MinDalle_StableDiff/Python39/Lib/test/test_turtle.py

443 lines
13 KiB
Python

import pickle
import unittest
from test import support
turtle = support.import_module('turtle')
Vec2D = turtle.Vec2D
test_config = """\
width = 0.75
height = 0.8
canvwidth = 500
canvheight = 200
leftright = 100
topbottom = 100
mode = world
colormode = 255
delay = 100
undobuffersize = 10000
shape = circle
pencolor = red
fillcolor = blue
resizemode = auto
visible = None
language = english
exampleturtle = turtle
examplescreen = screen
title = Python Turtle Graphics
using_IDLE = ''
"""
test_config_two = """\
# Comments!
# Testing comments!
pencolor = red
fillcolor = blue
visible = False
language = english
# Some more
# comments
using_IDLE = False
"""
invalid_test_config = """
pencolor = red
fillcolor: blue
visible = False
"""
class TurtleConfigTest(unittest.TestCase):
def get_cfg_file(self, cfg_str):
self.addCleanup(support.unlink, support.TESTFN)
with open(support.TESTFN, 'w') as f:
f.write(cfg_str)
return support.TESTFN
def test_config_dict(self):
cfg_name = self.get_cfg_file(test_config)
parsed_cfg = turtle.config_dict(cfg_name)
expected = {
'width' : 0.75,
'height' : 0.8,
'canvwidth' : 500,
'canvheight': 200,
'leftright': 100,
'topbottom': 100,
'mode': 'world',
'colormode': 255,
'delay': 100,
'undobuffersize': 10000,
'shape': 'circle',
'pencolor' : 'red',
'fillcolor' : 'blue',
'resizemode' : 'auto',
'visible' : None,
'language': 'english',
'exampleturtle': 'turtle',
'examplescreen': 'screen',
'title': 'Python Turtle Graphics',
'using_IDLE': '',
}
self.assertEqual(parsed_cfg, expected)
def test_partial_config_dict_with_comments(self):
cfg_name = self.get_cfg_file(test_config_two)
parsed_cfg = turtle.config_dict(cfg_name)
expected = {
'pencolor': 'red',
'fillcolor': 'blue',
'visible': False,
'language': 'english',
'using_IDLE': False,
}
self.assertEqual(parsed_cfg, expected)
def test_config_dict_invalid(self):
cfg_name = self.get_cfg_file(invalid_test_config)
with support.captured_stdout() as stdout:
parsed_cfg = turtle.config_dict(cfg_name)
err_msg = stdout.getvalue()
self.assertIn('Bad line in config-file ', err_msg)
self.assertIn('fillcolor: blue', err_msg)
self.assertEqual(parsed_cfg, {
'pencolor': 'red',
'visible': False,
})
class VectorComparisonMixin:
def assertVectorsAlmostEqual(self, vec1, vec2):
if len(vec1) != len(vec2):
self.fail("Tuples are not of equal size")
for idx, (i, j) in enumerate(zip(vec1, vec2)):
self.assertAlmostEqual(
i, j, msg='values at index {} do not match'.format(idx))
class Multiplier:
def __mul__(self, other):
return f'M*{other}'
def __rmul__(self, other):
return f'{other}*M'
class TestVec2D(VectorComparisonMixin, unittest.TestCase):
def test_constructor(self):
vec = Vec2D(0.5, 2)
self.assertEqual(vec[0], 0.5)
self.assertEqual(vec[1], 2)
self.assertIsInstance(vec, Vec2D)
self.assertRaises(TypeError, Vec2D)
self.assertRaises(TypeError, Vec2D, 0)
self.assertRaises(TypeError, Vec2D, (0, 1))
self.assertRaises(TypeError, Vec2D, vec)
self.assertRaises(TypeError, Vec2D, 0, 1, 2)
def test_repr(self):
vec = Vec2D(0.567, 1.234)
self.assertEqual(repr(vec), '(0.57,1.23)')
def test_equality(self):
vec1 = Vec2D(0, 1)
vec2 = Vec2D(0.0, 1)
vec3 = Vec2D(42, 1)
self.assertEqual(vec1, vec2)
self.assertEqual(vec1, tuple(vec1))
self.assertEqual(tuple(vec1), vec1)
self.assertNotEqual(vec1, vec3)
self.assertNotEqual(vec2, vec3)
def test_pickling(self):
vec = Vec2D(0.5, 2)
