def setUp(self):
        self.testSolver = solver.Solver()

        #Square test data
        self.testSquareComplete = [[1, 2, 3], [4, 5, 6], [7, 8, 9]]
        self.testSquareHorizontalDuplicate = [[1, 2, 3], [5, 5, 6], [7, 8, 9]]
        self.testSquareVerticalDuplicate = [[1, 2, 4], [4, 5, 6], [7, 8, 9]]
        self.testSquareIncomplete = [['O', 2, 3], [4, 'O', 6], [7, 8, 9]]
        self.testSquareShort = [[5, 6], [7, 8, 9]]
        self.testSquareLong = [[1, 2, 3], [4, 5, 6], [7, 8, 9, 10]]
def test_calcPercentStake():
    player.Player.id = 0

    opts["PLAYERS"] = [(1, i) for i in range(10)]
    s = solver.Solver(opts)

    assert s.calcPercentStake() == [
        0, 1 / 45, 2 / 45, 3 / 45, 4 / 45, 5 / 45, 6 / 45, 7 / 45, 8 / 45,
        9 / 45
    ]
    def simulate(self, filename):
        """Start the simulation by calling the solver"""
        
       
        input_data = self.netHandler.readFile(self.pathToRessources + filename)
        schaltung = nt.Schaltung(input_data)
        schaltung.initInzidenzMatritzen()

        solver = solv.Solver(schaltung)
        self.solutionData = solver.simulate(self.t, self.t_steps)
Exemple #4
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    def test_methods(self):
        "Test exploration between portal locations and other methods"

        # 1. Create an solver without a donut and then slap on a donut
        mysolver = solver.Solver()
        mysolver.donut = donut.Donut(text=from_text(test_donut.EXAMPLES[0]))

        # 2. Explore from all portal ends
        self.assertEqual(mysolver.explore_from((2, 8)), {(6, 10): 6})   # BC -> DE
        self.assertEqual(mysolver.explore_from((2, 13)), {(2, 15): 4})  # DE -> FG
        self.assertEqual(mysolver.explore_from((2, 15)), {(2, 13): 4})  # FG -> DE
        self.assertEqual(mysolver.explore_from((6, 10)), {(2, 8): 6})   # DE -> BC
        self.assertEqual(mysolver.explore_from((9, 2)), {(9, 6): 4,     # AA -> BC
                                                         (11, 12): 30,   # AA -> FG
                                                         (13, 16): 26})  # AA -> ZZ
        self.assertEqual(mysolver.explore_from((11, 12)), {(13, 16): 6,  # FG -> ZZ
                                                           (9, 2): 30,   # FG -> AA
                                                           (9, 6): 32})  # FG -> BC
        self.assertEqual(mysolver.explore_from((13, 16)), {(11, 12): 6,  # ZZ -> FG
                                                           (9, 2): 26,   # ZZ -> AA
                                                           (9, 6): 28})  # ZZ -> BC

        # 3. Compute and check direct portal paths
        mysolver.portal_paths = mysolver.get_direct_paths_between_portals()
        self.assertEqual(len(mysolver.portal_paths), 5)
        self.assertEqual(sorted(mysolver.portal_paths.keys()), ['AA', 'BC', 'DE', 'FG', 'ZZ'])
        self.assertEqual(len(mysolver.portal_paths['AA']), 3)
        self.assertEqual(sorted([path.steps for path in mysolver.portal_paths['AA']]), [4, 26, 30])
        self.assertEqual(sorted([path.steps for path in mysolver.portal_paths['BC']]), [1, 1, 4, 6, 28, 32])
        self.assertEqual(sorted([path.steps for path in mysolver.portal_paths['DE']]), [1, 1, 4, 6])
        self.assertEqual(sorted([path.steps for path in mysolver.portal_paths['FG']]), [1, 1, 4, 6, 30, 32])
        self.assertEqual(sorted([path.steps for path in mysolver.portal_paths['ZZ']]), [6, 26, 28])

        # 4. Compute and check graph
        mysolver.graph = mysolver.portal_paths_to_graph()
        self.assertEqual(len(mysolver.graph.edges), 22)

