la clave dada, evaluamos la distancia de la hoja más cercana en el subárbol enraizado con la clave dada. También recorremos todos los ancestros uno por uno y encontramos la distancia de la hoja más cercana en el subárbol enraizado con el ancestro. Comparamos todas las distancias y devoluciones mínimas.
A continuación se muestra la implementación del enfoque anterior.
C++
// A C++ program to find the closest leaf4 // of a given key in Binary Tree #include <bits/stdc++.h> using namespace std; /* A binary tree Node has key, pocharer to left and right children */ struct Node { char key; struct Node* left, *right; }; /* Helper function that allocates a new node with the given data and NULL left and right pocharers. */ Node *newNode(char k) { Node *node = new Node; node->key = k; node->right = node->left = NULL; return node; } // A utility function to find minimum of x and y int getMin(int x, int y) { return (x < y)? x :y; } // A utility function to find distance of closest // leaf of the tree rooted under given root int closestDown(struct Node *root) { // Base cases if (root == NULL) return INT_MAX; if (root->left == NULL && root->right == NULL) return 0; // Return minimum of left and right, plus one return 1 + getMin(closestDown(root->left), closestDown(root->right)); } // Returns distance of the closest leaf to a given key 'k'. The array // ancestors is used to keep track of ancestors of current node and // 'index' is used to keep track of current index in 'ancestors[]' int findClosestUtil(struct Node *root, char k, struct Node *ancestors[], int index) { // Base case if (root == NULL) return INT_MAX; // If key found if (root->key == k) { // Find the closest leaf under the subtree rooted with given key int res = closestDown(root); // Traverse all ancestors and update result if any parent node // gives smaller distance for (int i = index-1; i>=0; i--) res = getMin(res, index - i + closestDown(ancestors[i])); return res; } // If key node found, store current node and recur for left and // right childrens ancestors[index] = root; return getMin(findClosestUtil(root->left, k, ancestors, index+1), findClosestUtil(root->right, k, ancestors, index+1)); } // The main function that returns distance of the closest key to 'k'. It // mainly uses recursive function findClosestUtil() to find the closes // distance. int findClosest(struct Node *root, char k) { // Create an array to store ancestors // Assumption: Maximum height of tree is 100 struct Node *ancestors[100]; return findClosestUtil(root, k, ancestors, 0); } /* Driver program to test above functions*/ int main() { // Let us construct the BST shown in the above figure struct Node *root = newNode('A'); root->left = newNode('B'); root->right = newNode('C'); root->right->left = newNode('E'); root->right->right = newNode('F'); root->right->left->left = newNode('G'); root->right->left->left->left = newNode('I'); root->right->left->left->right = newNode('J'); root->right->right->right = newNode('H'); root->right->right->right->left = newNode('K'); char k = 'H'; cout << "Distance of the closest key from " << k << " is " << findClosest(root, k) << endl; k = 'C'; cout << "Distance of the closest key from " << k << " is " << findClosest(root, k) << endl; k = 'E'; cout << "Distance of the closest key from " << k << " is " << findClosest(root, k) << endl; k = 'B'; cout << "Distance of the closest key from " << k << " is " << findClosest(root, k) << endl; return 0; }
Java
// Java program to find closest leaf of a given key in Binary Tree /* Class containing left and right child of current node and key value*/ class Node { int data; Node left, right; public Node(int item) { data = item; left = right = null; } } class BinaryTree { Node root; // A utility function to find minimum of x and y int getMin(int x, int y) { return (x < y) ? x : y; } // A utility function to find distance of closest leaf of the tree // rooted under given root int closestDown(Node node) { // Base cases if (node == null) return Integer.MAX_VALUE; if (node.left == null && node.right == null) return 0; // Return minimum of left and right, plus one return 1 + getMin(closestDown(node.left), closestDown(node.right)); } // Returns distance of the closest leaf to a given key 'k'. The array // ancestors is used to keep track of ancestors of current node and // 'index' is used to keep track of current index in 'ancestors[]' int findClosestUtil(Node node, char k, Node ancestors[], int index) { // Base case if (node == null) return Integer.MAX_VALUE; // If key found if (node.data == k) { // Find the closest leaf under the subtree rooted with given key int res = closestDown(node); // Traverse all ancestors and update result if any parent node // gives smaller distance for (int i = index - 1; i >= 0; i--) res = getMin(res, index - i + closestDown(ancestors[i])); return res; } // If key node found, store current node and recur for left and // right childrens ancestors[index] = node; return getMin(findClosestUtil(node.left, k, ancestors, index + 1), findClosestUtil(node.right, k, ancestors, index + 1)); } // The main function that returns distance of the closest key to 'k'. It // mainly uses recursive function findClosestUtil() to find the