2022-12-16 06:13:24 +00:00
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import sys
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2022-12-17 04:44:57 +00:00
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import operator
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2022-12-16 06:13:24 +00:00
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import matrix
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import shared
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import scanf
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from dataclasses import dataclass
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2022-12-17 03:07:17 +00:00
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from collections import defaultdict
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2022-12-16 06:13:24 +00:00
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from typing import List, Dict
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from pprint import pprint
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import networkx as nx
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2022-12-17 03:07:17 +00:00
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from IPython.display import Image, display
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2022-12-16 06:13:24 +00:00
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@dataclass
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class Valve:
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label: str
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rate: int
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tunnels: List[str]
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opened_at: int = -1
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potential: Dict[str, int] = None
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def set_potential(self, valves):
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self.potential = {}
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for tunnel in self.tunnels:
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self.potential[tunnel] = valves[tunnel].rate
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def highest_potential(self):
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return max(self.potential, key=self.potential.get)
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def parse(rows):
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valves = {}
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for row in rows:
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2022-12-16 06:19:30 +00:00
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left, right = row.split(" valve")
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right = right.replace("s ", "").lstrip()
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valve, rate = scanf.scanf("Valve %s has flow rate=%d; %*s %*s to", left)
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tunnels = right.split(", ")
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valves[valve] = Valve(label=valve, rate=rate, tunnels=tunnels)
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for _, v in valves.items():
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v.set_potential(valves)
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return valves
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def part1(rows, sample=False):
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p1 = Volcano(rows, sample, 30)
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p1.run()
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class Volcano:
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def __init__(self, rows, sample, minutes):
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self.rows = rows
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self.sample = sample
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self.valves = parse(rows)
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self.nonzero = {v.label: v for _, v in self.valves.items() if v.rate > 0}
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self.cur = "AA"
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self.tick = 1
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self.minutes = minutes
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self.g = nx.DiGraph()
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self.path_distances = defaultdict(dict)
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self.set_up_graph()
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def draw(self):
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pdot = nx.drawing.nx_pydot.to_pydot(self.g)
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pdot.write_png("15.png")
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def set_up_graph(self):
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for lbl, v in self.valves.items():
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for t in v.tunnels:
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# self.g.add_edge(lbl, t, {'weight':self.valves[t].rate})
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self.g.add_edge(lbl, t, weight=self.valves[t].rate)
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all_keys = self.valves.keys()
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l = dict(nx.all_pairs_shortest_path_length(self.g))
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for lbl, _ in self.valves.items():
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for other in all_keys:
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if other == lbl:
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continue
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self.path_distances[lbl][other] = l[lbl][other]
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self.draw()
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def do_tick(self, minute):
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pressure = 0
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opened = []
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for _, valve in self.valves.items():
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if valve.opened_at >= 0:
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pressure += valve.rate
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opened.append(valve.label)
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print(f"== Min {minute}:: {len(opened)} Valves {', '.join(opened)} are open, releasing {pressure} pressure")
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def calculate_total_flow(self):
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total = 0
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for label, valve in self.valves.items():
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if valve.opened_at > 0:
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total += valve.rate * (30 - valve.opened_at)
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return total
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def run(self):
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# Construct the graph with vertices & edges from the input
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# Call a function to compute the distances between every pair of vertices
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# Create a closed set containing all the valves with non-zero rates
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# At each step, iterate over the remaining set of closed, non-zero valves
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# - Subtract the distance from remaining minutes
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# - Calculate the flow (rate * remaining minutes)
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# - Remove the recently opened valve from the closed set (functionally), so the deeper levels won't consider it
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def priority(remaining):
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print("REMAINING", remaining)
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_pris = []
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for _,n in self.nonzero.items():
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# (time_remaining - distance_to_valve - 1) * flow rate
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d = self.path_distances[self.cur][n.label]
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pri = (remaining - d) * n.rate
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_pris.append((n.label, pri, d))
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_pris = list(sorted(_pris, key=operator.itemgetter(2,1)))
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print(self.cur, end=' ')
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pprint(_pris)
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return _pris
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remaining = self.minutes
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open_order = []
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while len(self.nonzero):
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if remaining <= 0:
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print("ran out of time")
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break
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self.do_tick(31-remaining)
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# CALCULATE PRIORITIES
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pris = priority(remaining)
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#print(pris)
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# GET HIGHEST PRIORITY label
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nxt, _, distance = pris.pop(0)
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#distance *= -1
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# GET HIGHEST PRIORITY VALVE
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n = self.nonzero[nxt]
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# remove valve from dict
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del self.nonzero[nxt]
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# keep track of which order opened
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open_order.append(n.label)
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self.cur = n.label
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self.valves[self.cur].opened_at = self.minutes - (remaining - 1)
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self.do_tick(self.minutes+1-remaining)
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print("\tMoving to", n.label)
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print("\tOpening ", n.label)
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print()
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remaining -= distance # Move
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print("\t\tMoved", distance,"distance/minutes")
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remaining -= 1 # open
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print("\t\tOpened",nxt,"1 minute")
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print("total flow:", self.calculate_total_flow())
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self.do_tick(30)
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print(remaining)
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print(open_order)
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print("sample: 1651")
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print("total flow:", self.calculate_total_flow())
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def part2(rows, sample=False):
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p2 = Volcano(rows, sample, 26)
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p2.run()
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def main():
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sample = False
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if sys.argv[-1] == "--sample":
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sample = True
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rows = [row for row in shared.load_rows(16)]
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with shared.elapsed_timer() as elapsed:
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part1(rows, sample)
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print("🕒", elapsed())
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# with shared.elapsed_timer() as elapsed:
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# part2(rows, sample)
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# print("🕒", elapsed())
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print("The result for solution 1 is: 1820")
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print("The result for solution 2 is: 2602")
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if __name__ == "__main__":
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main()
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