mirror of
https://github.com/TheAlgorithms/C
synced 2024-11-29 00:33:14 +03:00
b79f0c1214
I puted few comments and changed a little bit.
207 lines
5.6 KiB
C
207 lines
5.6 KiB
C
#include <stdio.h>
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#include <stdlib.h>
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/* A basic unbalanced binary search tree implementation in C, with the following functionalities implemented:
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- Insertion
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- Deletion
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- Search by key value
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- Listing of node keys in order of value (from left to right)
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*/
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// Node, the basic data structure in the tree
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typedef struct node{
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// left child
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struct node* left;
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// right child
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struct node* right;
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// data of the node
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int data;
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} node;
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// The node constructor, which receives the key value input and returns a node pointer
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node* newNode(int data){
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// creates a slug
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node* tmp = (node*)malloc(sizeof(node));
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// initializes the slug
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tmp->data = data;
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tmp->left = NULL;
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tmp->right = NULL;
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return tmp;
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}
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// Insertion procedure, which inserts the input key in a new node in the tree
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node* insert(node* root, int data){
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// If the root of the subtree is null, insert key here
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if (root == NULL)
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root = newNode(data);
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// If it isn't null and the input key is greater than the root key, insert in the right leaf
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else if (data > root->data)
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root->right = insert(root->right, data);
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// If it isn't null and the input key is lower than the root key, insert in the left leaf
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else if (data < root->data)
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root->left = insert(root->left, data);
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// Returns the modified tree
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return root;
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}
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// Utilitary procedure to find the greatest key in the left subtree
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node* getMax(node* root){
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// If there's no leaf to the right, then this is the maximum key value
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if (root->right == NULL)
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return root;
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else
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root->right = getMax(root->right);
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}
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// Deletion procedure, which searches for the input key in the tree and removes it if present
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node* delete(node* root, int data){
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// If the root is null, nothing to be done
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if (root == NULL)
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return root;
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// If the input key is greater than the root's, search in the right subtree
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else if (data > root->data)
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root->right = delete(root->right, data);
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// If the input key is lower than the root's, search in the left subtree
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else if (data < root->data)
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root->left = delete(root->left, data);
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// If the input key matches the root's, check the following cases
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// termination condition
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else if (data == root->data){
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// Case 1: the root has no leaves, remove the node
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if ((root->left == NULL) && (root->right == NULL)){
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free(root);
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return NULL;
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}
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// Case 2: the root has one leaf, make the leaf the new root and remove the old root
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else if (root->left == NULL){
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node* tmp = root;
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root = root->right;
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free(tmp);
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return root;
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}
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else if (root->right == NULL){
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node* tmp = root;
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root = root->left;
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free(tmp);
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return root;
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}
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// Case 3: the root has 2 leaves, find the greatest key in the left subtree and switch with the root's
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else {
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// finds the biggest node in the left branch.
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node* tmp = getMax(root->left);
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// sets the data of this node equal to the data of the biggest node (lefts)
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root->data = tmp->data;
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root->left = delete(root->left, tmp->data);
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}
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}
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return root;
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}
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// Search procedure, which looks for the input key in the tree and returns 1 if it's present or 0 if it's not in the tree
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int find(node* root, int data){
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// If the root is null, the key's not present
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if (root == NULL)
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return 0;
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// If the input key is greater than the root's, search in the right subtree
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else if (data > root->data)
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return find(root->right, data);
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// If the input key is lower than the root's, search in the left subtree
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else if (data < root->data)
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return find(root->left, data);
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// If the input and the root key match, return 1
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else if (data == root->data)
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return 1;
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}
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// Utilitary procedure to measure the height of the binary tree
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int height(node* root){
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// If the root is null, this is the bottom of the tree (height 0)
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if (root == NULL)
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return 0;
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else{
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// Get the height from both left and right subtrees to check which is the greatest
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int right_h = height(root->right);
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int left_h = height(root->left);
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// The final height is the height of the greatest subtree(left or right) plus 1(which is the root's level)
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if (right_h > left_h)
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return (right_h + 1);
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else
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return (left_h + 1);
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}
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}
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// Utilitary procedure to free all nodes in a tree
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void purge(node* root){
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if (root != NULL){
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if (root->left != NULL)
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purge(root->left);
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if (root->right != NULL)
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purge(root->right);
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free(root);
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}
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}
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// Traversal procedure to list the current keys in the tree in order of value (from the left to the right)
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void inOrder(node* root){
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if(root != NULL){
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inOrder(root->left);
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printf("\t[ %d ]\t", root->data);
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inOrder(root->right);
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}
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}
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void main(){
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// this reference don't change.
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// only the tree changes.
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node* root = NULL;
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int opt = -1;
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int data = 0;
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// event-loop.
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while (opt != 0){
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printf("\n\n[1] Insert Node\n[2] Delete Node\n[3] Find a Node\n[4] Get current Height\n[5] Print Tree in Crescent Order\n[0] Quit\n");
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scanf("%d",&opt); // reads the choice of the user
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// processes the choice
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switch(opt){
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case 1: printf("Enter the new node's value:\n");
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scanf("%d",&data);
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root = insert(root,data);
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break;
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case 2: printf("Enter the value to be removed:\n");
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if (root != NULL){
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scanf("%d",&data);
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root = delete(root,data);
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}
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else
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printf("Tree is already empty!\n");
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break;
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case 3: printf("Enter the searched value:\n");
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scanf("%d",&data);
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find(root,data) ? printf("The value is in the tree.\n") : printf("The value is not in the tree.\n");
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break;
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case 4: printf("Current height of the tree is: %d\n", height(root));
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break;
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case 5: inOrder(root);
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break;
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}
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}
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// deletes the tree from the heap.
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purge(root);
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}
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