def test_function_100times_eq_100q():
q1 = Qualean(random.choice(states))
new_q = Qualean(0)
for _ in range(100):
new_q += q1.q
assert math.isclose(new_q, q1 * 100, rel_tol=1e-4)
def test_qualean_lt():
q1, q2 = Qualean(1), Qualean(0)
if q1.number > 0:
q1 = q1.__invertsign__()
assert q1 < q2
def test_qualean_value():
q1 = Qualean(1)
q2 = Qualean(0)
q3 = Qualean(-1)
assert q1.number >= -1 and q1.number <= 1
assert q2.number == 0
assert q3.number >= -1 and q1.number <= 1
def test_qualean_gt():
q1, q2 = Qualean(1), Qualean(0)
if q1.number < 0:
q1 = q1.__invertsign__()
assert q1 > q2
def test_qualean_le():
q1, q2, q3 = Qualean(1), Qualean(0), Qualean(0)
if q1.number > 0:
q1 = q1.__invertsign__()
assert q1 <= q2
assert q2 <= q3
def test_qualean_ge():
q1, q2, q3 = Qualean(1), Qualean(0), Qualean(0)
if q1.number < 0:
q1 = q1.__invertsign__()
assert q1 >= q2
assert q2 >= q3
def test_qualean_sqrt():
decimal.getcontext().prec = 10
sign = lambda x : copysign(1.0, x)
q = Qualean(-1)
if q.number < 0:
q = q.__invertsign__()
assert q.__sqrt__() == Decimal(q.number).sqrt()
def test_addition():
num = random.choice([-1, 0, 1])
q = Qualean(num)
sum_of_q = Qualean(0)
for i in range(100):
sum_of_q = q + sum_of_q
# print(sum_of_q)
# return sum_of_q
# return sum_of_q == q*100
# print(sum_of_q,q*100)
# return sum_of_q == q *100
assert sum_of_q == q * 100, "summing of q 100 times is equal to q multiplied by 100"
def test_qualean_and():
q1 = Qualean(1)
q2 = Qualean(0)
q3 = Qualean(-1)
i = 113
if q1 and q3:
assert q1.__and__(q3)
assert not q1.__and__(q2)
assert not q3.__and__(q2)
assert not q2.__and__(i)
def test_qualean_or():
q1 = Qualean(1)
q2 = Qualean(0)
q3 = Qualean(-1)
i = 113
if q1 or q3:
assert q1.__or__(q3)
assert q1.__or__(q2)
assert q3.__or__(q2)
if q1:
assert q1.__or__(i)
def test_million_q_sum():
result = 0
for _ in range(0,1000000):
x = random.choice([0, -1, 1])
result += Qualean(x).number
assert math.isclose(result, 0, abs_tol = 1000), ("not nearing to 0", result)
def test_repetitive_addition_multiplication():
q = Qualean(random.choice([0, -1, 1]))
res = 0
for _ in range(0, 100):
res += q.number
assert round(res,10) == round(100 * q.number,10)
def test_function_decimal_sqrt_check():
q1 = Qualean(1)
Decimal_Test=False
print(Decimal_Test)
if q1.q >= 0:
with decimal.localcontext() as ctx:
ctx.prec = 10
ctx.rounding = decimal.ROUND_HALF_EVEN
if q1.__sqrt__() == Decimal(str(q1)).sqrt(context=ctx):
Decimal_Test=True
pass
else:
pass
else:
Decimal_Test= True
print(Decimal_Test)
assert Decimal_Test == True, "Check your the function"
def test_invertsign():
q1 = Qualean(random.choice([-1, 0, 1]))
if q1.get_number() < 0:
assert (q1.__invertsign__() > 0) == True, "invertsign not working"
elif q1.get_number() > 0:
assert (q1.__invertsign__() < 0) == True, "invertsign not working"
else:
assert (q1.__invertsign__() == 0) == True, "invertsign not working"
def test_function_sum_million_q_eq_zero():
q1 = 0
TEST_million = True
for x in range(100001):
q = random.choice(states)
q = Qualean(q)
q1 = q1 + q.q
print(q1)
else:
if math.isclose(q1, 0):
TEST_million=False
assert TEST_million== True, 'Check'
def test_or_functionality():
q1 = Qualean(random.choice([-1, 0, 1]))
q2 = Qualean(random.choice([-1, 0, 1]))
if q1.get_number() != 0 or q2.get_number() != 0:
assert q1 | q2 == True, "or True case is not working as expected"
else:
assert q1 | q2 == False, "or False case is not working as expected"
def test_lt():
q1 = Qualean(random.choice([-1, 0, 1]))
q2 = Qualean(random.choice([-1, 0, 1]))
if q1.get_number() < q2.get_number():
assert (q1 < q2) == True, "__lt__ True case not working"
else:
assert (q1 < q2) == False, "__lt__ False case not working"
def test_ge():
q1 = Qualean(random.choice([-1, 0, 1]))
q2 = Qualean(random.choice([-1, 0, 1]))
if q1.get_number() >= q2.get_number():
# print(q1.get_number())
# print(q2.get_number())
# print(True)
assert (q1 >= q2) == True, "__ge__ True case not working"
else:
# print(q1.get_number())
# print(q2.get_number())
# print(False)
assert (q1 >= q2) == False, "__ge__ False case not working"
def test_function_equality_true():
q1 = Qualean(random.choice(states))
assert q1 == q1
def test_function_bool():
q1 = Qualean(1)
assert bool(q1)
q1 = Qualean(0)
assert not bool(q1)
def test_function_add():
q1 = Qualean(random.choice(states))
q2 = Qualean(random.choice(states))
assert math.isclose(q1.__add__(q2), q1.q+q2.q, rel_tol=1e-8 )
def test_function_str():
assert "object at" not in Qualean(random.choice(states)).__str__()
def test_function_invalid_integer_input():
with pytest.raises(ValueError) as execinfo:
_ = Qualean(2)
assert "ValueError" in str(execinfo)
def test_function_valid_input():
q1 = Qualean(random.choice(states))
assert isinstance(q1, Qualean)
def test_function_equality_false():
q1 = Qualean(1)
q2 = Qualean(0)
assert not q1 == q2
def test_function_less_than_equal_to():
q1 = Qualean(random.choice(states))
assert q1 <= q1 + 1
def test_function_lesser_than():
q1 = Qualean(random.choice(states))
assert q1 < q1 + 1
def test_function_greater_than_equal_to():
q1 = Qualean(random.choice(states))
assert q1 + 1 >= q1
def test_function_greater():
q1 = Qualean(random.choice(states))
assert q1 + 1 > q1
def test_function_float_conversion():
q1 = Qualean(random.choice(states))
assert isinstance(q1.__float__(), float)
