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# coding: utf-8 |
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import os, sys |
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from z3 import * |
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# get the playground information |
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if len(sys.argv) != 2: |
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print("Usage: python3 square.py <level-file>") |
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sys.exit(0) |
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with open(sys.argv[1]) as f: |
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playground = f.read() |
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rows = playground.strip().split("\n") |
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playground = [[None if x == "_" else int(x) for x in r.split()] for r in rows] |
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# get the playground size |
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size_y = len(playground) |
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assert(size_y != 0) |
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size_x = len(playground[0]) |
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assert(size_x != 0) |
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assert(size_x == size_y) |
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#################################### Square #################################### |
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# create the solver |
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solver = Solver() |
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# todo: create an integer variable for each playground cell |
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# hint: use something like the coordinates as part of the variable name |
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numbers = [[None for _j in range(size_x)] for _j in range(size_y)] |
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for i in range(size_y): |
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for j in range(size_x): |
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pass # ... replace this with your code ... |
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# todo: assign each known number the corresponding value from playground |
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for i in range(size_y): |
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for j in range(size_x): |
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pass # ... replace this with your code ... |
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# todo: declare a variable for the sum of all columns, rows and diagonals |
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# ... your code goes here ... |
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# todo: enforce that each column sums up to the declared variable |
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for j in range(size_x): |
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pass # ... replace this with your code ... |
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# todo: enforce that each row sums up to the declared variable |
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for i in range(size_y): |
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pass # ... replace this with your code ... |
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# todo: enforce that both diagonals sum up to the declared variable |
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# call the solver and check satisfiability |
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res = solver.check() |
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if res != sat: |
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print("unsat") |
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sys.exit(1) |
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# print the model |
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m = solver.model() |
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for i in range(size_y): |
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results = [] |
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for j in range(size_x): |
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num = numbers[i][j] |
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results.append("_" if num is None else m[num].as_long()) |
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print(("%4s" * len(results)) % tuple(results)) |
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################################################################################ |