        # 5. Test solving the graph
        mysolver.solve_donut_maze()
        self.assertEqual(len(mysolver.path), 8)
        self.assertEqual(mysolver.cost, 23)

        # 6. Test part2 graph generation
        mysolver.part2 = True
        mysolver.graph = mysolver.portal_paths_to_graph(depth=1)
        self.assertCountEqual(Counter([(_.start[0], _.end[0]) for _ in mysolver.graph.edges]),
                              {(0, 0): 22})

        mysolver.graph = mysolver.portal_paths_to_graph(depth=2)
        self.assertCountEqual(Counter([(_.start[0], _.end[0]) for _ in mysolver.graph.edges]),
                              {(0, 0): 12, (1, 1): 6, (0, 1): 3, (1, 0): 3})

        mysolver.graph = mysolver.portal_paths_to_graph(depth=3)
        self.assertCountEqual(Counter([(_.start[0], _.end[0]) for _ in mysolver.graph.edges]),
                              {(0, 0): 12, (1, 1): 6, (2, 2): 6, (0, 1): 3, (1, 2): 3, (1, 0): 3, (2, 1): 3})
Exemple #5
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 def restart(self, size, mines):
     self.solving = False
     self.lastSolvedTile = (-1, -1)
     pygame.time.set_timer(pygame.USEREVENT, 0)  # turn off the timer
     self.game.reset()
     self.game.set_size(size)
     self.size = size
     self.game.set_mines(mines)
     self.mines = mines
     self.failed_tile = (-1, -1)
     self.solver = solver.Solver(self.game)
     self.game.begin()
    def test_text_init(self):
        "Test the Solver object creation from text"

        # 1. Create Solver object from text
        myobj = solver.Solver(text=aoc_11.from_text(EXAMPLE_TEXT))

        # 2. Make sure it has the expected values
        self.assertEqual(myobj.part2, False)
        self.assertEqual(len(myobj.text), 4)

        # 3. Check methods
        self.assertEqual(myobj.number_moves(), 11)
Exemple #7
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def test():
    for board in configure.BOARD_MAP.values():
        missing_count = len(board.not_on)
        print '-----------------'
        print missing_count
        total = 1 if missing_count == 10 else 8
        counts = []
        for i in range(total):
            s = solver.Solver(board)
            s.solve()
            print s.state_visited_count
            counts.append(s.state_visited_count)
        print 'avg:', sum(counts) / len(counts)
Exemple #8
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  def __init__(self, puzzle_variant):
    self.piece_set = Piece_set(puzzle_variant)
    self.center_view = setup.setup_center_view(self.piece_set)
    setup.setup_drawer_views(self.piece_set)
    self.solver = solver.Solver(puzzle_variant)

    self.show_drawer_animation = setup.setup_show_drawer_animation()
    
    self.solved_tray_piece = None
    self.tray_piece_transforms = []
    self.tray_piece_transforms_index = -1
    
    data.hud_layer.set_title(str(puzzle_variant.name).replace('_', ' '))
Exemple #9
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    def setUp(self):
        self.testSolver = solver.Solver()

        #Vertical test data
        self.testVerticalRowComplete = [[1], [2], [3], [4], [5], [6], [7], [8],
                                        [9]]
        self.testVerticalRowDuplicate = [[1], [2], [3], [5], [5], [6], [7],
                                         [8], [9]]
        self.testVerticalRowIncomplete = [['O'], [2], [3], [4], ['O'], [6],
                                          [7], [8], [9]]
        self.testVerticalRowShort = [[5], [6], [7], [8], [9]]
        self.testVerticalRowLong = [[1], [2], [3], [4], [5], [6], [7], [8],
                                    [9], [10]]
Exemple #10
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def run(typ,rand,sbd,d,tnumber):

    try:

        dname = str(typ)+"_"+str(rand)+"_"+str(sbd)+"_"+str(d)+"_"+str(tnumber)
        pickle.dump(([[[i for i in range(typ)]]],[[typ]]), open(dname+".bounds","wb"),-1)
        pickle.dump([],open(dname+"true.state","wb"),-1)
        pickle.dump([],open(dname+"true.reward","wb"),-1)

