C program for searching a Node in List | Link List Searching in C
Data values are given which we call a key and a binary
search tree. To search for the key in the given binary search tree, start with
the root node and compare the key with the
data value of the root node. If they match, return the root pointer. If the key
is less than the data value of the root node, repeat the process by using the
left subtree. Otherwise, repeat the same process with the right subtree until
either a match is found or the subtree under consideration becomes an empty
tree.
#include#include struct tnode { int data; struct tnode *lchild, *rchild; }; /* A function to serch for a given data value in a binary search tree*/ struct tnode *search( struct tnode *p,int key) { struct tnode *temp; temp = p; while( temp != NULL) { if(temp->data == key) return(temp); else if(temp->data > key) temp = temp->lchild; else temp = temp->rchild; } return(NULL); } /*an iterative function to print the binary tree in inorder*/ void inorder1(struct tnode *p) { struct tnode *stack[100]; int top; top = −1; if(p != NULL) { top++; stack[top] = p; p = p->lchild; while(top >= 0) { while ( p!= NULL)/* push the left child onto stack*/ { top++; stack[top] =p; p = p->lchild; } p = stack[top]; top-; printf("%d\t",p->data); p = p->rchild; if ( p != NULL) /* push right child*/ { top++; stack[top] = p; p = p->lchild; } } } } /* A function to insert a new node in binary search tree to get a tree created*/ struct tnode *insert(struct tnode *p,int val) { struct tnode *temp1,*temp2; if(p == NULL) { p = (struct tnode *) malloc(sizeof(struct tnode)); /* insert the new node as root node*/ if(p == NULL) { printf("Cannot allocate\n"); exit(0); } p->data = val; p->lchild=p->rchild=NULL; } else { temp1 = p; /* traverse the tree to get a pointer to that node whose child will be the newly created node*/ while(temp1 != NULL) { temp2 = temp1; if( temp1 ->data > val) temp1 = temp1->lchild; else temp1 = temp1->rchild; } if( temp2->data > val) { temp2->lchild = (struct tnode*)malloc(sizeof(struct tnode));/ *inserts the newly created node as left child*/ temp2 = temp2->lchild; if(temp2 == NULL) { printf("Cannot allocate\n"); exit(0); } temp2->data = val; temp2->lchild=temp2->rchild = NULL; } else { temp2->rchild = (struct tnode*)malloc(sizeof(struct tnode));/ *inserts the newly created node as left child*/ temp2 = temp2->rchild; if(temp2 == NULL) { printf("Cannot allocate\n"); exit(0); } temp2->data = val; temp2->lchild=temp2->rchild = NULL; } } return(p); } void main() { struct tnode *root = NULL, *temp = NULL; int n,x; printf("Enter the number of nodes in the tree\n"); scanf("%d",&n); while( n - > 0) { printf("Enter the data value\n"); scanf("%d",&x); root = insert(root,x); } printf("The created tree is :\n"); inorder1(root); printf("\n Enter the value of the node to be searched\n"); scanf("%d",&n); temp=search(root,n); if(temp != NULL) printf("The data value is present in the tree \n"); else printf("The data value is not present in the tree \n"); }
Explanation
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Input: 1. The number of nodes that the tree to be created should have
2. The data values of each node in the tree to be created
3. The key value -
Output: If the key is present and appears in the created tree, then a message
"The data value is present in the tree" appears. Otherwise the message
"The data value is not present in the tree" appears.
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