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Software Development Exam  >  Software Development Tests  >  DSA in C++  >  Test: Trees - 2 - Software Development MCQ

Test: Trees - 2 - Software Development MCQ


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15 Questions MCQ Test DSA in C++ - Test: Trees - 2

Test: Trees - 2 for Software Development 2024 is part of DSA in C++ preparation. The Test: Trees - 2 questions and answers have been prepared according to the Software Development exam syllabus.The Test: Trees - 2 MCQs are made for Software Development 2024 Exam. Find important definitions, questions, notes, meanings, examples, exercises, MCQs and online tests for Test: Trees - 2 below.
Solutions of Test: Trees - 2 questions in English are available as part of our DSA in C++ for Software Development & Test: Trees - 2 solutions in Hindi for DSA in C++ course. Download more important topics, notes, lectures and mock test series for Software Development Exam by signing up for free. Attempt Test: Trees - 2 | 15 questions in 30 minutes | Mock test for Software Development preparation | Free important questions MCQ to study DSA in C++ for Software Development Exam | Download free PDF with solutions
Test: Trees - 2 - Question 1
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In a binary search tree, the time complexity of the search operation is:

Detailed Solution for Test: Trees - 2 - Question 1

In a binary search tree, the search operation has a time complexity of O(log N), where N is the total number of nodes in the tree. This is because the search narrows down the search space by half at each step, similar to a binary search in a sorted array.

Test: Trees - 2 - Question 2
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Which of the following operations can be efficiently performed on a binary search tree?

Detailed Solution for Test: Trees - 2 - Question 2

All of the mentioned operations can be efficiently performed on a binary search tree. Insertion and deletion of elements maintain the binary search tree property, and the elements can be sorted in ascending order by performing an inorder traversal. Additionally, finding the kth smallest element can be done efficiently using inorder traversal or other techniques.

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Test: Trees - 2 - Question 3
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In a binary search tree, if the values are inserted in a sorted order, the resulting tree will be:

Detailed Solution for Test: Trees - 2 - Question 3

If the values are inserted in a sorted order into a binary search tree, the resulting tree will be unbalanced, with one long branch of nodes. This is because the tree's structure depends on the order of insertion, and inserting values in sorted order leads to a skewed tree.

Test: Trees - 2 - Question 4
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#include <iostream>
using namespace std;

struct Node {
   int data;
   Node* left;
   Node* right;
};

Node* findMin(Node* root) {
   if (root == NULL)
      return NULL;

   if (root->left == NULL)
      return root;

   return findMin(root->left);
}

int main() {
   Node* root = new Node();
   root->data = 10;
   root->left = new Node();
   root->left->data = 5;
   root->right = new Node();
   root->right->data = 15;
   root->right->left = new Node();
   root->right->left->data = 12;
   root->right->right = new Node();
   root->right->right->data = 18;

   Node* minNode = findMin(root);

   cout << minNode->data << endl;
   return 0;
}
What will be the output of the above code?
Detailed Solution for Test: Trees - 2 - Question 4

The code defines a function 'findMin' that finds the minimum value in a binary search tree. The tree is created with six nodes, and the function is called with the root node. The output is the minimum value, which is 5.

Test: Trees - 2 - Question 5
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#include <iostream>
using namespace std;

struct Node {
   int data;
   Node* left;
   Node* right;
};

void deleteTree(Node* root) {
   if (root == NULL)
      return;

   deleteTree(root->left);
   deleteTree(root->right);

   delete root;
}

int main() {
   Node* root = new Node();
   root->data = 10;
   root->left = new Node();
   root->left->data = 20;
   root->right = new Node();
   root->right->data = 30;
   root->left->left = new Node();
   root->left->left->data = 40;
   root->left->right = new Node();
   root->left->right->data = 50;

   deleteTree(root);

   cout << root->data << endl;
   return 0;
}
What will be the output of the above code?
Detailed Solution for Test: Trees - 2 - Question 5

The code defines a function 'deleteTree' that recursively deletes all the nodes in a binary tree. After calling 'deleteTree' with the root node, the 'root' pointer becomes a dangling pointer, and accessing its data will lead to undefined behavior. The output cannot be determined.

Test: Trees - 2 - Question 6
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What is a tree data structure?
Detailed Solution for Test: Trees - 2 - Question 6

A tree data structure is a hierarchical data structure consisting of nodes connected by edges. It starts with a root node and each node can have zero or more child nodes.

Test: Trees - 2 - Question 7
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Which traversal technique visits the root node first?
Detailed Solution for Test: Trees - 2 - Question 7

Preorder traversal visits the root node first, then the left subtree, and finally the right subtree.

Test: Trees - 2 - Question 8
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Which traversal technique visits the left subtree first?
Detailed Solution for Test: Trees - 2 - Question 8

Inorder traversal visits the left subtree first, then the root node, and finally the right subtree.

Test: Trees - 2 - Question 9
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In a binary search tree, which property holds true for any node?
Detailed Solution for Test: Trees - 2 - Question 9

In a binary search tree, the value of the right child is greater than the value of the node, while the value of the left child is less than the value of the node.

Test: Trees - 2 - Question 10
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What is the time complexity of searching for an element in a binary search tree?
Detailed Solution for Test: Trees - 2 - Question 10

The time complexity of searching for an element in a binary search tree is O(log n) in the average case, where n is the number of nodes in the tree.