closes // distance. int findClosest(Node node, char k) { // Create an array to store ancestors // Assumption: Maximum height of tree is 100 Node ancestors[] = new Node[100]; return findClosestUtil(node, k, ancestors, 0); } // Driver program to test for above functions public static void main(String args[]) { BinaryTree tree = new BinaryTree(); tree.root = new Node('A'); tree.root.left = new Node('B'); tree.root.right = new Node('C'); tree.root.right.left = new Node('E'); tree.root.right.right = new Node('F'); tree.root.right.left.left = new Node('G'); tree.root.right.left.left.left = new Node('I'); tree.root.right.left.left.right = new Node('J'); tree.root.right.right.right = new Node('H'); tree.root.right.right.right.left = new Node('H'); char k = 'H'; System.out.println("Distance of the closest key from " + k + " is " + tree.findClosest(tree.root, k)); k = 'C'; System.out.println("Distance of the closest key from " + k + " is " + tree.findClosest(tree.root, k)); k = 'E'; System.out.println("Distance of the closest key from " + k + " is " + tree.findClosest(tree.root, k)); k = 'B'; System.out.println("Distance of the closest key from " + k + " is " + tree.findClosest(tree.root, k)); } } // This code has been contributed by Mayank Jaiswal
Python3
# Python program to find closest leaf of a # given key in binary tree INT_MAX = 2**32 # A binary tree node class Node: # Constructor to create a binary tree def __init__(self ,key): self.key = key self.left = None self.right = None def closestDown(root): #Base Case if root is None: return INT_MAX if root.left is None and root.right is None: return 0 # Return minimum of left and right plus one return 1 + min(closestDown(root.left), closestDown(root.right)) # Returns distance of the closes leaf to a given key k # The array ancestors us used to keep track of ancestors # of current node and 'index' is used to keep track of # current index in 'ancestors[i]' def findClosestUtil(root, k, ancestors, index): # Base Case if root is None: return INT_MAX # if key found if root.key == k: # Find closest leaf under the subtree rooted # with given key res = closestDown(root) # Traverse ll ancestors and update result if any # parent node gives smaller distance for i in reversed(range(0,index)): res = min(res, index-i+closestDown(ancestors[i])) return res # if key node found, store current node and recur for left # and right childrens ancestors[index] = root return min( findClosestUtil(root.left, k,ancestors, index+1), findClosestUtil(root.right, k, ancestors, index+1)) # The main function that return distance of the clses key to # 'key'. It mainly uses recursive function findClosestUtil() # to find the closes distance def findClosest(root, k): # Create an array to store ancestors # Assumption: Maximum height of tree is 100 ancestors = [None for i in range(100)] return findClosestUtil(root, k, ancestors, 0) # Driver program to test above function root = Node('A') root.left = Node('B') root.right = Node('C'); root.right.left = Node('E'); root.right.right = Node('F'); root.right.left.left = Node('G'); root.right.left.left.left = Node('I'); root.right.left.left.right = Node('J'); root.right.right.right = Node('H'); root.right.right.right.left = Node('K'); k = 'H'; print ("Distance of the closest key from "+ k + " is",findClosest(root, k)) k = 'C' print ("Distance of the closest key from " + k + " is",findClosest(root, k)) k = 'E' print ("Distance of the closest key from " + k + " is",findClosest(root, k)) k = 'B' print ("Distance of the closest key from " + k + " is",findClosest(root, k)) # This code is contributed by Nikhil Kumar Singh(nickzuck_007)
C#
using System; // C# program to find closest leaf of a given key in Binary Tree /* Class containing left and right child of current node and key value*/ public class Node { public int data; public Node left, right; public Node(int item) { data = item; left = right = null; } } public class BinaryTree { public Node root; // A utility function to find minimum of x and y public virtual int getMin(int x, int y) { return (x < y) ? x : y; } // A utility function to find distance of closest leaf of the tree // rooted under given root public virtual int closestDown(Node node) { // Base cases if (node == null) { return int.MaxValue; } if (node.left == null && node.right == null) { return 0; } // Return minimum of left and right, plus one return 1 + getMin(closestDown(node.left), closestDown(node.right)); } // Returns distance of the closest leaf to a given key 'k'. The array // ancestors is used to keep track of ancestors of current node and // 'index' is used to keep track of current index in 'ancestors[]' public virtual int findClosestUtil(Node node, char k, Node[] ancestors, int index) { // Base case if (node == null) { return int.MaxValue; } // If key found if ((char)node.data == k) { // Find the closest leaf under the subtree rooted with given key int res = closestDown(node); // Traverse all ancestors and update result if any parent node // gives smaller distance for (int i = index - 1; i >= 0; i--) { res = getMin(res, index - i + closestDown(ancestors[i])); } return res; } // If key node found, store current node and recur for left and // right childrens