sp
4 weeks ago
6 changed files with 184 additions and 0 deletions
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28Lecture2/colours-solution.py
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13Lecture2/level0.txt
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3Lecture2/level1.txt
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17Lecture2/level2.txt
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99Lecture2/maestria-in-class.py
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24Lecture2/xkcd_287.py
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from itertools import combinations |
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from z3 import * |
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solver = Solver() |
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Colours = Datatype("Colours") |
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Colours.declare("RED") |
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Colours.declare("BLUE") |
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Colours.declare("GREEN") |
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Colours.declare("YELLOW") |
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Colour = Colours.create() |
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f = Function('f', IntSort(), Colour) |
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variables = list() |
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for i in range(0,5): |
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variables.append(Int(f"x{i}")) |
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solver.add(0 <= variables[-1]) |
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solver.add(variables[-1] <= 5) |
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solver.add(Distinct(variables)) |
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for combi in combinations(variables,2): |
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solver.add(Implies(Abs(combi[0] - combi[1]) == 1, f(combi[0]) != f(combi[1]))) |
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result = solver.check() |
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if result == sat: |
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print(solver.model()) |
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XX_________________________________XX |
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_____________________________________ |
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________________1____________________ |
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_____________________________________ |
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_____________________________________ |
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_____________________________________ |
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_____________________________________ |
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_____________________________________ |
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_____________________________________ |
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_____________________________________ |
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_2_________________________________3_ |
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_____________________________________ |
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XX_________________________________XX |
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XXXXXXXX |
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X_1__3__ |
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X_2__4__ |
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XX___________________________XX |
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_______________________________ |
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_2___________________________3_ |
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_______________________________ |
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_______________________________ |
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_______________________________ |
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_______________________________ |
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_______________________________ |
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_______________________________ |
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_______________________________ |
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_______________________________ |
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_______________________________ |
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______________________1________ |
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_______________________________ |
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_______________________________ |
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_______________________________ |
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XX___________________________XX |
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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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import string |
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# get the playground information |
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directory = os.path.dirname(os.path.realpath(__file__)) |
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fname = directory + "/" + "test0.txt" |
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if len(sys.argv) == 2: |
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fname = sys.argv[1] |
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with open(fname) as f: |
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playground = f.read() |
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playground = [[c for c in row] for row in playground.strip().split("\n")] |
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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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for row in playground: |
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assert(len(row) == size_x) |
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bells = {} |
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for i in range(size_y): |
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for j in range(size_x): |
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c = playground[i][j] |
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if ord(c) in range(ord("1"), ord("9") + 1): |
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assert(int(c) not in bells.keys()) |
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bells[int(c)] = (j, i) |
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################################### Maestria ################################### |
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print(f"Playground size : {size_x} x {size_y}") |
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print("Playground:") |
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print("\n".join(["".join(i) for i in playground])) |
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print("Bell positions:") |
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print(bells) |
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print("\n") |
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# create the solver |
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solver = Solver() |
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fudge_x, fudge_y = Ints("fudge_x fudge_y") |
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# position must be in the board |
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solver.add(fudge_x >= 0, fudge_x < size_x, fudge_y >= 0, fudge_y < size_y) |
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# position must be on walkable cell |
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for i in range(size_y): |
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for j in range(size_x): |
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if playground[i][j] != "_": |
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solver.add(Not(And(fudge_y == i, fudge_x == j))) |
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# encode distances in formula |
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distances = {bell: None for bell in bells.keys()} |
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for bell, (x,y) in bells.items(): |
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distances[bell] = (fudge_x - x) * (fudge_x - x) + (fudge_y - y) * (fudge_y - y) |
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# |
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# enforce ordering of distances |
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distances_sorted = [distances[b] for b in sorted(bells.keys())] |
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for i in range(len(distances_sorted) - 1): |
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near = distances_sorted[i] |
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far = distances_sorted[i+1] |
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solver.add(near < far) |
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# call the solver and check satisfiability |
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while solver.check() == sat: |
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#result = solver.check() |
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#if result == sat: |
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m = solver.model() |
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if fudge_x is not None and fudge_y is not None: |
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pos_x = m[fudge_x].as_long() |
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pos_y = m[fudge_y].as_long() |
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playground[pos_y][pos_x] = "F" |
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solver.add(Or(fudge_x != pos_x, fudge_y != pos_y)) |
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################################################################################ |
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from colorama import Fore, Back, Style |
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cols = [Fore.BLUE, Fore.GREEN, Fore.RED, Fore.YELLOW, Fore.MAGENTA, Fore.CYAN] |
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tones = [Style.BRIGHT, Style.DIM] |
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cols = sum([[c + t for c in cols] for t in tones], []) |
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if sys.stdout.isatty(): |
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for bell in sorted(list(bells.keys())): |
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x, y = bells[bell] |
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playground[y][x] = Back.BLACK + cols[bell - 1] + playground[y][x] + Style.RESET_ALL |
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for y in range(size_y): |
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for x in range(size_x): |
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c = playground[y][x] |
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if c == "_": playground[y][x] = Fore.BLACK + Back.WHITE + c + Style.RESET_ALL |
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if c == "X": playground[y][x] = Fore.WHITE + Back.BLACK + c + Style.RESET_ALL |
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if c == "F": playground[y][x] = Fore.BLACK + Back.WHITE + c + Style.RESET_ALL |
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text = "\n".join(["".join([c for c in row]) for row in playground]) |
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print(text) |
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#!/usr/bin/python3 |
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from z3 import * |
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a,b,c,d,e,f = Ints('a b c d e f') |
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s = Solver() |
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s.add(215*a + 275*b + 335*c + 355*d + 420*e + 580*f == 1505, a>=0, b>=0, c>=0, d>=0, e>=0, f>=0) |
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results=[] |
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while True: |
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if s.check() == sat: # |
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m = s.model() # |
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print(m) # |
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results.append(m) |
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#block = [a != m[a].as_long(), b != m[b].as_long(), c != m[c].as_long(), d != m[d].as_long(), e != m[e].as_long(), f != m[f].as_long()] |
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#Different approach: Iterate over all entries in the model |
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block = [] |
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for d in m.decls(): |
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#print(d, type(d), d(), type(d()), m[d], type(m[d])) |
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block.append(d() != m[d].as_long()) |
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s.add(Or(block)) |
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else: |
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print ("All results enumerated, total =", len(results)) |
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break |
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