"""
Created on Thu Oct 5 16:44:23 2017
@author: Christian Bender
This Python library contains some useful functions to deal with
prime numbers and whole numbers.
Overview:
is_prime(number)
sieve_er(N)
get_prime_numbers(N)
prime_factorization(number)
greatest_prime_factor(number)
smallest_prime_factor(number)
get_prime(n)
get_primes_between(pNumber1, pNumber2)
----
is_even(number)
is_odd(number)
gcd(number1, number2) // greatest common divisor
kg_v(number1, number2) // least common multiple
get_divisors(number) // all divisors of 'number' inclusive 1, number
is_perfect_number(number)
NEW-FUNCTIONS
simplify_fraction(numerator, denominator)
factorial (n) // n!
fib (n) // calculate the n-th fibonacci term.
-----
goldbach(number) // Goldbach's assumption
"""
from math import sqrt
def is_prime(number: int) -> bool:
"""
input: positive integer 'number'
returns true if 'number' is prime otherwise false.
"""
assert isinstance(number, int) and (
number >= 0
), "'number' must been an int and positive"
status = True
if number <= 1:
status = False
for divisor in range(2, int(round(sqrt(number))) + 1):
if number % divisor == 0:
status = False
break
assert isinstance(status, bool), "'status' must been from type bool"
return status
def sieve_er(n):
"""
input: positive integer 'N' > 2
returns a list of prime numbers from 2 up to N.
This function implements the algorithm called
sieve of erathostenes.
"""
assert isinstance(n, int) and (n > 2), "'N' must been an int and > 2"
begin_list = list(range(2, n + 1))
ans = []
for i in range(len(begin_list)):
for j in range(i + 1, len(begin_list)):
if (begin_list[i] != 0) and (begin_list[j] % begin_list[i] == 0):
begin_list[j] = 0
ans = [x for x in begin_list if x != 0]
assert isinstance(ans, list), "'ans' must been from type list"
return ans
def get_prime_numbers(n):
"""
input: positive integer 'N' > 2
returns a list of prime numbers from 2 up to N (inclusive)
This function is more efficient as function 'sieveEr(...)'
"""
assert isinstance(n, int) and (n > 2), "'N' must been an int and > 2"
ans = []
for number in range(2, n + 1):
if is_prime(number):
ans.append(number)
assert isinstance(ans, list), "'ans' must been from type list"
return ans
def prime_factorization(number):
"""
input: positive integer 'number'
returns a list of the prime number factors of 'number'
"""
assert isinstance(number, int) and number >= 0, "'number' must been an int and >= 0"
ans = []
factor = 2
quotient = number
if number in {0, 1}:
ans.append(number)
elif not is_prime(number):
while quotient != 1:
if is_prime(factor) and (quotient % factor == 0):
ans.append(factor)
quotient /= factor
else:
factor += 1
else:
ans.append(number)
assert isinstance(ans, list), "'ans' must been from type list"
return ans
def greatest_prime_factor(number):
"""
input: positive integer 'number' >= 0
returns the greatest prime number factor of 'number'
"""
assert isinstance(number, int) and (
number >= 0
), "'number' bust been an int and >= 0"
ans = 0
prime_factors = prime_factorization(number)
ans = max(prime_factors)
assert isinstance(ans, int), "'ans' must been from type int"
return ans
def smallest_prime_factor(number):
"""
input: integer 'number' >= 0
returns the smallest prime number factor of 'number'
"""
assert isinstance(number, int) and (
number >= 0
), "'number' bust been an int and >= 0"
ans = 0
prime_factors = prime_factorization(number)
ans = min(prime_factors)
assert isinstance(ans, int), "'ans' must been from type int"
return ans
def is_even(number):
"""
input: integer 'number'
returns true if 'number' is even, otherwise false.
"""
assert isinstance(number, int), "'number' must been an int"
assert isinstance(number % 2 == 0, bool), "compare bust been from type bool"
return number % 2 == 0
def is_odd(number):
"""
input: integer 'number'
returns true if 'number' is odd, otherwise false.
"""
assert isinstance(number, int), "'number' must been an int"
assert isinstance(number % 2 != 0, bool), "compare bust been from type bool"
return number % 2 != 0
def goldbach(number):
"""
Goldbach's assumption
input: a even positive integer 'number' > 2
returns a list of two prime numbers whose sum is equal to 'number'
"""
assert (
isinstance(number, int) and (number > 2) and is_even(number)
), "'number' must been an int, even and > 2"
ans = []
prime_numbers = get_prime_numbers(number)
len_pn = len(prime_numbers)
i = 0
j = None
loop = True
while i < len_pn and loop:
j = i + 1
while j < len_pn and loop:
if prime_numbers[i] + prime_numbers[j] == number:
loop = False
ans.append(prime_numbers[i])
ans.append(prime_numbers[j])
j += 1
i += 1
assert (
isinstance(ans, list)
and (len(ans) == 2)
and (ans[0] + ans[1] == number)
and is_prime(ans[0])
and is_prime(ans[1])
), "'ans' must contains two primes. And sum of elements must been eq 'number'"
return ans
def gcd(number1, number2):
"""
Greatest common divisor
input: two positive integer 'number1' and 'number2'
returns the greatest common divisor of 'number1' and 'number2'
"""
assert (
isinstance(number1, int)
and isinstance(number2, int)
and (number1 >= 0)
and (number2 >= 0)
), "'number1' and 'number2' must been positive integer."
