From 2841c11da1cac9d5e94dd72f6cd301561baad012 Mon Sep 17 00:00:00 2001 From: Aviv Faraj <73610201+avivfaraj@users.noreply.github.com> Date: Mon, 6 Sep 2021 13:58:46 -0400 Subject: [PATCH] Deleted duplicate file --- maths/gamma_recursive.py | 83 ---------------------------------------- 1 file changed, 83 deletions(-) delete mode 100644 maths/gamma_recursive.py diff --git a/maths/gamma_recursive.py b/maths/gamma_recursive.py deleted file mode 100644 index e7e2c70c7..000000000 --- a/maths/gamma_recursive.py +++ /dev/null @@ -1,83 +0,0 @@ -""" -Gamma function is a very useful tool in physics. -It helps calculating complex integral in a convenient way. -for more info: https://en.wikipedia.org/wiki/Gamma_function -""" - -# Importing packages -from math import pi, sqrt -from re import match -from typing import Union - - -def gamma(num: Union[int, float]) -> Union[int, float]: - """ - Calculates the value of Gamma function of num - where num is either an integer (1,2,3..) or a half-integer (0.5,1.5,2.5...). - Implemented using recursion - Examples: - >>> Gamma of: 0.5 - √π - >>> Gamma of: 2 - 1 - >>> Gamma of: 3.5 - 1.875√π - """ - if num == 1: - return 1 - elif num == 0.5: - return sqrt(pi) - elif num > 1: - return (num - 1) * gamma(num - 1) - # Error - return -2 - - -def test_gamma() -> None: - """ - >>> test_gamma() - """ - assert sqrt(pi) == gamma(0.5) - assert 1 == gamma(1) - assert 1 == gamma(2) - - -if __name__ == "__main__": - # Initialize boolean - number = True - # Get input from user - input_ = input("Gamma of: ") - # Ensure valid input - try: - # Ensure input matches half-integer (float) pattern - if match(r"^[0-9]*\.5$", input_): - # Convert string to float - num = float(input_) - # Ensure input matches an integer pattern - elif match(r"^[1-9][0-9]*$", input_): - # Convert string to int - num = int(input_) - # Input is not a valid number - else: - # raise an error - raise ValueError - # Ensure print an error message - except ValueError: - print("Error: Input must be an integer or an half-integer!") - number = False - finally: - # Ensure input is a valid number - if number: - print(f"\u0393({num}) = ", end="") - # Ensure input is an integer - if isinstance(gamma(num), int): - # Print result - print(gamma(num)) - # Otherwise print results with √π (gamma of 0.5 is √π) - # Therefore all results will be a number times √π - else: - results = f"{gamma(num) / sqrt(pi):.4f}" - results = results.rstrip("0").rstrip(".") - if results == "1": - results = "" - print(results + "\u221A\u03c0")