QUIZ 1 + 2

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#include <iostream> // Link list nodestruct Node { int data; struct Node* next; }; static void reverse(Node** head_ref) { Node* prev = nullptr;Node* current = *head_ref; Node* next; while (current != nullptr) { next = current->next; current->next = prev; prev = current; current = next; } //ADD A STATEMENT HERE } What should be added in place of "//ADD A STATEMENT HERE", so that the function correctly reverses a linked list.

*head_ref = prev;

What output is displayed after the following segment of code executes: stack <int> s; int a = 22, b = 44; s.push(2); s.push(a); s.push(a + b); b = s.top(); s.pop(); s.push(b); s.push(a - b); s.pop(); while (!s.empty()) { cout << s.top() << endl; s.pop(); }

66 22 2

Explain the concept of amortized analysis and how it is applied in algorithm analysis.

Amortized analysis is a method used to determine the average time complexity of a sequence of operations performed on a data structure. It involves analyzing the total cost of a series of operations over time, rather than individual operations.

Which data structure requires a contiguous block of memory?

Array

If the characters 'D', 'C', 'B', 'A' are placed in a queue (in that order), and then removed one at a time, in what order will they be removed?

DCBA

Which of the following operations cannot be performed efficiently on a singly linked list?

Deletion at the Tail

What is the primary advantage of using a doubly linked list over a singly linked list?

Efficient Insertion at Both Ends

A stack is an example of a non-linear data structure.

False

Which of the following is NOT a desirable property of a hash function h(k)?

If x1, ... , xn are the items to be hashed, then the numbers h(x1), ... , h(xn) should be uniformly distributed over the integers. It should be computable in O(1) time. The range of h(k) should include a wide variety of integers.

Compare and contrast singly linked lists and doubly linked lists in terms of operations and memory overhead.

In a singly linked list each node knows which next node comes next in the list, while doubly linked list's nodes knows both which node comes next and which node is directly before it in the list. As such singly linked lists have lower memory overhead, storing half the number of pointers, but doubly linked lists allow traversal in both directions and easier deletion of nodes.

Which of the following operations is NOT typically performed on a stack?

Insertion In the Middle

Which of the following is true about linked list implementation of stack?

None of the above

What is the time complexity of accessing an element in an array?

O(1)

Which if the following represent the highest runtime complexity?

O(n^2)

Part 1 (5 points) Consider a hash table storing integer keys that handles collision using double hashing. If N = 15 h(k) = k mod 15 d(k) = 11 -k mod 11 Insert the following keys in order into the hash table below 32, 64, 18, 33, 19 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Part 2 (3 points) Assuming your hash table is implemented as an array, write C++ code to implement the double hashing approach above. Assume you only have to implement the insert method and you have an array called table with each location initialized to -1. This method should take as input the int key. In the method you will need to do the following: compute the hash code detect a collision compute d(k) place the data correctly Make sure your code treats the array as a circular array, and wraps around.

Part 1: 01 2 3 4 5 6 7 8 9 10 11 12 13 14 ------------------------------------------------------------ 32 18 64 19 33 Part 2: void insert(int key) { // Compute the hash code int index = key % 15; if (table[index] == -1) { // No collision, insert directly table[index] = key; } else { // Collision occurred, use double hashing with d(k) = 11 - k mod 11 int step = 11 - (key % 11); int newIndex = (index + step) % 15; while (table[newIndex] != -1) { // Continue probing until finding an empty slot newIndex = (newIndex + step) % 15; } // Insert into the new index after collision resolution table[newIndex] = key; } }

Linear Probing

Place data in the next available space

Which data structure would be most appropriate to use for round-robin scheduling (in which the scheduler cycles repeatedly through all ready processes)?