        MEANS = np.array([i*1.0/(typ-1) for i in range(typ)])
        STDS = np.array([1.0/(6*(typ-1)) for i in range(typ)])
        if rand:
            MEANS = np.array([np.random.uniform() for i in range(typ)])

        pickle.dump((typ,MEANS,STDS,d), open(dname+"subsolve.dat","wb"),-1)
        

        env = gym.make('fish-v0')
        env.initialize(types=typ,sbdepth=sbd,days=d,means=MEANS,discretize=False,stds=STDS)

        pickle.dump([],open(dname+"true.state","wb"),-1)
        pickle.dump([],open(dname+"true.reward","wb"),-1)
        
        reward = 0
        s0 = state.State([parts(env.reset())],dname)
        sol = solver.Solver(s0,.95,1.02,dname)
        for i in range(d):
            a = sol.step()
            s, r, done, _ = env.step(a)
            sol.update([parts(s)])
            reward += r
            #input("Continue:")
            if os.path.getsize(dname+"true.state") > 0 and os.path.getsize(dname+"true.reward") > 0:
                S = pickle.load(open(dname+"true.state","rb"))
                R= pickle.load(open(dname+"true.reward","rb"))
            else:
                S = []
                R = []
            S.append(s)
            R.append(r)
            pickle.dump(S,open(dname+"true.state","wb"),-1)
            pickle.dump(R,open(dname+"true.reward","wb"),-1)
            
            #print("ACTUAL FISH:",s)
            #print("ACTUAL REWARD",r)
         
        #print("FINAL REWARD: ",reward)
        pickle.dump(reward,open(dname+".final","wb"),-1)

    except:
        traceback.print_exc(file=open(dname+".error","w"))
Exemple #11
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def part_two(args, input_lines):
    "Process part two of the puzzle"

    # 1. Create the puzzle solver
    two = solver.Solver(part2=True, text=input_lines)

    # 2. Determine the solution for part two
    solution = two.part_two(verbose=args.verbose, limit=args.limit)
    if solution is None:
        print("There is no solution")
    else:
        print("The solution for part two is %s" % (solution))

    # 3. Return result
    return solution is not None
Exemple #12
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def part_two(args, input_lines):
    "Process part two of the puzzle"

    # 1. Create the keymaster
    clortho = solver.Solver(text=input_lines, part2=True)

    # 2. Get the maximum of the amplifiers without feedback
    solution, _ = clortho.get_all_keys(verbose=args.verbose)
    if solution is None:
        print("The keymaster could not solve the vault")
    else:
        print("The keymaster collected all the keys in %d steps" % (solution))

    # 3. Return result
    return solution is not None
Exemple #13
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    def test_p1e0_solve(self):
        "Test Solver object creation with text of part 1 example 0"

        # 1. Create Intcode obhect with values
        mysolver = solver.Solver(text=from_text(test_vault.EXAMPLES[0]))

        # 2. Make sure it has the specified values
        self.assertEqual(mysolver.vault.rows, 3)
        self.assertEqual(mysolver.vault.cols, 9)
        self.assertEqual(len(mysolver.key_paths), 3)

        # 3. Check methods
        solution = mysolver.get_all_keys()
        self.assertEqual(solution[0], 8)
        self.assertEqual(solution[1], [solver.ORIGIN_KEY, 'a', 'b'])
Exemple #14
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    def test_p1e4_init(self):
        "Test Solver object creation with text of part 1 example 4"

        # 1. Create Intcode obhect with values
        mysolver = solver.Solver(text=from_text(test_vault.EXAMPLES[4]))

        # 2. Make sure it has the specified values
        self.assertEqual(mysolver.vault.rows, 6)
        self.assertEqual(mysolver.vault.cols, 24)
        self.assertEqual(len(mysolver.key_paths), 10)