for proto in range(pickle.HIGHEST_PROTOCOL + 1):
with self.subTest(proto=proto):
pickled = pickle.dumps(vec, protocol=proto)
unpickled = pickle.loads(pickled)
self.assertEqual(unpickled, vec)
self.assertIsInstance(unpickled, Vec2D)
def _assert_arithmetic_cases(self, test_cases, lambda_operator):
for test_case in test_cases:
with self.subTest(case=test_case):
((first, second), expected) = test_case
op1 = Vec2D(*first)
op2 = Vec2D(*second)
result = lambda_operator(op1, op2)
expected = Vec2D(*expected)
self.assertVectorsAlmostEqual(result, expected)
def test_vector_addition(self):
test_cases = [
(((0, 0), (1, 1)), (1.0, 1.0)),
(((-1, 0), (2, 2)), (1, 2)),
(((1.5, 0), (1, 1)), (2.5, 1)),
]
self._assert_arithmetic_cases(test_cases, lambda x, y: x + y)
def test_vector_subtraction(self):
test_cases = [
(((0, 0), (1, 1)), (-1, -1)),
(((10.625, 0.125), (10, 0)), (0.625, 0.125)),
]
self._assert_arithmetic_cases(test_cases, lambda x, y: x - y)
def test_vector_multiply(self):
vec1 = Vec2D(10, 10)
vec2 = Vec2D(0.5, 3)
answer = vec1 * vec2
expected = 35
self.assertAlmostEqual(answer, expected)
vec = Vec2D(0.5, 3)
expected = Vec2D(5, 30)
self.assertVectorsAlmostEqual(vec * 10, expected)
self.assertVectorsAlmostEqual(10 * vec, expected)
self.assertVectorsAlmostEqual(vec * 10.0, expected)
self.assertVectorsAlmostEqual(10.0 * vec, expected)
M = Multiplier()
self.assertEqual(vec * M, Vec2D(f"{vec[0]}*M", f"{vec[1]}*M"))
self.assertEqual(M * vec, f'M*{vec}')
def test_vector_negative(self):
vec = Vec2D(10, -10)
expected = (-10, 10)
self.assertVectorsAlmostEqual(-vec, expected)
def test_distance(self):
self.assertEqual(abs(Vec2D(6, 8)), 10)
self.assertEqual(abs(Vec2D(0, 0)), 0)
self.assertAlmostEqual(abs(Vec2D(2.5, 6)), 6.5)
def test_rotate(self):
cases = [
(((0, 0), 0), (0, 0)),
(((0, 1), 90), (-1, 0)),
(((0, 1), -90), (1, 0)),
(((1, 0), 180), (-1, 0)),
(((1, 0), 360), (1, 0)),
]
for case in cases:
with self.subTest(case=case):
(vec, rot), expected = case
vec = Vec2D(*vec)
got = vec.rotate(rot)
self.assertVectorsAlmostEqual(got, expected)
class TestTNavigator(VectorComparisonMixin, unittest.TestCase):
def setUp(self):
self.nav = turtle.TNavigator()
def test_goto(self):
self.nav.goto(100, -100)
self.assertAlmostEqual(self.nav.xcor(), 100)
self.assertAlmostEqual(self.nav.ycor(), -100)
def test_pos(self):
self.assertEqual(self.nav.pos(), self.nav._position)
self.nav.goto(100, -100)
self.assertEqual(self.nav.pos(), self.nav._position)
def test_left(self):
self.assertEqual(self.nav._orient, (1.0, 0))
self.nav.left(90)
self.assertVectorsAlmostEqual(self.nav._orient, (0.0, 1.0))
def test_right(self):
self.assertEqual(self.nav._orient, (1.0, 0))
self.nav.right(90)
self.assertVectorsAlmostEqual(self.nav._orient, (0, -1.0))
def test_reset(self):
self.nav.goto(100, -100)
self.assertAlmostEqual(self.nav.xcor(), 100)
self.assertAlmostEqual(self.nav.ycor(), -100)
self.nav.reset()
self.assertAlmostEqual(self.nav.xcor(), 0)
self.assertAlmostEqual(self.nav.ycor(), 0)
def test_forward(self):
self.nav.forward(150)
expected = Vec2D(150, 0)
self.assertVectorsAlmostEqual(self.nav.position(), expected)
self.nav.reset()
self.nav.left(90)
self.nav.forward(150)
expected = Vec2D(0, 150)
self.assertVectorsAlmostEqual(self.nav.position(), expected)
self.assertRaises(TypeError, self.nav.forward, 'skldjfldsk')
def test_backwards(self):
self.nav.back(200)
expected = Vec2D(-200, 0)
self.assertVectorsAlmostEqual(self.nav.position(), expected)
