AdventOfCode/2024/20/solution.py

#!/bin/python3
import sys,time,re,copy
from pprint import pprint
sys.path.insert(0, '../../')
from fred import list2int,get_re,nprint,lprint,loadFile,dijkstra,toGrid,findInGrid,create_graph_from_grid,get_value_in_direction,addTuples
start_time = time.time()

input_f = 'input'

#########################################
#                                       #
#              Part 1                   #
#                                       #
#########################################
def part1():
    grid = toGrid(input_f)
    start = findInGrid(grid,'S')
    end = findInGrid(grid,'E')
    graph = create_graph_from_grid(grid,start,end,'#')
    #nprint(grid)
    grid[start[0]][start[1]] = '.'
    grid[end[0]][end[1]] = '.'
    
    path, dist = dijkstra(graph,start,end)
    
    cheatWalls = []
    
    for r,row in enumerate(grid):
        for c,pos in enumerate(row):
            if pos == '.':
                if get_value_in_direction(grid,(r,c),'up') == '#' and get_value_in_direction(grid,(r,c),'down') == '#':
                    cheatWalls.append(addTuples((r,c),(-1,0)))
                    cheatWalls.append(addTuples((r,c),(1,0)))
                elif get_value_in_direction(grid,(r,c),'left') == '#' and get_value_in_direction(grid,(r,c),'right') == '#':
                    cheatWalls.append(addTuples((r,c),(0,-1)))
                    cheatWalls.append(addTuples((r,c),(0,1)))
            if pos == '#':
                if get_value_in_direction(grid,(r,c),'up') == '.' and get_value_in_direction(grid,(r,c),'down') == '.':
                    cheatWalls.append((r,c))
                    cheatWalls.append((r,c))
                elif get_value_in_direction(grid,(r,c),'left') == '.' and get_value_in_direction(grid,(r,c),'right') == '.':
                    cheatWalls.append((r,c))
                    cheatWalls.append((r,c))

    
    #print(dist)
    #nprint(grid,positions=path)
    
    results = {}
    startDist = dist
    #print(cheatWalls)
    for c in cheatWalls:
        newGrid = copy.deepcopy(grid)
        newGrid[c[0]][c[1]] = '.'
        graph = create_graph_from_grid(newGrid,start,end,'#')
        path, dist = dijkstra(graph,start,end)
        dist = startDist-dist
        if dist not in results:
            results[dist] = 0
        results[dist] += 1
        
    pprint(results)
        
start_time = time.time()
print('Part 1:',part1(), '\t\t', round((time.time() - start_time)*1000), 'ms')


#########################################
#                                       #
#              Part 2                   #
#                                       #
#########################################
def part2():
    return
    
start_time = time.time()
print('Part 2:',part2(), '\t\t', round((time.time() - start_time)*1000), 'ms')