        # 3. Check methods
        solution = mysolver.get_all_keys()
        self.assertEqual(solution[0], 81)
        self.assertEqual(len(solution[1]), 10)
Exemple #15
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def solve():
    s = solver.Solver()
    s.game.display()
    print(print_format_string.format('h3', *s.a_star(game.Heuristic.H3)))
    print(print_format_string.format('h3s', *s.a_star(game.Heuristic.H3s)))
    print(print_format_string.format('h2', *s.a_star(game.Heuristic.H2)))
    print(print_format_string.format('h1', *s.a_star(game.Heuristic.H1)))
    print(
        print_format_string.format('iterative deepening',
                                   *s.iterative_deepening_search()))
    print(
        "depth first Fini: {0}, noeuds traités: {1}, coups à jouer depuis l’état initial: {3}"
        .format(*s.depth_first_search(max_depth=15)))
    print(
        print_format_string.format('breadth first', *s.breadth_first_search()))
Exemple #16
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    def __init__(self, puzzle_str):
        self.puzzle_str = puzzle_str
        self.root_window = tkinter.Tk()
        self.root_window.title("Sudoku")

        self.label = tkinter.Label(master=self.root_window,
                                   text="Unsolved puzzle",
                                   width="12",
                                   height="1")
        self.label.pack(side=tkinter.TOP)
        self.label_state = True

        self.solve_button = tkinter.Button(master=self.root_window,
                                           text="Solve puzzle",
                                           fg="red",
                                           command=self.solve_puzzle)
        self.solve_button.pack(side=tkinter.TOP)

        self.new_puzzle_button = tkinter.Button(master=self.root_window,
                                                text="New puzzle",
                                                fg="red",
                                                command=self.new_puzzle)
        self.new_puzzle_button.pack(side=tkinter.TOP)

        self.grid = tkinter.Frame(self.root_window)
        self.grid.pack(side=tkinter.BOTTOM)

        self.size = 9
        self.table = [[
            puzzle_str[i + self.size * j] for i in range(self.size)
        ] for j in range(self.size)]

        for row in range(self.size):
            for col in range(self.size):
                label = tkinter.Label(
                    self.grid,
                    relief=tkinter.RAISED,  # raised border
                    padx=10,  # make label wide
                    width=2,
                    height=2,
                    text=self.table[row][col])  # label text
                # place label in row r and column c
                label.grid(row=row, column=col)

        self.sol = solver.Solver(9, 3)
        self.solved_table = None

        self.root_window.mainloop()
Exemple #17
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    def test_p1e1_solve(self):
        "Test Solver object creation with text of part 1 example 1"

        # 1. Test Solver object creation with text of part 1 example 1
        mysolver = solver.Solver(text=from_text(test_donut.EXAMPLES[1]))

        # 2. Make sure it has the specified values
        self.assertEqual(mysolver.donut.rows, 37)
        self.assertEqual(mysolver.donut.cols, 35)
        self.assertEqual(len(mysolver.portal_paths), 12)
        self.assertEqual(len(mysolver.graph.edges), 56)

        # 3. Solve the donut maze
        mysolver.solve_donut_maze()
        self.assertEqual(len(mysolver.path), 10)
        self.assertEqual(mysolver.cost, 58)
Exemple #18
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    def test_p1e0_solve(self):
        "Test Solver object creation with text of part 1 example 0"

        # 1. Create Donut Maze solver object from part one example 0
        mysolver = solver.Solver(text=from_text(test_donut.EXAMPLES[0]))

        # 2. Make sure it has the specified values
        self.assertEqual(mysolver.donut.rows, 19)
        self.assertEqual(mysolver.donut.cols, 19)
        self.assertEqual(len(mysolver.portal_paths), 5)
        self.assertEqual(len(mysolver.graph.edges), 22)

        # 3. Solve the donut maze
        mysolver.solve_donut_maze()
        self.assertEqual(len(mysolver.path), 8)
        self.assertEqual(mysolver.cost, 23)
Exemple #19
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    def test_p2e3_solve(self):
        "Test Solver object creation with text of part 2 example 3"