ancestors[index] = node; return getMin(findClosestUtil(node.left, k, ancestors, index + 1), findClosestUtil(node.right, k, ancestors, index + 1)); } // The main function that returns distance of the closest key to 'k'. It // mainly uses recursive function findClosestUtil() to find the closes // distance. public virtual int findClosest(Node node, char k) { // Create an array to store ancestors // Assumption: Maximum height of tree is 100 Node[] ancestors = new Node[100]; return findClosestUtil(node, k, ancestors, 0); } // Driver program to test for above functions public static void Main(string[] args) { BinaryTree tree = new BinaryTree(); tree.root = new Node('A'); tree.root.left = new Node('B'); tree.root.right = new Node('C'); tree.root.right.left = new Node('E'); tree.root.right.right = new Node('F'); tree.root.right.left.left = new Node('G'); tree.root.right.left.left.left = new Node('I'); tree.root.right.left.left.right = new Node('J'); tree.root.right.right.right = new Node('H'); tree.root.right.right.right.left = new Node('H'); char k = 'H'; Console.WriteLine("Distance of the closest key from " + k + " is " + tree.findClosest(tree.root, k)); k = 'C'; Console.WriteLine("Distance of the closest key from " + k + " is " + tree.findClosest(tree.root, k)); k = 'E'; Console.WriteLine("Distance of the closest key from " + k + " is " + tree.findClosest(tree.root, k)); k = 'B'; Console.WriteLine("Distance of the closest key from " + k + " is " + tree.findClosest(tree.root, k)); } } // This code is contributed by Shrikant13
Javascript
<script> // JavaScript program to find closest // leaf of a given key in Binary Tree /* Class containing left and right child of current node and key value*/ class Node { constructor(item) { this.data = item; this.left = null; this.right= null; } } var root = null; // A utility function to find minimum of x and y function getMin(x, y) { return (x < y) ? x : y; } // A utility function to find distance of closest leaf of the tree // rooted under given root function closestDown(node) { // Base cases if (node == null) { return 1000000000; } if (node.left == null && node.right == null) { return 0; } // Return minimum of left and right, plus one return 1 + getMin(closestDown(node.left), closestDown(node.right)); } // Returns distance of the closest // leaf to a given key 'k'. The array // ancestors is used to keep track of // ancestors of current node and // 'index' is used to keep track of // current index in 'ancestors[]' function findClosestUtil(node, k, ancestors, index) { // Base case if (node == null) { return 1000000000; } // If key found if (node.data == k) { // Find the closest leaf under the // subtree rooted with given key var res = closestDown(node); // Traverse all ancestors and update // result if any parent node // gives smaller distance for (var i = index - 1; i >= 0; i--) { res = getMin(res, index - i + closestDown(ancestors[i])); } return res; } // If key node found, store current // node and recur for left and // right childrens ancestors[index] = node; return getMin(findClosestUtil(node.left, k, ancestors, index + 1), findClosestUtil(node.right, k, ancestors, index + 1)); } // The main function that returns // distance of the closest key to 'k'. It // mainly uses recursive function // findClosestUtil() to find the closes // distance. function findClosest(node, k) { // Create an array to store ancestors // Assumption: Maximum height of tree is 100 var ancestors = Array(100).fill(null); return findClosestUtil(node, k, ancestors, 0); } // Driver program to test for above functions root = new Node('A'); root.left = new Node('B'); root.right = new Node('C'); root.right.left = new Node('E'); root.right.right = new Node('F'); root.right.left.left = new Node('G'); root.right.left.left.left = new Node('I'); root.right.left.left.right = new Node('J'); root.right.right.right = new Node('H'); root.right.right.right.left = new Node('H'); var k = 'H'; document.write( "Distance of the closest key from " + k + " is " + findClosest(root, k) + "<br>"); k = 'C'; document.write( "Distance of the closest key from " + k + " is " + findClosest(root, k)+ "<br>"); k = 'E'; document.write( "Distance of the closest key from " + k + " is " + findClosest(root, k)+ "<br>"); k = 'B'; document.write( "Distance of the closest key from " + k + " is " + findClosest(root, k)+ "<br>"); </script>
Distance of the closest key from H is 1 Distance of the closest key from C is 2 Distance of the closest key from E is 2 Distance of the closest key from B is 0
El código anterior se puede optimizar almacenando la información izquierda/derecha también en la array de antepasados. La idea es que, si la clave dada está en el subárbol izquierdo de un ancestro, entonces no tiene sentido llamar a closeDown(). Además, el bucle que atraviesa la array de antepasados se puede optimizar para no atravesar antepasados que están a más distancia que el resultado actual.
Ejercicio:
Amplíe la solución anterior para imprimir no solo la distancia, sino también la clave de la hoja más cercana.
Publicación traducida automáticamente
Artículo escrito por GeeksforGeeks-1 y traducido por Barcelona Geeks. The original can be accessed here. Licence: CCBY-SA