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https://github.com/thib8956/advent-of-code.git
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118 lines
3.1 KiB
Python
118 lines
3.1 KiB
Python
from dataclasses import dataclass
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from heapq import heappop, heappush
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DIRECTIONS = {
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">": 1 + 0j, # EAST
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"v": 0 + 1j, # SOUTH
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"<": -1 + 0j, # WEST
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"^": 0 - 1j, # NORTH
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}
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DIRECTIONS_RV = {v: k for k,v in DIRECTIONS.items()}
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@dataclass(frozen=True)
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class Node:
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pos: complex
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direction: complex
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cost: int = 0
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parent: "Node" = None
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def __lt__(self, other):
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return self.cost < other.cost
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def find_start_and_goal(grid):
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start, goal = None, None
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for y, row in enumerate(grid):
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for x, _ in enumerate(row):
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if grid[y][x] == "S":
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start = complex(x, y)
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elif grid[y][x] == "E":
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goal = complex(x, y)
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return start, goal
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def get_pos(grid, pos):
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x, y = int(pos.real), int(pos.imag)
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if 0 <= x < len(grid[0]) and 0 <= y < len(grid):
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return grid[y][x]
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return None
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def search(grid, start_node, end_pos):
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"""
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Returns the shortest path between start and end using Dijkstra's algorithm
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"""
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queue = [start_node]
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visited = set()
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best_costs = {}
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while queue != []:
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node = heappop(queue)
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visited.add(node)
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if node.pos == end_pos:
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return node
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if node.cost > best_costs.get((node.pos, node.direction), 99999999): # already found a better path to this pos
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continue
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best_costs[(node.pos, node.direction)] = node.cost
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# visit each neighbor
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# go in the same direction
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n1 = Node(node.pos + node.direction, node.direction, node.cost + 1, node)
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if get_pos(grid, n1.pos) != "#" and n1 not in visited:
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heappush(queue, n1)
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# turn clockwise
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turned = node.direction * 1j
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n2 = Node(node.pos + turned, turned, node.cost + 1000 + 1, node)
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if get_pos(grid, n2.pos) != "#" and n2 not in visited:
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heappush(queue, n2)
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# turn counterclockwise
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turned = node.direction * -1j
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n3 = Node(node.pos + turned, turned, node.cost + 1000 + 1, node)
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if get_pos(grid, n3.pos) != "#" and n3 not in visited:
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heappush(queue, n3)
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return None
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def print_grid(grid):
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for row in grid:
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print("".join(row))
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def main(grid, debug=False):
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start, goal = find_start_and_goal(grid)
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direction = 1 + 0j # initial direction is east
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end_node = search(grid, Node(start, direction), goal)
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total_cost = end_node.cost
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print("Part 1: ", total_cost)
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if debug:
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# compute path
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n = end_node
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path = []
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if n is not None:
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while n.parent is not None:
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path.insert(0, n)
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n = n.parent
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for n in path:
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x, y = int(n.pos.real), int(n.pos.imag)
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grid[y][x] = "O"
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print(f"Pos {x},{y} Direction {DIRECTIONS_RV[n.direction]} Cost {n.cost}")
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print_grid(grid)
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input()
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print(chr(27) + "[2J") # clear terminal
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if __name__ == "__main__":
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import sys
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infile = sys.argv[1] if 1 < len(sys.argv) else "example.txt"
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with open(infile) as f:
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grid = [list(l.rstrip()) for l in f.readlines()]
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main(grid)
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