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main
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 notkshitij
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ff72fdf47c
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notkshitij
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028eb10661
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notkshitij
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e8327327d4
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notkshitij
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d53169d89f
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notkshitij
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ecd6ecae64
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notkshitij
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e051c585bc
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notkshitij
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f24c40a32e
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notkshitij
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158b164fa4
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notkshitij
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5c39b18d49
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notkshitij
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21eac5a235
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notkshitij
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ab568b290b
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notkshitij
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1cd69b32e7
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notkshitij
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fbaf0330da
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notkshitij
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c27d224e93
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notkshitij
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bf4f5beb17
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notkshitij
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a39a53ea90
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notkshitij
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2d45b17899
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@@ -3,24 +3,34 @@
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#include <iostream>
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using namespace std;
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int recursiveSteps = 0;
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int iterativeSteps = 0;
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// Recursive function for Fibonacci
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int fibRecursive(int n) {
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recursiveSteps++;
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if (n <= 1)
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return n; // Base case: fib(0)=0, fib(1)=1
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return n;
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return fibRecursive(n - 1) + fibRecursive(n - 2);
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}
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// Non-recursive (Iterative) Fibonacci
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int fibIterative(int n) {
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if (n <= 1)
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return n;
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void fibIterative(int n) {
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if (n <= 0)
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return;
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int prev = 0, curr = 1, next;
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for (int i = 2; i <= n; i++) {
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cout << prev << " ";
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if (n == 1)
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return;
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cout << curr << " ";
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for (int i = 2; i < n; i++) {
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next = prev + curr;
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cout << next << " ";
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prev = curr;
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curr = next;
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iterativeSteps++;
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}
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return curr;
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}
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int main() {
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@@ -29,22 +39,26 @@ int main() {
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cin >> n;
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cout << "\nFibonacci Series using Recursion: ";
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for (int i = 0; i < n; i++)
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for (int i = 0; i < n; i++) {
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cout << fibRecursive(i) << " ";
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}
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cout << "\nTotal Recursive Steps: " << recursiveSteps;
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cout << "\nFibonacci Series using Iteration: ";
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for (int i = 0; i < n; i++)
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cout << fibIterative(i) << " ";
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cout << "\n\nFibonacci Series using Iteration: ";
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fibIterative(n);
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cout << "\nTotal Iterative Steps: " << iterativeSteps;
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cout << endl;
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return 0;
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}
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// SAMPLE OUTPUT
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// SAMPLE OUTOUT
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/*
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* $ ./a.out
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* Enter the number of terms: 5
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*
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* Fibonacci Series using Recursion: 0 1 1 2 3
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* Total Recursive Steps: 19
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*
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* Fibonacci Series using Iteration: 0 1 1 2 3
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* Total Iterative Steps: 3
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*/
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@@ -1,4 +1,4 @@
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// Code-A2 (Huffman)
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// Code-A2 (Huffman Coding)
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#include <iostream>
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#include <queue>
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Executable → Regular
+39
-22
@@ -1,33 +1,50 @@
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# Code-A1 (Fibonacci)
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# Problem Statement: Write a program non-recursive and recursive program to calculate Fibonacci numbers and analyze their time and space complexity.