        # 1. Create Intcode obhect with values
        mysolver = solver.Solver(text=from_text(test_vault.EXAMPLES_PART2[3]),
                                 part2=True)
        #print(mysolver.key_paths.keys())

        # 2. Make sure it has the specified values
        self.assertEqual(mysolver.vault.rows, 9)
        self.assertEqual(mysolver.vault.cols, 13)
        self.assertEqual(len(mysolver.key_paths), 19)

        # 3. Check methods
        solution = mysolver.get_all_keys()
        self.assertEqual(solution[0], 72)
Exemple #20
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    def test_empty_init(self):
        """Test default Solver object creation"""

        # 1. Create default Astroids object
        mysolver = solver.Solver()

        # 2. Make sure it has the default values
        self.assertEqual(mysolver.vault.text, None)
        self.assertEqual(mysolver.vault.origin, None)
        self.assertEqual(mysolver.vault.origins, None)
        self.assertEqual(len(mysolver.key_paths), 0)

        # 3. Check methods
        solution = mysolver.get_all_keys()
        self.assertEqual(solution[0], 0)
        self.assertEqual(solution[1], [solver.ORIGIN_KEY])
 def draw_carType_new(self):
     vv = [26.42, 54.79, 68.36, 70.5, 85.79]
     fig = plt.figure()
     ax = fig.add_subplot(1, 1, 1)
     ax.set_xlabel('v/m^3')
     ax.set_ylabel('distance/km')
     ax.set_title('cartype-distance picture')
     y = []
     for v in vv:
         sol = solver.Solver(car_x=v, car_y=1, car_z=1)
         res = sol.get_saveDisSto_simpleV_mileageStockCost_Fre(
             disPrice_coe=5.2 * v / 70.5)
         y.append(res.total_dis)
     ax.plot(vv, y, label='car_type')
     plt.legend()
     plt.show()
Exemple #22
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def solve_board(index):
    board = configure.BOARD_MAP[index]
    s = solver.Solver(board)
    time_start = time.time()
    solution = s.solve()
    time_finished = time.time()
    if solution:
        print 'Solution:'
        print solution
        print '\nStates Visited:', s.state_visited_count
        print '\nTotal Seened:', s.state_count
        print '\nUnique Seened:', len(s.seen)
        print '\nTime Cost:', time_finished - time_start
        g = gui.GUI(solution)
        g.update()
        g.win.getMouse()
Exemple #23
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def part_one(args, input_lines):
    "Process part one of the puzzle"

    # 1. Create the donut solver
    krispy_kreme = solver.Solver(text=input_lines, verbose=args.verbose)

    # 2. Solve the donut maze
    krispy_kreme.solve_donut_maze()
    solution = krispy_kreme.cost
    if solution is None:
        print("Your could not solve the maze")
    else:
        print("You solved the maze in %d steps" % (solution))

    # 3. Return result
    return solution is not None
Exemple #24
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    def solve(self):

        board = copy.deepcopy(self.board.grid)
        puzzle_solver = solver.Solver(board, self.num_row, self.num_col)
        solutions = puzzle_solver.a_star()
        print(solutions)

        self.control_buttons('disabled')
        moves = [self.move_left, self.move_right, self.move_up, self.move_down]

        for move in reversed(solutions):
            moves[move.value](
            )  # value defined in the Move Enum class in Solver.py
            self.update()
            time.sleep(0.2)

        self.control_buttons('normal')
Exemple #25
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    def test_is(self):

        netHandler = nt.NetListHandler()

        input_data = netHandler.readFile("Test-Schaltung.txt")
        schaltung = nt.Schaltung(input_data)
        schaltung.initInzidenzMatritzen()

        solv = solver.Solver(schaltung)
        solv.createInzidenzMatrices()
        solv.startwertEntkopplung(solv.potencialList, 0)

        i_s = solv.i_s(0)

        expected_i_s = [23]

        self.assertAlmostEqual(i_s[0], expected_i_s[0], places=15, msg=None, delta=None)
Exemple #26
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    def testFunction1(self):

        netHandler = nt.NetListHandler()