Test: Trees - 2 - Question 11
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What will be the output of the following code?
#include <iostream>

struct Node {
   int data;
   Node* left;
   Node* right;
};

Node* createNode(int data) {
   Node* newNode = new Node();
   newNode->data = data;
   newNode->left = nullptr;
   newNode->right = nullptr;

   return newNode;
}

void insertNode(Node* root, int data) {
   if (root->data > data) {
      if (root->left == nullptr) {
         root->left = createNode(data);
      } else {
         insertNode(root->left, data);
      }
   } else {
      if (root->right == nullptr) {
         root->right = createNode(data);
      } else {
         insertNode(root->right, data);
      }
   }
}

void inOrderTraversal(Node* node) {
   if (node == nullptr)
      return;

   inOrderTraversal(node->left);
   std::cout << node->data << " ";
   inOrderTraversal(node->right);
}

int main() {
   Node* root = createNode(10);
   insertNode(root, 20);
   insertNode(root, 30);

   inOrderTraversal(root);

   delete root->left;
   delete root->right;
   delete root;

   return 0;
}
Detailed Solution for Test: Trees - 2 - Question 11

The code inserts nodes with values 20 and 30 into the binary search tree and performs an inorder traversal. The output will be "20 10 30".

Test: Trees - 2 - Question 12
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What will be the output of the following code?
#include <iostream>

struct Node {
   int data;
   Node* left;
   Node* right;
};

Node* deleteNode(Node* root, int key) {
   if (root == nullptr)
      return root;

   if (key < root->data) {
      root->left = deleteNode(root->left, key);
   } else if (key > root->data) {
      root->right = deleteNode(root->right, key);
   } else {
      if (root->left == nullptr) {
         Node* temp = root->right;
         delete root;
         return temp;
      } else if (root->right == nullptr) {
         Node* temp = root->left;
         delete root;
         return temp;
      }

      Node* temp = root->right;
      while (temp->left != nullptr) {
         temp = temp->left;
      }
      root->data = temp->data;
      root->right = deleteNode(root->right, temp->data);
   }

   return root;
}

void inOrderTraversal(Node* node) {
   if (node == nullptr)
      return;

   inOrderTraversal(node->left);
   std::cout << node->data << " ";
   inOrderTraversal(node->right);
}

int main() {
   Node* root = new Node();
   root->data = 10;
   root->left = new Node();
   root->right = new Node();
   root->left->data = 20;
   root->right->data = 30;

   root = deleteNode(root, 20);

   inOrderTraversal(root);

   delete root->left;
   delete root->right;
   delete root;

   return 0;
}
Detailed Solution for Test: Trees - 2 - Question 12

The code deletes the node with a value of 20 from the binary search tree and performs an inorder traversal. The output will be "10 30"

Test: Trees - 2 - Question 13
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Which traversal technique is used in the following code?
#include <iostream>

struct Node {
   int data;
   Node* left;
   Node* right;
};

void preOrderTraversal(Node* node) {
   if (node == nullptr)
      return;

   std::cout << node->data << " ";
   preOrderTraversal(node->left);
   preOrderTraversal(node->right);
}

int main() {
   Node* root = new Node();
   root->data = 10;
   root->left = new Node();
   root->right = new Node();
   root->left->data = 20;
   root->right->data = 30;

   preOrderTraversal(root);

   delete root->left;
   delete root->right;
   delete root;

   return 0;
}
Detailed Solution for Test: Trees - 2 - Question 13

The code performs a preorder traversal of the tree, which visits the root node first, then the left subtree, and finally the right subtree.

Test: Trees - 2 - Question 14
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What will be the output of the following code?
#include <iostream>

struct Node {
   int data;
   Node* left;
   Node* right;
};

int findMin(Node* root) {
   if (root == nullptr)
      return INT_MAX;

   int minVal = root->data;
   int leftMin = findMin(root->left);
   int rightMin = findMin(root->right);

   if (leftMin < minVal)
      minVal = leftMin;
   if (rightMin < minVal)
      minVal = rightMin;

   return minVal;
}

int main() {
   Node* root = new Node();
   root->data = 10;
   root->left = new Node();
   root->right = new Node();
   root->left->data = 20;
   root->right->data = 30;

   int minValue = findMin(root);

   delete root->left;
   delete root->right;
   delete root;

   std::cout << minValue;

   return 0;
}
Detailed Solution for Test: Trees - 2 - Question 14

The code finds the minimum value in the tree using a recursive function. The minimum value in the given tree is 20.

Test: Trees - 2 - Question 15
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What will be the output of the following code?
#include <iostream>

struct Node {
   int data;
   Node* left;
   Node* right;
};

bool searchNode(Node* root, int key) {
   if (root == nullptr)
      return false;

   if (root->data == key)
      return true;
   else if (key < root->data)
      return searchNode(root->left, key);
   else
      return searchNode(root->right, key);
}

int main() {
   Node* root = new Node();
   root->data = 10;
   root->left = new Node();
   root->right = new Node();
   root->left->data = 20;
   root->right->data = 30;

   bool isFound = searchNode(root, 20);

   delete root->left;
   delete root->right;
   delete root;

   std::cout << std::boolalpha << isFound;

   return 0;
}
Detailed Solution for Test: Trees - 2 - Question 15

The code searches for the node with a value of 20 in the binary search tree and returns true if it is found. In this case, the node is found, so the output will be "true".

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