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# Non-recursion
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def fibonacci(n):
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fib_series = []
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a = 0
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b = 1
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# Initalize global variables
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iteration_counter = 0
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recursion_counter = 0
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# Iteration
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def fibonacci_iteration(n):
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fib_series = [] # For storing Fibonacci series
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previous = 0 # Previous
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current = 1 # Next
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global iteration_counter # Global iteration counter
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iteration_counter = 0 # Initialize global iteration counter to 0
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for i in range(n):
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fib_series.append(a)
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a, b = b, a + b
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fib_series.append(previous)
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previous, current = current, previous + current
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iteration_counter += 1
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return fib_series
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# Recursion
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def fibonacci_recursive(n):
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if n <= 0:
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return []
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elif n == 1:
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return [0]
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elif n == 2:
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return [0, 1]
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else:
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fib_series = fibonacci_recursive(n - 1) # Get the series up to n-1
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fib_series.append(fib_series[-1] + fib_series[-2]) # Append the next Fibonacci number
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return fib_series
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def fibonacci_recursion(n):
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global recursion_counter # Global recursion counter
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recursion_counter += 1 # Increment recursion counter for each call
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if (n <= 0): # Handle n less than or equal to 0
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return 0
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elif (n <= 1): # Handle n less than or equal to 1
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return n
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else: # Recursive call
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return fibonacci_recursion(n - 1) + fibonacci_recursion(n - 2)
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# Non-recursion
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n = int(input("Enter total numbers to print in fibonacci series:\t"))
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print("Fibonacci Series (non-recusive):\t", fibonacci(n))
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# Recursion
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print("Fibonacci Series (recusive):\t\t", fibonacci_recursive(n))
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# Fibonacci using iteration
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fib_series = fibonacci_iteration(n)
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print(f"Fibonacci using iteration:\t{fib_series}")
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print(f"Iteration counter:\t{iteration_counter}| Time Complexity: O(n) (linear growth)")
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print("="*80)
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# Fibonacci using recursion
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fib_series = []
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for i in range(n):
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fib_series.append(fibonacci_recursion(i))
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print(f"Fibonacci using recursion:\t{fib_series}")
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print(f"Recursion counter:\t{recursion_counter} | Time Complexity: O(2^n) (exponential growth)")
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@@ -0,0 +1,46 @@
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# Problem Statement: Write a program non-recursive and recursive program to calculate Fibonacci numbers and analyze their time and space complexity.
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## NOTE: THIS IS A HEAVILY OPTIMIZED CODE FOR FIBONACCI.
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## NUMBER OF RECURSION CALLS (IN RECURSION) ARE LOWER THAN NUMBER OF ITERATIONS (IN ITERATION FUNCTION)
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iteration_counter = 0
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recursion_counter = 0
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# Non-recursion
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def fibonacci(n):
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global iteration_counter
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fib_series = []
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a = 0
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b = 1
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for i in range(n):
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fib_series.append(a)
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a, b = b, a + b
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iteration_counter += 1
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return fib_series
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# Recursion
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def fibonacci_recursive(n):
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global recursion_counter
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recursion_counter += 1
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if n <= 0:
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return []
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elif n == 1:
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return [0]
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elif n == 2:
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return [0, 1]
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else:
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fib_series = fibonacci_recursive(n - 1) # Get the series up to n-1
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fib_series.append(fib_series[-1] + fib_series[-2]) # Append the next Fibonacci number
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return fib_series
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# Non-recursion
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n = int(input("Enter total numbers to print in fibonacci series:\t"))
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print("Fibonacci Series (non-recusive):\t", fibonacci(n))
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print("Iteration counter:\t", iteration_counter)
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# Recursion
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print("Fibonacci Series (recusive):\t\t", fibonacci_recursive(n))
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print("Recursion counter:\t", recursion_counter)
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@@ -0,0 +1,95 @@
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# Code-A2 (Huffman Coding)
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import heapq
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# Node class for Huffman Tree
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class Node:
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def __init__(self, char, freq):
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self.char = char
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self.freq = freq
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self.left = None
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self.right = None
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# Comparison function for priority queue
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def __lt__(self, other):
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return self.freq < other.freq
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# Function to build Huffman Tree
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def build_huffman_tree(char_freq):
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heap = [Node(ch, freq) for ch, freq in char_freq.items()]
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heapq.heapify(heap)
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while len(heap) > 1:
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# Pick two smallest nodes (greedy choice)
