Program to Print Butterfly Pattern (Star Pattern) Last Updated : 10 Feb, 2024 Summarize Comments Improve Suggest changes Share Like Article Like Report Given an integer N, print N rows of Butterfly pattern. Examples: Input: 3Output: * *** ********* *** * Input: 5Output: * *** ***** ******* ***************** ******* ***** *** * Approach: The problem can be solved using three nested loops inside an outer loop. The outer loop will run for the rows, the first inner loop will print the stars, the second inner loop will print the spaces and the third inner loop will again print the stars. Step-by-step algorithm: Maintain two variable spaces = 2 * N - 1 and stars = 0 to store the number of spaces and stars for each row.Run an outer loop from i = 1 to the number of rows (2 * N - 1).If we are in the upper half of the butterfly, decrease number of spaces by 2 and increase number of stars by 1.If we are in the lower half of the butterfly, increase number of spaces by 2 and decrease number of stars by 1.Run an inner loop from j = 1 to stars.Print an asterisk in each iteration of the inner loop.Run an inner loop from j = 1 to spaces.Print a space in each iteration of the inner loop.Run an inner loop from j = 1 to stars.Print an asterisk in each iteration of the inner loop.Print a newline character ("\n") to move to the next row.After N iterations, we will have the right half pyramid pattern. Below is the implementation of the above approach: C++ #include <iostream> using namespace std; int main() { // Number of rows int N = 5; // Variables to store number of spaces and stars int spaces = 2 * N - 1; int stars = 0; // The outer loop will run for (2 * N - 1) times for (int i = 1; i <= 2 * N - 1; i++) { // Upper half of the butterfly if (i <= N) { spaces = spaces - 2; stars++; } // Lower half of the butterfly else { spaces = spaces + 2; stars--; } // Print stars for (int j = 1; j <= stars; j++) { cout << "*"; } // Print spaces for (int j = 1; j <= spaces; j++) { cout << " "; } // Print stars for (int j = 1; j <= stars; j++) { if (j != N) { cout << "*"; } } cout << "\n"; } return 0; } Java public class ButterflyPattern { public static void main(String[] args) { // Number of rows int N = 5; // Variables to store number of spaces and stars int spaces = 2 * N - 1; int stars = 0; // The outer loop will run for (2 * N - 1) times for (int i = 1; i <= 2 * N - 1; i++) { // Upper half of the butterfly if (i <= N) { spaces = spaces - 2; stars++; } // Lower half of the butterfly else { spaces = spaces + 2; stars--; } // Print stars for (int j = 1; j <= stars; j++) { System.out.print("*"); } // Print spaces for (int j = 1; j <= spaces; j++) { System.out.print(" "); } // Print stars for (int j = 1; j <= stars; j++) { if (j != N) { System.out.print("*"); } } System.out.println(); } } } //this code is contributed by Adarsh Python3 # Number of rows N = 5 # Variables to store number of spaces and stars spaces = 2 * N - 1 stars = 0 # The outer loop will run for (2 * N - 1) times for i in range(1, 2 * N): # Upper half of the butterfly if i <= N: spaces = spaces - 2 stars += 1 # Lower half of the butterfly else: spaces = spaces + 2 stars -= 1 # Print stars for j in range(1, stars + 1): print("*", end="") # Print spaces for j in range(1, spaces + 1): print(" ", end="") # Print stars for j in range(1, stars + 1): if j != N: print("*", end="") print() # Move to the next line C# using System; class Program { static void Main() { // Number of rows int N = 5; // Variables to store the number of spaces and stars int spaces = 2 * N - 1; int stars = 0; // The outer loop will run for (2 * N - 1) times for (int i = 1; i <= 2 * N - 1; i++) { // Upper half of the butterfly if (i <= N) { spaces = spaces - 2; stars++; } // Lower half of the butterfly else { spaces = spaces + 2; stars--; } // Print stars for (int j = 1; j <= stars; j++) { Console.Write("*"); } // Print spaces for (int j = 1; j <= spaces; j++) { Console.Write(" "); } // Print stars for (int j = 1; j <= stars; j++) { if (j != N) { Console.Write("*"); } } Console.WriteLine(); } } } JavaScript // Number of rows const N = 5; // Variables to store number of spaces and stars let spaces = 2 * N - 1; let stars = 0; // The outer loop will run for (2 * N - 1) times for (let i = 1; i <= 2 * N - 1; i++) { // Upper half of the butterfly if (i <= N) { spaces = spaces - 2; stars++; } // Lower half of the butterfly else { spaces = spaces + 2; stars--; } // Print stars for (let j = 1; j <= stars; j++) { process.stdout.write("*"); } // Print spaces for (let j = 1; j <= spaces; j++) { process.stdout.write(" "); } // Print stars for (let j = 1; j <= stars; j++) { if (j !== N) { process.stdout.write("*"); } } process.stdout.write("\n"); } Output* * ** ** *** *** **** **** ********* **** **** *** *** ** ** * *Time Complexity: O(N^2), where N is the number of rows in the pattern.Auxiliary Space: O(1) Comment More infoAdvertise with us Next Article Program to Print Butterfly Pattern (Star Pattern) M mrityuanjay8vae Follow Improve Article Tags : DSA pattern-printing Practice Tags : pattern-printing Similar Reads DSA Tutorial - Learn Data Structures and Algorithms DSA (Data Structures and Algorithms) is the study of organizing data efficiently using data structures like arrays, stacks, and trees, paired with step-by-step procedures (or algorithms) to solve problems effectively. 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