        input_data = netHandler.readFile("Test-Schaltung.txt")
        schaltung = nt.Schaltung(input_data)
        schaltung.initInzidenzMatritzen()

        solv = solver.Solver(schaltung)
        solv.createInzidenzMatrices()
        solv.startwertEntkopplung(solv.potencialList, 0)

        func1 = solv.function1([-90], [0], [-999, -900], 0)

        expected_func1 = [-1.14]

        self.assertAlmostEqual(func1[0], expected_func1[0], places=15, msg=None, delta=None)
Exemple #27
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    def testMatrixMc(self):

        netHandler = nt.NetListHandler()

        input_data = netHandler.readFile("Test-Schaltung.txt")
        schaltung = nt.Schaltung(input_data)
        schaltung.initInzidenzMatritzen()

        solv = solver.Solver(schaltung)
        solv.createInzidenzMatrices()
        solv.startwertEntkopplung(solv.potencialList, 0)

        mc = solv.matrix_mc([-280], 1)

        expected_mc = [[2.86]]

        self.assertAlmostEqual(mc[0][0], expected_mc[0][0], places=15, msg=None, delta=None)
Exemple #28
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def solvePuzzles():
    '''Driver code to demonstrate solver algorithm in solve.py.

    This will eventually have an interactive GUI.
    '''

    sol = solver.Solver(9, 3)

    board_obj = board.Board(puzzle)
    helper.display("ORIGINAL BOARD", board_obj)
    t_0 = time.time()
    sol.solve(board_obj)
    t_1 = time.time()
    if board_obj.solved:
        helper.display("SOLVED BOARD IN {} seconds".format(t_1-t_0), board_obj)
    else:
        print("no solution to this puzzle")
Exemple #29
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def main(c, n, o):
    """:parameter c 解の個数の閾値
       :parameter n 問題の個数
       :parameter o 出力先パス
    """
    # 問題をリスト
    ans = list()
    while True:
        # 問題生成クラス
        g = Generator()

        # 最低基準まで入力
        if not g.fill():
            continue

        while True:
            try:
                # ソルバークラス
                s = st.Solver(g.get_str(), c)

                for c in range(2, 5):
                    # N国同盟
                    s.remove_by_n_association(s.values, c)

                # 探索
                if not s.brute_force(s.values):
                    raise exception.NonAnswerException
                else:
                    ans.append(g.get_str())
                    print(g.get_str())
                    break
            except exception.NonAnswerException:
                break
            except exception.MultipleAnswerException:
                # 解が複数ある場合は追加で埋める
                if g.update():
                    continue
                else:
                    break

        if len(ans) == n:
            break
    print(ans)
    with open("./question/{}.csv".format(o), "a") as f:
        f.write("\n".join(ans))
Exemple #30
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    def __init__(self):
        # size of the grid
        self.size = 16

        # number of mines on the grid
        self.mines = 40

        # game clock
        self.clock = pygame.time.Clock()

        # screen
        self.screen = pygame.display.set_mode(
            (Gui.CANVAS_SIZE + Gui.COMMANDS_BAR_SIZE + 2 * Gui.PADDING,
             Gui.CANVAS_SIZE + 2 * Gui.PADDING))

        # Initialize the mines game
        self.game = game.Game()
        self.game.set_size(self.size)
        self.game.set_mines(self.mines)

        # Initialize the solver module
        self.solver = solver.Solver(self.game)

        # true when the Gui is using the solver module
        self.solving = False

        # tile that was last edited by the solver
        self.lastSolvedTile: (int, int) = (-1, -1)

        # the last mine tile where the left mouse was down
        self.last_left_down = (-1, -1)

        # the last mine tile where the right mouse was down
        self.last_right_down = (-1, -1)

        # tile that was pressed when the game was lost
        self.failed_tile = (-1, -1)

        # Initialize pygame
        pygame.init()

        pygame.display.set_caption("'Mines' made by mattlourenco27 on Github")
        # Icon made by Creaticca Creative Agency from www.flaticon.com
        icon = pygame.image.load("./assets/sprites/icon.png")
        pygame.display.set_icon(icon)