312 lines
5.8 KiB
Plaintext
312 lines
5.8 KiB
Plaintext
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Advent of Code
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• [About]
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• [Events]
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• [Shop]
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• [Settings]
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• [Log Out]
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br0xen (AoC++) 16*
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0.0.0.0:2022
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• [Calendar]
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• [AoC++]
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• [Sponsors]
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• [Leaderboard]
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• [Stats]
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Our sponsors help make Advent of Code possible:
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King - At King, we create unforgettable games (like Candy Crush) that are loved around the world. Join us to bring
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moments of magic to hundreds of millions of people every single day!
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--- Day 9: Rope Bridge ---
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This rope bridge creaks as you walk along it. You aren't sure how old it is, or whether it can even support your weight.
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It seems to support the Elves just fine, though. The bridge spans a gorge which was carved out by the massive river far
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below you.
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You step carefully; as you do, the ropes stretch and twist. You decide to distract yourself by modeling rope physics;
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maybe you can even figure out where not to step.
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Consider a rope with a knot at each end; these knots mark the head and the tail of the rope. If the head moves far
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enough away from the tail, the tail is pulled toward the head.
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Due to nebulous reasoning involving Planck lengths, you should be able to model the positions of the knots on a
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two-dimensional grid. Then, by following a hypothetical series of motions (your puzzle input) for the head, you can
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determine how the tail will move.
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Due to the aforementioned Planck lengths, the rope must be quite short; in fact, the head (H) and tail (T) must always
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be touching (diagonally adjacent and even overlapping both count as touching):
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....
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.TH.
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....
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....
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.H..
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..T.
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....
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...
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.H. (H covers T)
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...
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If the head is ever two steps directly up, down, left, or right from the tail, the tail must also move one step in that
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direction so it remains close enough:
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..... ..... .....
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.TH.. -> .T.H. -> ..TH.
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..... ..... .....
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... ... ...
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.T. .T. ...
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.H. -> ... -> .T.
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... .H. .H.
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... ... ...
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Otherwise, if the head and tail aren't touching and aren't in the same row or column, the tail always moves one step
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diagonally to keep up:
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..... ..... .....
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..... ..H.. ..H..
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..H.. -> ..... -> ..T..
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.T... .T... .....
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..... ..... .....
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..... ..... .....
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..... ..... .....
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..H.. -> ...H. -> ..TH.
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.T... .T... .....
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..... ..... .....
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You just need to work out where the tail goes as the head follows a series of motions. Assume the head and the tail both
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start at the same position, overlapping.
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For example:
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R 4
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U 4
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L 3
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D 1
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R 4
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D 1
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L 5
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R 2
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This series of motions moves the head right four steps, then up four steps, then left three steps, then down one step,
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and so on. After each step, you'll need to update the position of the tail if the step means the head is no longer
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adjacent to the tail. Visually, these motions occur as follows (s marks the starting position as a reference point):
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== Initial State ==
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......
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......
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......
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......
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H..... (H covers T, s)
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== R 4 ==
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......
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......
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......
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......
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TH.... (T covers s)
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......
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......
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......
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......
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sTH...
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......
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......
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......
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......
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s.TH..
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......
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......
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......
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......
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s..TH.
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== U 4 ==
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......
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......
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......
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....H.
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s..T..
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......
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......
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....H.
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....T.
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s.....
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......
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....H.
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....T.
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......
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s.....
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....H.
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....T.
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......
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......
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s.....
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== L 3 ==
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...H..
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....T.
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......
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......
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s.....
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..HT..
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......
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......
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......
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s.....
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.HT...
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......
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......
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......
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s.....
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== D 1 ==
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..T...
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.H....
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......
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......
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s.....
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== R 4 ==
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..T...
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..H...
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......
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......
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s.....
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..T...
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...H..
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......
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......
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s.....
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......
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...TH.
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......
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......
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s.....
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......
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....TH
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......
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......
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s.....
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== D 1 ==
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......
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....T.
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.....H
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......
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s.....
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== L 5 ==
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......
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....T.
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....H.
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......
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s.....
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......
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....T.
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...H..
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......
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s.....
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......
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......
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..HT..
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......
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s.....
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......
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......
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.HT...
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......
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s.....
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......
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......
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HT....
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......
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s.....
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== R 2 ==
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......
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......
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.H.... (H covers T)
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......
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s.....
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......
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......
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.TH...
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......
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s.....
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After simulating the rope, you can count up all of the positions the tail visited at least once. In this diagram, s
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again marks the starting position (which the tail also visited) and # marks other positions the tail visited:
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..##..
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...##.
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.####.
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....#.
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s###..
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So, there are 13 positions the tail visited at least once.
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Simulate your complete hypothetical series of motions. How many positions does the tail of the rope visit at least once?
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To begin, get your puzzle input.
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Answer: _____________________ [ [Submit] ]
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You can also [Shareon Twitter Mastodon] this puzzle.
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References
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Visible links
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. https://adventofcode.com/
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. https://adventofcode.com/2022/about
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. https://adventofcode.com/2022/events
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. https://teespring.com/stores/advent-of-code
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. https://adventofcode.com/2022/settings
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. https://adventofcode.com/2022/auth/logout
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. Advent of Code Supporter
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https://adventofcode.com/2022/support
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. https://adventofcode.com/2022
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. https://adventofcode.com/2022
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. https://adventofcode.com/2022/support
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. https://adventofcode.com/2022/sponsors
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. https://adventofcode.com/2022/leaderboard
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. https://adventofcode.com/2022/stats
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. https://adventofcode.com/2022/sponsors
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. https://careers.king.com/
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. https://en.wikipedia.org/wiki/Planck_units#Planck_length
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. https://adventofcode.com/2022/day/9/input
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. https://twitter.com/intent/tweet?text=%22Rope+Bridge%22+%2D+Day+9+%2D+Advent+of+Code+2022&url=https%3A%2F%2Fadventofcode%2Ecom%2F2022%2Fday%2F9&related=ericwastl&hashtags=AdventOfCode
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. javascript:void(0);
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