def test_str_to_direction_should_parse_correctly_inputs(self):
        mower1 = Mower(0, 0, 0, 0, 0, 'N', None)
        mower2 = Mower(0, 0, 0, 0, 0, 'S', None)
        mower3 = Mower(0, 0, 0, 0, 0, 'E', None)
        mower4 = Mower(0, 0, 0, 0, 0, 'W', None)

        self.assertTrue(mower1.direction == Direction.NORTH)
        self.assertTrue(mower2.direction == Direction.SOUTH)
        self.assertTrue(mower3.direction == Direction.EAST)
        self.assertTrue(mower4.direction == Direction.WEST)
 def test_move_forward_shoud_not_move_if_on_west_lawn_border(self):
     mower1 = Mower(0, 0, 5, 5, 5, 'W', None)
     pos_x_before = mower1.pos_x
     pos_y_before = mower1.pos_y
     mower1.move_forward()
     pos_x_after = mower1.pos_x
     pos_y_after = mower1.pos_y
     self.assertEqual(pos_x_before, pos_x_after,
                      'position x before and after do not match')
     self.assertEqual(pos_y_before, pos_y_after,
                      'position y before and after do not match')
 def test_rotate_right_should_modify_direction_to_the_right(self):
     mower1 = Mower(0, 0, 0, 0, 0, 'N', None)
     self.assertTrue(mower1.direction == Direction.NORTH)
     mower1.rotate_right()
     self.assertTrue(mower1.direction == Direction.EAST)
     mower1.rotate_right()
     self.assertTrue(mower1.direction == Direction.SOUTH)
     mower1.rotate_right()
     self.assertTrue(mower1.direction == Direction.WEST)
     mower1.rotate_right()
     self.assertTrue(mower1.direction == Direction.NORTH)
Exemplo n.º 4
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def read_mower_status(line, line_number, up_right):
    """
    Parse a "mower status" line in the input test file (format: "%d %d [NESW]") and returns a mower initial status.
    :param line: a line holding a mower status in the test file as a string
    :param line_number: line number in the input file (used in exception to report error)
    :param up_right: (int, int) tuple ==> grid lawn upper right corner coordinates
    :return: a tuple as ((int, int), [NESW]) giving a mower status (position, orientation) if no exception occurs
    """
    matcher = re.match(MOWER_STATUS_PATTERN, line)
    if matcher and len(matcher.groups()) == 3:
        x = read_integer(matcher, 1, line_number)
        y = read_integer(matcher, 2, line_number)
        if x > up_right[0] or y > up_right[1]:
            raise Exception(
                'Error line {}, coordinates should be less or equal than line 1 coordinates'
                .format(line_number))
        else:
            if Mower.is_valid_orientation(matcher.group(3)):
                return (x, y), matcher.group(3)
            else:
                raise Exception(
                    'Error line {}, format expected:'.format(line_number) +
                    '"%d %d {one char in N,E,S,W}"')
    else:
        raise Exception('Error line {}, format expected:'.format(line_number) +
                        '"%d %d {one char in N,E,S,W}"')
Exemplo n.º 5
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def read_program(line, line_number):
    """
    Parse a mower "program" line in the test file (should be a sequence of valid mower actions (a, G or D) as a string.
    :param line: line holding the mower program as a string
    :param line_number: line number in the input file (used in exception to report error)
    :return: the program as a string if no exception occurs
    """
    for action in line:
        if not Mower.is_valid_moving_code(action):
            raise Exception(
                'Error line {}: programs should be a sequence matching "[AGD]*"'
                .format(line_number))
    return line
Exemplo n.º 6
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 def open(self):
     """
     Open and parse input test file (file_name).
     :return: A list of tuples (Mower, program) if no exception occurs
     """
     with open(self._filename, 'r') as f:
         line = read_line(f)
         Mower.set_up_right_corner(read_grid_up_right_corner(line, 1))
         line_number = 1
         status = None
         self._mowers = []
         line = read_line(f)
         while line != '':
             line_number += 1
             if line_number % 2 == 0:
                 status = read_mower_status(line, line_number,
                                            Mower.GRID_UP_RIGHT_CORNER)
             else:
                 program = read_program(line, line_number)
                 self._mowers.append((Mower(status[0], status[1]), program))
             line = read_line(f)
         f.close()
Exemplo n.º 7
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def parse_input_file(file_path):
    if not path.exists(file_path):
        print('Input file not found')
        return

    f = open(file_path, 'r')

    content = f.readlines()

    if len(content) < 3:
        print('Input file format error: file contains:' + str(len(content)) +
              ' lines it should at least contains 3 lines ')
        return
    f.close

    # clean data
    for i in range(len(content)):
        content[i] = content[i].strip()

    max_grid = content[0].split(' ')
    if len(max_grid) != 2:
        print('unable to read max grid data')
        return

    i = 1
    id = 1
    mowers = []
    while i + 1 < len(content):
        initial_pos = content[i].split(' ')
        if (len(initial_pos) != 3):
            print('unable to read mower' + str(id) + ' initial position')
        else:
            moves = list(content[i + 1])
            m = Mower(id, initial_pos[0], initial_pos[1], max_grid[0],
                      max_grid[1], initial_pos[2], moves)
            mowers.append(m)
        i += 2
        id += 1

    return mowers
Exemplo n.º 8
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def main(mowerNum):
    lawn = setup(mowerNum)
    if mowerNum == 0:
        mower = Mower()
    else:
        mower = mowerUser