Queue

Which of the following would be the best option to use to serve as the key for storing information in a key-value pair?

student ID

A stack can be implemented using either arrays or a linked lists.

true

In a doubly linked list, each node contains pointers to both the next and previous nodes.

true

Queues follow the Last In, First Out (LIFO) principle.

false

Write a C++ method to find the sum of all elements in a queue q. Assume you have all the supporting code you need including code that implements enqueue, dequeue, empty, front NOTE: you do NOT need to preserve the information in the queue.

int sumOfQueueElements() { int sum = 0; // Iterate through the queue and add each element to the sum while (!q.empty()) { sum += q.front(); q.pop(); } return sum; }

Assuming the code below has no errors and the necessary methods have been implemented, what will the output of the code be? #include <iostream> #include <queue> int main() { std::queue<int> queue; for (int i = 0; i<40; i++) { if(i%4 ==0){queue.enqueue(i); } } std::cout << "Elements in the queue after loop completes are: "; while (!queue.empty()) { std::cout << queue.front() << " "; queue.dequeue(); } std::cout << std::endl; return 0; }

Elements in the queue after loop completes are: 0 4 8 12 16 20 24 28 32 36

What output will be produced by the code below? #include <iostream> #include <stack> int main() { std::stack<int> stack; stack.push(10); stack.push(20); stack.pop(); stack.push(30); stack.pop(); stack.push(40); stack.push(50); stack.pop(); std::cout << "Elements in the stack after all operations: "; while (!stack.empty()) { std::cout << stack.top() << " "; stack.pop();}std::cout << std::endl; return 0; }

Elements in the stack after all operations: 40 10

In the linked list implementation of a stack, in the push operation, if new nodes are inserted at the front of the linked list, then when popping, nodes must be removed from the end of the linked list.

False

Which of the following data structures does NOT requires contiguous require contiguous memory allocation?

Linked List

Which data structure uses Last In, First Out (LIFO)

Stack

What does considering the amortized processing time of an algorithm help us understand?

The average time taken by a sequence of operations performed by the algorithm

A hash tables can perform many operations like insert, delete, find and others very efficiently, this can only happen if the hash function and load factor have certain properties. What is the most important property?

The keys are distributed uniformly

What is the load factor of a hash table in C++? Why is it important?

The load factor is the ratio of the number of stored elements to the size of the hash table. It's important because a high load factor can lead to more collisions and reduced performance.

Describe a scenario where using a queue would be more appropriate than using a stack. Ensure that you show how data is manipulated in each data structure when you justify your choice for the scenario you specify.

There are many examples of scenarios where using a queue would be more appropriate than using a stack. One exmaple is in managing tasks or print jobs. When you have a shared printer, multiple users may send print jobs to the printer at different times. A queue ensures that print jobs are processed in the order they were received, following the First-In-First-Out (FIFO) principle. This means that the first job to arrive is the first to be printed. Using a queue: 1. When a user sends a print job, it is added to the end of the queue. 2. The printer dequeues jobs from the front of the queue and processes them one by one. 3. New jobs are continuously added to the back of the queue as users send print requests. This approach ensures fairness in print job processing, as all jobs are processed in the order they were received. It prevents any single user from monopolizing the printer's resources by submitting multiple jobs simultaneously. In contrast, using a stack in this scenario would result in the Last-In-First-Out (LIFO) principle, where the most recent print job sent to the printer would be processed first. This would not be ideal in the example above, as it would prioritize newer jobs over older ones, potentially causing delays for users who submitted their print requests earlier.

Assuming all the supporting code that is necessary is available, what operation is the code below performing on a linked list? void function (int val, int newVal) { if (head == nullptr) { return; } Node* current = head;Node* prev = nullptr; while (current != nullptr && current->data != val) { prev = current; current = current->next; } if (current == nullptr) { return; } Node* newNode = new Node(newVal); if (prev == nullptr) { newNode->next = head; head = newNode; } else { prev->next = newNode; newNode->next = current; } }

This code is a function that takes 2 values. It traverses the list to find the first value and creates a new node with the second value and inserts it in the list before the node with the first value that was specified. It also does the usual checks to make sure the list is not empty and ensures that all the pointers are updated correctly.

Double Hashing

Use an additional function to determine where to place data

Separate Chaining

Use an auxillary linked list to store collided data

Which of the following operations does not have a time complexity of O(1)?

Using a collision resolution strategy


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