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left = heapq.heappop(heap)
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right = heapq.heappop(heap)
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# Merge them into a new node
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merged = Node(None, left.freq + right.freq)
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merged.left = left
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merged.right = right
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heapq.heappush(heap, merged)
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return heap[0]
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# Function to generate Huffman codes
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def generate_codes(root, current_code="", codes={}):
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if root is None:
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return
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if root.char is not None:
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codes[root.char] = current_code
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generate_codes(root.left, current_code + "0", codes)
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generate_codes(root.right, current_code + "1", codes)
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return codes
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# Main program
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text = input("Enter text to encode: ")
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# Step 1: Calculate frequency of each character
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freq = {}
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for ch in text:
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freq[ch] = freq.get(ch, 0) + 1
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# Step 2: Build Huffman Tree using greedy approach
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root = build_huffman_tree(freq)
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# Step 3: Generate Huffman Codes
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codes = generate_codes(root)
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# Step 4: Encode the text
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encoded_text = "".join(codes[ch] for ch in text)
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# Step 5: Display results
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print("\nCharacter | Frequency | Huffman Code")
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print("------------------------------------")
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for ch in freq:
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print(f" {ch!r} | {freq[ch]} | {codes[ch]}")
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print("\nEncoded Text:", encoded_text)
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# SAMPLE OUTPUT
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"""
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Enter text to encode: lord kska git
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Character | Frequency | Huffman Code
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------------------------------------
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'l' | 1 | 1100
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'o' | 1 | 1101
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'r' | 1 | 001
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'd' | 1 | 1010
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' ' | 2 | 011
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'k' | 2 | 100
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's' | 1 | 000
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'a' | 1 | 010
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'g' | 1 | 1011
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'i' | 1 | 1111
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't' | 1 | 1110
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Encoded Text: 110011010011010011100000100010011101111111110
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"""
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@@ -0,0 +1,74 @@
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# Code-A5 (N-Queen)
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def print_board(board, n):
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for i in range(n):
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for j in range(n):
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print(board[i][j], end=" ")
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print()
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print() # blank line between solutions
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def is_safe(board, row, col, n):
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# Check column
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for i in range(row):
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if board[i][col] == 1:
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return False
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# Check upper-left diagonal
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i, j = row, col
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while i >= 0 and j >= 0:
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if board[i][j] == 1:
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return False
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i -= 1
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j -= 1
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# Check upper-right diagonal
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i, j = row, col
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while i >= 0 and j < n:
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if board[i][j] == 1:
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return False
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i -= 1
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j += 1
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return True
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def solve_n_queens(board, row, n):
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if row == n:
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print_board(board, n)
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return True
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res = False
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for col in range(n):
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if is_safe(board, row, col, n):
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board[row][col] = 1
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res = solve_n_queens(board, row + 1, n) or res
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board[row][col] = 0 # backtrack
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return res
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# Main program
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n = int(input("Enter number of queens: "))
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board = [[0 for _ in range(n)] for _ in range(n)]
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print(f"\nSolutions for {n}-Queens Problem:\n")
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if not solve_n_queens(board, 0, n):
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print("No solution exists!")
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# SAMPLE OUTPUT
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"""
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Enter number of queens: 4
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Solutions for 4-Queens Problem:
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0 1 0 0
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0 0 0 1
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1 0 0 0
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0 0 1 0
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0 0 1 0
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1 0 0 0
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0 0 0 1
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0 1 0 0
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"""
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@@ -25,6 +25,7 @@ This repository contains valuable resources for the Design and Analysis of Algor
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> [!NOTE]
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> C++ versions of all codes are available in the [./Codes/C++](./Codes/C++) directory.
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> Python version of some codes are available in [./Codes/Python](./Codes/Python) directory.
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### Practical
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@@ -40,6 +41,7 @@ This repository contains valuable resources for the Design and Analysis of Algor
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- [END-SEM](Question%20Papers/END-SEM)
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### [IN-SEM PYQ Answers](Notes/IN-SEM%20PYQ%20Answers)
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### [END-SEM PYQ Answers](Notes/END-SEM%20PYQ%20Answers)
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---
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Reference in New Issue
Block a user