    # # draw the initial mower location
    mowerID = canvas.create_rectangle((mower.getPosition()[0] * SQUARE_W + CORNER_OFFSET),
                                      (mower.getPosition()[1] * SQUARE_W + CORNER_OFFSET),
                                      (mower.getPosition()[2] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                      (mower.getPosition()[3] * SQUARE_W + CORNER_OFFSET + SQUARE_W), fill="red")
    mowerTriID = canvas.create_polygon((mower.getTriangle()[0] * SQUARE_W + CORNER_OFFSET),
                                       (mower.getTriangle()[1] * SQUARE_W + CORNER_OFFSET),
                                       (mower.getTriangle()[2] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                       (mower.getTriangle()[3] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                       (mower.getTriangle()[4] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                       (mower.getTriangle()[5] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                       outline='black',
                                       fill='black', width=0)
    # drawMower(mower)
    # tk0.mainloop()
    lawn = mower.updateLawn(lawn)
    while not mower.isDone(lawn):
    # while 2 in lawn[:, :]:
        tk.update_idletasks()
        tk.update()
        # do stuff
        canvas.delete(mowerID)
        canvas.delete(mowerTriID)

        lawn = mower.updateLawn(lawn)
        mower.makeMove(lawn)

        # update lawn:
        for ix, iy in np.ndindex(lawn.shape):
            if lawn[ix][iy] == 2:
                canvas.create_rectangle((iy * SQUARE_W + CORNER_OFFSET), (ix * SQUARE_W + CORNER_OFFSET),
                                        (iy * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                        (ix * SQUARE_W + CORNER_OFFSET + SQUARE_W), fill=initColor)
            if lawn[ix][iy] == 4:
                canvas.create_rectangle((iy * SQUARE_W + CORNER_OFFSET), (ix * SQUARE_W + CORNER_OFFSET),
                                        (iy * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                        (ix * SQUARE_W + CORNER_OFFSET + SQUARE_W), fill="white")

            if lawn[ix][iy] == 1:
                canvas.create_rectangle((iy * SQUARE_W + CORNER_OFFSET), (ix * SQUARE_W + CORNER_OFFSET),
                                        (iy * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                        (ix * SQUARE_W + CORNER_OFFSET + SQUARE_W), fill=mowedColor)


        mowerID = canvas.create_rectangle((mower.getPosition()[0] * SQUARE_W + CORNER_OFFSET),
                                          (mower.getPosition()[1] * SQUARE_W + CORNER_OFFSET),
                                          (mower.getPosition()[2] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                          (mower.getPosition()[3] * SQUARE_W + CORNER_OFFSET + SQUARE_W), fill="red")
        mowerTriID = canvas.create_polygon((mower.getTriangle()[0] * SQUARE_W + CORNER_OFFSET),
                                           (mower.getTriangle()[1] * SQUARE_W + CORNER_OFFSET),
                                           (mower.getTriangle()[2] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                           (mower.getTriangle()[3] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                           (mower.getTriangle()[4] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                           (mower.getTriangle()[5] * SQUARE_W + CORNER_OFFSET + SQUARE_W),
                                           outline='black',
                                           fill='black', width=0)
Exemplo n.º 9
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import argparse
from tkinter import *
import time
import numpy as np

from mower import Mower_User
from mower import Mower

tk = Tk()
canvas = Canvas(tk, width=500, height=400)
MAX_WIDTH = 20
MAX_HEIGHT = 30
homeTL = [-1, -1]
mowerUser = Mower()    # Change this to switch between user and AI
CORNER_OFFSET = 5
tl_x = CORNER_OFFSET
tl_y = CORNER_OFFSET
SQUARE_W = 20

mowedColor = '#%02x%02x%02x' % (41, 138, 10)
initColor = '#%02x%02x%02x' % (48, 220, 0)

fwd = 0
back = 1
left = 2
right = 3
diagL = 4
diagR = 5

def setup(mowerNum):
    initlawn = np.zeros([MAX_HEIGHT * 2, MAX_WIDTH * 2])
Exemplo n.º 10
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from lawn import Lawn
from mower import Mower

lawn = Lawn(width=5, length=5)
lawn.render_grid()

mower1 = Mower(position=[1, 2],
               orientation="N",
               directions=list("LFLFLFLFF"),
               lawn=lawn)
mower2 = Mower(position=[3, 3],
               orientation="E",
               directions=list("FFRFFRFRRF"),
               lawn=lawn)

mower1.move()
print(f"final mower1 position: {mower1.get_position()}")
print(f"final mower1 orientation: {mower1.get_orientation()}")

mower2.move()
print(f"final mower2 position: {mower2.get_position()}")
print(f"final mower2 orientation: {mower2.get_orientation()}")
Exemplo n.º 11
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from state import State
from mower import Mower
from reader import reader

if __name__ == '__main__':

    settings = reader("setting_file.txt")

    initial_states = []
    mowers = []
    for s in settings:
        initial_state = State(x=s["x_ini"],
                              y=s["y_ini"],
                              orientation=s["orientation_ini"],
                              x_max=s["x_max"],
                              y_max=s["y_max"])
        mowers.append(
            Mower(state=initial_state,
                  instructions=s["instructions"],
                  name=s["name"]))

    objective_states = ["13W", "25N"]
    for m, mower in enumerate(mowers):
        mower.sequence_move()
        assert str(
            mower.state) == objective_states[m], \
            "wrong state %r, should be %r" % mower.name % objective_states[m]

        print("passed test for", mower.name)
 def test_str_to_direction_should_return_unknown(self):
     mower = Mower(0, 0, 0, 0, 0, '@', None)
     self.assertTrue(mower.direction == Direction.UNKNOWN)
    def test_str_to_direction_should_not_be_case_sensitive(self):
        mower1 = Mower(0, 0, 0, 0, 0, 'N', None)
        mower2 = Mower(0, 0, 0, 0, 0, 'n', None)

        self.assertTrue(mower1.direction == Direction.NORTH)
        self.assertTrue(mower2.direction == Direction.NORTH)