HACKTOBERFEST - Added solution to Euler 64. (#3706)

* Added solution to Euler 64. Added Python solution to Project Euler Problem 64. Added a folder problem_064. Added __init__.py file. Added sol1.py file. * Update sol1.py Made formatting changes as mentioned by pre-commit * Update sol1.py Minor changes to variable naming and function calling as mentioned by @ruppysuppy * Update sol1.py Changes to function call as mentioned by @cclauss
2024-11-23 21:11:08 +00:00 · 2020-11-02 22:18:14 -05:00 · 2020-11-02 22:18:14 -05:00 · 29d0fbb0e0
commit 29d0fbb0e0
parent ff00bfa0ab
2 changed files with 77 additions and 0 deletions
--- a/project_euler/problem_064/init.py
+++ b/project_euler/problem_064/init.py
--- a/project_euler/problem_064/sol1.py
+++ b/project_euler/problem_064/sol1.py
@ -0,0 +1,77 @@
 """
 Project Euler Problem 64: https://projecteuler.net/problem=64
 All square roots are periodic when written as continued fractions.
 For example, let us consider sqrt(23).
 It can be seen that the sequence is repeating.
 For conciseness, we use the notation sqrt(23)=[4;(1,3,1,8)],
 to indicate that the block (1,3,1,8) repeats indefinitely.
 Exactly four continued fractions, for N<=13, have an odd period.
 How many continued fractions for N<=10000 have an odd period?
 References:
 - https://en.wikipedia.org/wiki/Continued_fraction
 """
 from math import floor, sqrt
 def continuous_fraction_period(n: int) -> int:
    """
    Returns the continued fraction period of a number n.
    >>> continuous_fraction_period(2)
    1
    >>> continuous_fraction_period(5)
    1
    >>> continuous_fraction_period(7)
    4
    >>> continuous_fraction_period(11)
    2
    >>> continuous_fraction_period(13)
    5
    """
    numerator = 0.0
    denominator = 1.0
    ROOT = int(sqrt(n))
    integer_part = ROOT
    period = 0
    while integer_part != 2 * ROOT:
        numerator = denominator * integer_part - numerator
        denominator = (n - numerator ** 2) / denominator
        integer_part = int((ROOT + numerator) / denominator)
        period += 1
    return period
 def solution(n: int = 10000) -> int:
    """
    Returns the count of numbers <= 10000 with odd periods.
    This function calls continuous_fraction_period for numbers which are
    not perfect squares.
    This is checked in if sr - floor(sr) != 0 statement.
    If an odd period is returned by continuous_fraction_period,
    count_odd_periods is increased by 1.
    >>> solution(2)
    1
    >>> solution(5)
    2
    >>> solution(7)
    2
    >>> solution(11)
    3
    >>> solution(13)
    4
    """
    count_odd_periods = 0
    for i in range(2, n + 1):
        sr = sqrt(i)
        if sr - floor(sr) != 0:
            if continuous_fraction_period(i) % 2 == 1:
                count_odd_periods += 1
    return count_odd_periods
 if __name__ == "__main__":
    print(f"{solution(int(input().strip()))}")