Python/project_euler/problem_057/sol1.py

"""
Project Euler Problem 57: https://projecteuler.net/problem=57
It is possible to show that the square root of two can be expressed as an infinite
continued fraction.

sqrt(2) = 1 + 1 / (2 + 1 / (2 + 1 / (2 + ...)))

By expanding this for the first four iterations, we get:
1 + 1 / 2 = 3 / 2 = 1.5
1 + 1 / (2 + 1 / 2} = 7 / 5 = 1.4
1 + 1 / (2 + 1 / (2 + 1 / 2)) = 17 / 12 = 1.41666...
1 + 1 / (2 + 1 / (2 + 1 / (2 + 1 / 2))) = 41/ 29 = 1.41379...

The next three expansions are 99/70, 239/169, and 577/408, but the eighth expansion,
1393/985, is the first example where the number of digits in the numerator exceeds
the number of digits in the denominator.

In the first one-thousand expansions, how many fractions contain a numerator with
more digits than the denominator?
"""


def solution(n: int = 1000) -> int:
    """
    returns number of fractions containing a numerator with more digits than
    the denominator in the first n expansions.
    >>> solution(14)
    2
    >>> solution(100)
    15
    >>> solution(10000)
    1508
    """
    prev_numerator, prev_denominator = 1, 1
    result = []
    for i in range(1, n + 1):
        numerator = prev_numerator + 2 * prev_denominator
        denominator = prev_numerator + prev_denominator
        if len(str(numerator)) > len(str(denominator)):
            result.append(i)
        prev_numerator = numerator
        prev_denominator = denominator

    return len(result)


if __name__ == "__main__":
    print(f"{solution() = }")
Project Euler 57 - Square root convergents (#3259) * include solution for problem 57 * fix line to long errors * update filenames and code to comply with new regulations * more descriptive local variables 2020-10-16 15:47:35 +00:00			`"""`
			`Project Euler Problem 57: https://projecteuler.net/problem=57`
			`It is possible to show that the square root of two can be expressed as an infinite`
			`continued fraction.`

			`sqrt(2) = 1 + 1 / (2 + 1 / (2 + 1 / (2 + ...)))`

			`By expanding this for the first four iterations, we get:`
			`1 + 1 / 2 = 3 / 2 = 1.5`
			`1 + 1 / (2 + 1 / 2} = 7 / 5 = 1.4`
			`1 + 1 / (2 + 1 / (2 + 1 / 2)) = 17 / 12 = 1.41666...`
			`1 + 1 / (2 + 1 / (2 + 1 / (2 + 1 / 2))) = 41/ 29 = 1.41379...`

			`The next three expansions are 99/70, 239/169, and 577/408, but the eighth expansion,`
			`1393/985, is the first example where the number of digits in the numerator exceeds`
			`the number of digits in the denominator.`

			`In the first one-thousand expansions, how many fractions contain a numerator with`
			`more digits than the denominator?`
			`"""`


			`def solution(n: int = 1000) -> int:`
			`"""`
			`returns number of fractions containing a numerator with more digits than`
			`the denominator in the first n expansions.`
			`>>> solution(14)`
			`2`
			`>>> solution(100)`
			`15`
			`>>> solution(10000)`
			`1508`
			`"""`
			`prev_numerator, prev_denominator = 1, 1`
			`result = []`
			`for i in range(1, n + 1):`
			`numerator = prev_numerator + 2 * prev_denominator`
			`denominator = prev_numerator + prev_denominator`
			`if len(str(numerator)) > len(str(denominator)):`
			`result.append(i)`
			`prev_numerator = numerator`
			`prev_denominator = denominator`

			`return len(result)`


			`if __name__ == "__main__":`
			`print(f"{solution() = }")`