def test_adding(self):
"""Test adding functionality"""
adder = Adder()
for i in range(-10, 10):
for j in range(-10, 10):
self.assertEqual(i + j, adder.calc(i, j))
def setUp(self):
self.adder = Adder()
self.subtracter = Subtracter()
self.multiplier = Multiplier()
self.divider = Divider()
self.calculator = Calculator(self.adder, self.subtracter,
self.multiplier, self.divider)
def test_module(self):
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(5)
calculator.enter_number(2)
calculator.multiply()
calculator.enter_number(46)
calculator.add()
calculator.enter_number(8)
calculator.divide()
calculator.enter_number(1)
result = calculator.subtract()
self.assertEqual(6, result)
# pulled from the unittest file, testing that there is not
# a missing operand
with self.assertRaises(InsufficientOperands):
calculator.add()
def __init__(self):
self.output = []
self.shift_register1 = Lfsr(input("seed for the first RFSR:"),[8,12,20,25])
self.shift_register2 = Lfsr(input("seed for the second RFSR:"),[21,16,24,31])
self.shift_register3 = Lfsr(input("seed for the third RFSR:"),[4,24,28,33])
self.shift_register4 = Lfsr(input("seed for the fourth RFSR:"),[4,28,36,39])
self.r1 = Register(input("seed for the register R1:"))
self.r2 = Register(self.r1.output)
self.t1 = InternalState()
self.t2 = InternalState()
self.adder1 = Adder()
self.adder2 = Adder()
self.iz = Iz()
self.xor_iz_t2 = Xor([self.t2.output,self.iz.output])
self.xor_t1_xor = Xor([self.t1.output,self.xor_iz_t2.output])
self.xor_zt = Xor([self.shift_register1.output,self.shift_register2.output,
self.shift_register3.output,self.shift_register4.output,self.r1.least_significant()])
def test_adder_meta():
now = datetime.datetime.now()
date_time = str(now).split(' ')
current_date = date_time[0]
add = Adder(current_date, '22:00:00')
conn = sqlite3.connect('src/weather.db')
add.add_meta_weather_forecasts(conn)
def test_multiplication(self):
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(10)
calculator.enter_number(12)
result = calculator.multiply()
self.assertEqual(120, result)
del calculator
def test_subtraction(self):
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(-2)
calculator.enter_number(10)
result = calculator.add()
self.assertEqual(8, result)
del calculator
def test_subtraction_error(self):
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(24)
calculator.enter_number(12)
result = calculator.subtract()
self.assertEqual(12, result)
del calculator
def test_division(self):
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(2)
calculator.enter_number(10)
result = calculator.divide()
self.assertEqual(5, result)
del calculator
def setUp(self):
"""Setup function to add modules to calculator"""
self.adder = Adder()
self.subtracter = Subtracter()
self.multiplier = Multiplier()
self.divider = Divider()
self.calculator = Calculator(self.adder, self.subtracter,
self.multiplier, self.divider)
def test_adder_owp_stress():
now = datetime.datetime.now()
date_time = str(now).split(' ')
current_date = date_time[0]
for i in range(0, 200):
add = Adder(current_date, '22:00:00')
conn = sqlite3.connect('src/weather.db')
add.add_owp_forecasts(conn)
conn.close()
def final_order(self):
self._strategy.order_type = self._order_type
bp = self.calculate_bonus_pack()
milk = bp * self._strategy.calculate_bonus_on('milk')
dark = bp * self._strategy.calculate_bonus_on('dark')
white = bp * self._strategy.calculate_bonus_on('white')
bonus = [milk, dark, white]
initial_purchase = self.calculate_initial_buy()
adder = Adder(self._order_type, initial_purchase)
self._adder_final_no_text = adder.adder(bonus)
r = adder.adder(bonus)
return 'milk {},dark {},white {}'.format(r[0], r[1], r[2])
def test_module(self):
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(3)
calculator.enter_number(4)
self.assertEqual(12, calculator.multiply())
calculator.enter_number(2)
self.assertEqual(10, calculator.subtract())
calculator.enter_number(10)
self.assertEqual(calculator.add(), 20)
calculator.enter_number(5)
result = calculator.divide()
self.assertEqual(4, result)
def test_module(self):
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(5)
calculator.enter_number(2)
calculator.multiply()
calculator.enter_number(46)
calculator.add()
calculator.enter_number(8)
calculator.divide()
calculator.enter_number(1)
result = calculator.subtract()
self.assertEqual(6, result)
def test_module(self):
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(5)
calculator.enter_number(2)
r1 = calculator.multiply()
print('multiplication result:', r1)
calculator.enter_number(46)
r2 = calculator.add()
print('addition result:', r2)
calculator.enter_number(8)
r3 = calculator.divide()
print('division result:', r3)
