# Power of 2 # # Given an integer n, return true if it is a power of two. Otherwise, return false. # # An integer n is a power of two, if there exists an integer x such that n == 2^x. # # Example 1: # Input: n = 1 # Output: true # Explanation: 2^0 = 1 # # Example 2: # Input: n = 16 # Output: true # Explanation: 2^4 = 16 # # Example 3: # Input: n = 3 # Output: false # # Example 4: # Input: n = 4 # Output: true # # Example 5: # Input: n = 5 # Output: false # # Constraints: -231 <= n <= 231 - 1 # @param {Integer} n # @return {Boolean} # # Approach 1: Recursion # # Time Complexity: O(logn) # def is_power_of_two(n) if n == 1 true elsif n % 2 == 0 is_power_of_two(n / 2) else false end end n = 1 # Output: true puts is_power_of_two(n) n = 16 # Output: true puts is_power_of_two(n) n = 3 # Output: false puts is_power_of_two(n) n = 4 # Output: true puts is_power_of_two(n) n = 5 # Output: false puts is_power_of_two(n) # # Approach 2: Without recursion # # Time Complexity: O(n) # def is_power_of_two(n) while n % 2 == 0 && n != 0 n /= 2 end n == 1 end n = 1 # Output: true puts is_power_of_two(n) n = 16 # Output: true puts is_power_of_two(n) n = 3 # Output: false puts is_power_of_two(n) n = 4 # Output: true puts is_power_of_two(n) n = 5 # Output: false puts is_power_of_two(n) # # Approach 3: Using Math library # # Time Complexity: O(1) # def is_power_of_two(n) result_exponent = Math.log(n) / Math.log(2) result_exponent % 1 == 0 end n = 1 # Output: true puts is_power_of_two(n) n = 16 # Output: true puts is_power_of_two(n) n = 3 # Output: false puts is_power_of_two(n) n = 4 # Output: true puts is_power_of_two(n) n = 5 # Output: false puts is_power_of_two(n)