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84 lines
3.0 KiB
Python
84 lines
3.0 KiB
Python
import numpy as np
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problem = []
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for x in range(9):
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i = input()
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l = [int(v) for v in i]
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problem.append(l)
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#print(problem)
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np_problem = np.array(problem)
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fixed_coordinates = [] # first getting the coordinates where fixed numbers are present
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empty_coordinates = []
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for i , sub_array in enumerate(problem) :
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temp = [[i , c] for c , sub_element in enumerate(sub_array) if sub_element > 0]
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temp2 = [[i , j] for j , sub_element2 in enumerate(sub_array) if sub_element2 == 0]
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for z in temp : fixed_coordinates.append(z)
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for w in temp2 : empty_coordinates.append(w)
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l , m , r = [0 , 3 , 6] , [1 , 4 , 7] , [2 , 5 , 8]
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avoid_dict = {idx : [] for idx in list(range(0 , len(empty_coordinates)))}
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def generate_bounds(r , c) -> list:
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lower_bound_c = c if c in l else c - 1 if c in m else c - 2
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upper_bound_c = c + 3 if c in l else c + 2 if c in m else c + 1
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lower_bound_r = r if r in l else r - 1 if r in m else r - 2
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upper_bound_r = r + 3 if r in l else r + 2 if r in m else r + 1
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return [lower_bound_c , upper_bound_c , lower_bound_r , upper_bound_r]
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def backtrack(return_coordinates) :
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n_r , n_c = empty_coordinates[empty_coordinates.index(return_coordinates) - 1] # getting back element coordinates
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while [n_r , n_c] != empty_coordinates[empty_coordinates.index(return_coordinates) + 1]:
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if np_problem[n_r , n_c] != 0 :
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avoid_dict[empty_coordinates.index([n_r , n_c])].append(np_problem[n_r , n_c])
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fix_flag = False
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r , c = n_r , n_c
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for num in range(1 , 10) :
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l_b_c , u_b_c , l_b_r , u_b_r = generate_bounds(r , c)
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if all([num not in np_problem[l_b_r : u_b_r , l_b_c : u_b_c] , num not in np_problem[r , :] , num not in np_problem[: , c]]) :
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if num not in avoid_dict.get(empty_coordinates.index([n_r , n_c])) :
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np_problem[n_r , n_c] , fix_flag = num , True
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break
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if fix_flag : n_r , n_c = empty_coordinates[empty_coordinates.index([n_r , n_c]) + 1]
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if not fix_flag :
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np_problem[n_r , n_c] = 0
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avoid_dict[empty_coordinates.index([n_r , n_c])].clear()
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n_r , n_c = empty_coordinates[empty_coordinates.index([n_r , n_c]) - 1]
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for r in range(9) :
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for c in range(9) :
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if [r , c] not in fixed_coordinates :
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fix_flag = False
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for num in range(1 , 10) :
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l_b_c , u_b_c , l_b_r , u_b_r = generate_bounds(r , c)
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if all([num not in np_problem[l_b_r : u_b_r , l_b_c : u_b_c] , num not in np_problem[r , :] , num not in np_problem[: , c]]) :
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np_problem[r , c] , fix_flag = num , True
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break
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if not fix_flag : backtrack([r , c])
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print(np_problem)
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