calculator.enter_number(1)
result = calculator.subtract()
print('result after final step of subtraction:', result)
self.assertEqual(6, result)
def test_modules(self):
"""Function to test each of the modules and function calls"""
calculator = Calculator(Adder(), Subtracter(), Multiplier(), Divider())
calculator.enter_number(5)
calculator.enter_number(2)
calculator.multiply()
calculator.enter_number(46)
calculator.add()
calculator.enter_number(8)
calculator.divide()
calculator.enter_number(1)
result = calculator.subtract()
self.assertEqual(6, result)
def test_adding(self):
adder = Adder()
for i in range(-10, 10):
for j in range(-10, 10):
self.assertEqual(i + j, adder.calc(i, j))
expected = [(a + b) & mask for a, b in zip(data_a, data_b)]
# for a, b, r in zip(data_a, data_b, expected):
# dut._log.info("[a]:{:02X}, [b]:{:02X}, [r]:{:02X}".format(a, b, r))
send_a = cocotb.fork(stream_input_a.send(data_a))
send_b = cocotb.fork(stream_input_b.send(data_b))
send_a.join()
send_b.join()
received = await stream_output.recv(N)
for expctd, rcvd in zip(expected, received):
if expctd != rcvd:
dut._log.info("Expected {} Got {}".format(expctd, rcvd))
raise TestFailure("Test failed")
raise TestSuccess("Test passed")
if __name__ == '__main__':
core = Adder(5)
run(core,
'test_adder',
ports=[
*list(core.a.fields.values()), *list(core.b.fields.values()),
*list(core.r.fields.values())
],
vcd_file='adder.vcd')
def test_adder_unreal_temp():
adder = Adder('2000-06-13', '22:00:00')
conn = sqlite3.connect('src/weather.db')
with pytest.raises(ValueError):
adder.add_real_weather(conn, '+1000000000000000')
def test_adder():
from adder import Adder
assert Adder(3).add(5) == 8
assert Adder(2).add(7) == 9
def test_adder_incorrect_input_temp_2():
adder = Adder('2000-06-13', '22:00:00')
conn = sqlite3.connect('src/weather.db')
with pytest.raises(ValueError):
adder.add_real_weather(conn, '+2q')
def test_adding(self):
adder = Adder()
for x in range(-5, 10):
for y in range(-5, 10):
self.assertEqual(x + y, adder.calc(x, y))
def test_sum_list(self):
self.assertEqual(Adder().sum_list([1, 2, 3]), 6)
def test_sum(self):
self.assertEqual(Adder().sum(1, 2), 3)
from step import Step
from adder import Adder
from scheduler import Scheduler
import component
import math
if __name__ == "__main__":
print("------------------------------\n")
print("t = 0")
step1 = Step(0.65, 1, -3, "01")
step2 = Step(0.35, 0, 1, "02")
step3 = Step(1, 0, 1, "03")
step4 = Step(1.5, 0, 4, "04")
adder = Adder(math.inf)
print(component.components)
port1 = component.Port(step1, [adder], "01")
port2 = component.Port(step2, [adder], "02")
port3 = component.Port(step3, [adder], "03")
port4 = component.Port(step4, [adder], "04")
step1.set_port(port1.name, port1)
step2.set_port(port2.name, port2)
step3.set_port(port3.name, port3)
step4.set_port(port4.name, port4)
adder.set_port(port1.name, port1)
adder.set_port(port4.name, port4)
from nmigen_cocotb import run
from adder import Adder
if __name__ == '__main__':
#inicializo el adder con la cantidad de bits que quiero en las entradas/salida. Luego corro los tests que se encuentran en test.py y se guarda la waveform
core = Adder(3)
run(core,
'test',
ports=[
*list(core.a.fields.values()), *list(core.b.fields.values()),
*list(core.r.fields.values())
],
vcd_file='adder.vcd')
from step import Step
from adder import Adder
from integrateur import Integrateur
from qss import Qss
from evenement import Evenement
import matplotlib.pyplot as plt
temps = 0
temps_fin = 10
liste_comp = [
Step(1, 1, -3, 0.65, [Evenement.XV]),
Step(2, 0, 1, 0.35, [Evenement.XV]),
Step(3, 0, 1, 1, [Evenement.XV]),
Step(4, 0, 4, 1.5, [Evenement.XV]),
Adder([Evenement.XV], [Evenement.X_POINT]),
Integrateur([Evenement.X_POINT], [Evenement.RES]),
Qss([Evenement.X_POINT], [Evenement.QI])
]
liste_points = []
liste_qss = []
liste_somme = []
liste_temps1 = []
liste_temps2 = []
liste_temps3 = []
while (temps <= temps_fin):
ta_min = liste_comp[0].get_ta()
for i in range(1, len(liste_comp)):
tmp = liste_comp[i].get_ta()
if ta_min > tmp:
ta_min = tmp
def test_adder(self):
a = Adder(data=[])
self.assertRaises(NotImplementedError, a.add, [])
def test_formatter(self):
formatter = Adder('white', 3)
print("test_formatter...\n\n")
print(formatter.out)
result = list(map(add, formatter.out, formatter.out))
self.assertEqual(result, formatter.adder(formatter.out))
########################################
# This is a python script file
# This fill calls Adder class.
########################################
import sys
from adder import Adder
if len(sys.argv) is not 3:
raise ValueError("please give two command line args.");
else:
a = int( sys.argv[1] )
b = int( sys.argv[2] )
print Adder(a,b).sum()