rest = 0
while number2 != 0:
rest = number1 % number2
number1 = number2
number2 = rest
assert isinstance(number1, int) and (
number1 >= 0
), "'number' must been from type int and positive"
return number1
def kg_v(number1, number2):
"""
Least common multiple
input: two positive integer 'number1' and 'number2'
returns the least common multiple of 'number1' and 'number2'
"""
assert (
isinstance(number1, int)
and isinstance(number2, int)
and (number1 >= 1)
and (number2 >= 1)
), "'number1' and 'number2' must been positive integer."
ans = 1
if number1 > 1 and number2 > 1:
prime_fac_1 = prime_factorization(number1)
prime_fac_2 = prime_factorization(number2)
elif number1 == 1 or number2 == 1:
prime_fac_1 = []
prime_fac_2 = []
ans = max(number1, number2)
count1 = 0
count2 = 0
done = []
for n in prime_fac_1:
if n not in done:
if n in prime_fac_2:
count1 = prime_fac_1.count(n)
count2 = prime_fac_2.count(n)
for _ in range(max(count1, count2)):
ans *= n
else:
count1 = prime_fac_1.count(n)
for _ in range(count1):
ans *= n
done.append(n)
for n in prime_fac_2:
if n not in done:
count2 = prime_fac_2.count(n)
for _ in range(count2):
ans *= n
done.append(n)
assert isinstance(ans, int) and (
ans >= 0
), "'ans' must been from type int and positive"
return ans
def get_prime(n):
"""
Gets the n-th prime number.
input: positive integer 'n' >= 0
returns the n-th prime number, beginning at index 0
"""
assert isinstance(n, int) and (n >= 0), "'number' must been a positive int"
index = 0
ans = 2
while index < n:
index += 1
ans += 1
while not is_prime(ans):
ans += 1
assert isinstance(ans, int) and is_prime(
ans
), "'ans' must been a prime number and from type int"
return ans
def get_primes_between(p_number_1, p_number_2):
"""
input: prime numbers 'pNumber1' and 'pNumber2'
pNumber1 < pNumber2
returns a list of all prime numbers between 'pNumber1' (exclusive)
and 'pNumber2' (exclusive)
"""
assert (
is_prime(p_number_1) and is_prime(p_number_2) and (p_number_1 < p_number_2)
), "The arguments must been prime numbers and 'pNumber1' < 'pNumber2'"
number = p_number_1 + 1
ans = []
while not is_prime(number):
number += 1
while number < p_number_2:
ans.append(number)
number += 1
while not is_prime(number):
number += 1
assert (
isinstance(ans, list)
and ans[0] != p_number_1
and ans[len(ans) - 1] != p_number_2
), "'ans' must been a list without the arguments"
return ans
def get_divisors(n):
"""
input: positive integer 'n' >= 1
returns all divisors of n (inclusive 1 and 'n')
"""
assert isinstance(n, int) and (n >= 1), "'n' must been int and >= 1"
ans = []
for divisor in range(1, n + 1):
if n % divisor == 0:
ans.append(divisor)
assert ans[0] == 1 and ans[len(ans) - 1] == n, "Error in function getDivisiors(...)"
return ans
def is_perfect_number(number):
"""
input: positive integer 'number' > 1
returns true if 'number' is a perfect number otherwise false.
"""
assert isinstance(number, int) and (
number > 1
), "'number' must been an int and >= 1"
divisors = get_divisors(number)
assert (
isinstance(divisors, list)
and (divisors[0] == 1)
and (divisors[len(divisors) - 1] == number)
), "Error in help-function getDivisiors(...)"
return sum(divisors[:-1]) == number
def simplify_fraction(numerator, denominator):
"""
input: two integer 'numerator' and 'denominator'
assumes: 'denominator' != 0
returns: a tuple with simplify numerator and denominator.
"""
assert (
isinstance(numerator, int)
and isinstance(denominator, int)
and (denominator != 0)
), "The arguments must been from type int and 'denominator' != 0"
gcd_of_fraction = gcd(abs(numerator), abs(denominator))
assert (
isinstance(gcd_of_fraction, int)
and (numerator % gcd_of_fraction == 0)
and (denominator % gcd_of_fraction == 0)
), "Error in function gcd(...,...)"
return (numerator // gcd_of_fraction, denominator // gcd_of_fraction)
def factorial(n):
"""
input: positive integer 'n'
returns the factorial of 'n' (n!)
"""
assert isinstance(n, int) and (n >= 0), "'n' must been a int and >= 0"
ans = 1
for factor in range(1, n + 1):
ans *= factor
return ans
def fib(n):
"""
input: positive integer 'n'
returns the n-th fibonacci term , indexing by 0
"""
assert isinstance(n, int) and (n >= 0), "'n' must been an int and >= 0"
tmp = 0
fib1 = 1
ans = 1
for _ in range(n - 1):
tmp = ans
ans += fib1
fib1 = tmp
return ans