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Thanks for the update on checking through solutions, and thanks in general for all the work you've put into this community!
Would just like to clarify: what are the valid decompressed strings? For an input of a333a3, should we return 2 (either a333 a3 or a3 33 a3) or 1 (since a333 a3 isn't a possible compression -- it would be a336 instead)? Do we have to handle cases like a00010, and if so, how?
The first one would give 2 since it doesnt validate what its supposed to have been when it was compressed
For a00010 that one would be a0 00 10 or a000 10 or a0 0010 or a00 010 or a00010 for 5 since it doesnt validate
So every list of strings, where each string is some character followed by one or more digits, is a distinct, valid decompressing option. Thanks for clarifying!
So, I also realized its the fibonacci sequence for number of combinations of numbers. All I care about is counting sequential digits, we skip a character after every sequence. We just need to account for if the first character is a number and we are good. I did this in ruby. I didn't really try for anything bonus points wise.
Pastebin because formatting doesn't like & or <
My code also outputs 0 if the sequence itself is invalid(ends on a non-digit character, or has two non-digit characters in a row)
A bit late to the party but here's a Rust solution that is probably maybe correct: https://pastebin.com/Eaes7hU9
Given an input c, outputs the number of distinct lists of strings lst such that:
''.join(lst) == cs in lst, s consists of an arbitrary character followed by one or more characters from '0123456789'Sure hope I didn't mess this up, because I think the fundamental idea is quite elegant! Should run successfully for all "reasonable" inputs (as in, the numeric output fits in a uint64 and the input isn't ridiculously long). Fundamental algorithm is O(n) if you assume all arithmetic is O(1). (If not, then I don't know what the time complexity is, and I don't feel like working it out.)
from functools import cache
from itertools import pairwise
from math import prod
@cache
def fibonacci(n: int) -> int:
if n == 0:
return 0
if n == 1:
return 1
return fibonacci(n - 1) + fibonacci(n - 2)
def main(compressed: str) -> int:
is_fragment_start = [i == 0 or c not in '0123456789' for i, c in enumerate(compressed)]
fragment_start_positions = [i for i, s in enumerate(is_fragment_start) if s]
fragment_lengths = [stop - start for start, stop in pairwise(fragment_start_positions + [len(compressed)])]
return prod(fibonacci(fragment_length - 1) for fragment_length in fragment_lengths)
if __name__ == '__main__':
from argparse import ArgumentParser
parser = ArgumentParser()
parser.add_argument('compressed')
print(main(parser.parse_args().compressed))
Idea: a00010 -> [a000, 10] -> [length 4, length 2] -> F(4) * F(2)
01a102b0305 -> [01, a102, b0305] -> [length 2, length 4, length 5] -> F(2) * F(4) * F(5)
where F(n) = fibonacci(n - 1) is the number of ways to partition a string of length n into a list of strings of length ≥2.
F(2) = 1 = fibonacci(1), F(3) = 1 = fibonacci(2), and F(n) = F(n - 2) + F(n - 1), so F is indeed just an offset version of the Fibonacci sequence.
To see why F(n) = F(n - 2) + F(n - 1), here are the ways to split up 'abcde': ['ab'] + (split up 'cde'), ['abc'] + (split up 'de'), and ['abcde'], corresponding to F(5) = F(3) + F(2) + 1.
And the ways to split up 'abcdef': ['ab'] + (split up 'cdef'), ['abc'] + (split up 'def'), ['abcd'] + (split up 'ef'), and ['abcdef'], corresponding to F(6) = F(4) + F(3) + F(2) + 1 = F(4) + F(5) = F(6 - 2) + F(6 - 1).
The same logic generalizes to all n >= 4.
Without memoization, I believe the Fibonacci sequence is O(2^N). It's dependent on how long a sequence of digits is in the input, so your worst case is like O(2^N) if the string is mostly digits and best case being O(N) if there are only 1 or 2 digit sequences.
Someone can correct me if I'm wrong.
My implementation is memoized by functools.cache, but that is a concern when it comes to recursive Fibonacci. That, and stack overflows, which are also a problem for my code (but, again, not for "reasonable" inputs -- fibonacci(94) already exceeds 2^64).
Time complexity-wise, I was more thinking about the case where the numbers get so big that addition, multiplication, etc. can no longer be modelled as taking constant time. Especially if math.prod and enumerate are implemented in ways that are less efficient for huge integers (I haven't thoroughly checked, and I'm not planning to).
functools.cache
That's pretty cool. I haven't dived too deep into python, so I should of looked up the library when you attached the @cache decorator. I learned something.