self.nav.reset()
self.nav.right(90)
self.nav.back(200)
expected = Vec2D(0, 200)
self.assertVectorsAlmostEqual(self.nav.position(), expected)
def test_distance(self):
self.nav.forward(100)
expected = 100
self.assertAlmostEqual(self.nav.distance(Vec2D(0,0)), expected)
def test_radians_and_degrees(self):
self.nav.left(90)
self.assertAlmostEqual(self.nav.heading(), 90)
self.nav.radians()
self.assertAlmostEqual(self.nav.heading(), 1.57079633)
self.nav.degrees()
self.assertAlmostEqual(self.nav.heading(), 90)
def test_towards(self):
coordinates = [
# coordinates, expected
((100, 0), 0.0),
((100, 100), 45.0),
((0, 100), 90.0),
((-100, 100), 135.0),
((-100, 0), 180.0),
((-100, -100), 225.0),
((0, -100), 270.0),
((100, -100), 315.0),
]
for (x, y), expected in coordinates:
self.assertEqual(self.nav.towards(x, y), expected)
self.assertEqual(self.nav.towards((x, y)), expected)
self.assertEqual(self.nav.towards(Vec2D(x, y)), expected)
def test_heading(self):
self.nav.left(90)
self.assertAlmostEqual(self.nav.heading(), 90)
self.nav.left(45)
self.assertAlmostEqual(self.nav.heading(), 135)
self.nav.right(1.6)
self.assertAlmostEqual(self.nav.heading(), 133.4)
self.assertRaises(TypeError, self.nav.right, 'sdkfjdsf')
self.nav.reset()
rotations = [10, 20, 170, 300]
result = sum(rotations) % 360
for num in rotations:
self.nav.left(num)
self.assertEqual(self.nav.heading(), result)
self.nav.reset()
result = (360-sum(rotations)) % 360
for num in rotations:
self.nav.right(num)
self.assertEqual(self.nav.heading(), result)
self.nav.reset()
rotations = [10, 20, -170, 300, -210, 34.3, -50.2, -10, -29.98, 500]
sum_so_far = 0
for num in rotations:
if num < 0:
self.nav.right(abs(num))
else:
self.nav.left(num)
sum_so_far += num
self.assertAlmostEqual(self.nav.heading(), sum_so_far % 360)
def test_setheading(self):
self.nav.setheading(102.32)
self.assertAlmostEqual(self.nav.heading(), 102.32)
self.nav.setheading(-123.23)
self.assertAlmostEqual(self.nav.heading(), (-123.23) % 360)
self.nav.setheading(-1000.34)
self.assertAlmostEqual(self.nav.heading(), (-1000.34) % 360)
self.nav.setheading(300000)
self.assertAlmostEqual(self.nav.heading(), 300000%360)
def test_positions(self):
self.nav.forward(100)
self.nav.left(90)
self.nav.forward(-200)
self.assertVectorsAlmostEqual(self.nav.pos(), (100.0, -200.0))
def test_setx_and_sety(self):
self.nav.setx(-1023.2334)
self.nav.sety(193323.234)
self.assertVectorsAlmostEqual(self.nav.pos(), (-1023.2334, 193323.234))
def test_home(self):
self.nav.left(30)
self.nav.forward(-100000)
self.nav.home()
self.assertVectorsAlmostEqual(self.nav.pos(), (0,0))
self.assertAlmostEqual(self.nav.heading(), 0)
def test_distance_method(self):
self.assertAlmostEqual(self.nav.distance(30, 40), 50)
vec = Vec2D(0.22, .001)
self.assertAlmostEqual(self.nav.distance(vec), 0.22000227271553355)
another_turtle = turtle.TNavigator()
another_turtle.left(90)
another_turtle.forward(10000)
self.assertAlmostEqual(self.nav.distance(another_turtle), 10000)
class TestTPen(unittest.TestCase):
def test_pendown_and_penup(self):
tpen = turtle.TPen()
self.assertTrue(tpen.isdown())
tpen.penup()
self.assertFalse(tpen.isdown())
tpen.pendown()
self.assertTrue(tpen.isdown())
def test_showturtle_hideturtle_and_isvisible(self):
tpen = turtle.TPen()
self.assertTrue(tpen.isvisible())
tpen.hideturtle()
self.assertFalse(tpen.isvisible())
tpen.showturtle()
self.assertTrue(tpen.isvisible())
if __name__ == '__main__':
unittest.main()