def test_double_qubit_gates(self): test_q0 = __rand__(0, 2048) test_q1 = __rand__(0, 2048) test_gate = 'cx' test_targets = f'q[{test_q0}], q[{test_q1}]' expected_value = f'{test_gate} {test_targets};' actual_value = __g__.gate(test_gate, # Gate Spec test_q0, # TargetA Spec test_q1) # TargetB Spec self.assertEqual(expected_value, actual_value)
def test_measurements(self): # Initialize variables test_q = __rand__(0, 1024) test_c = __rand__(0, 1024) # Set expected value expected_measurements = f"measure q[{test_q}] -> c[{test_c}];" # Get actual value actual_measurements = __g__.measurement(test_q, test_c) # Check if actual and expected values match as they should self.assertEqual(expected_measurements, actual_measurements)
def test_triple_qubit_gates(self): test_q0 = __rand__(0, 2048) test_q1 = __rand__(0, 2048) test_q2 = __rand__(0, 2048) test_gate = 'cx' test_targets = f'q[{test_q0}], q[{test_q1}], q[{test_q2}]' expected_value = f'{test_gate} {test_targets};' actual_value = __g__.gate( test_gate, # Gate Spec test_q0, # TargetA Spec test_q1, # TargetB Spec test_q2) # TargetC Spec expected_equals_actual = __tc__.compare(expected_value, actual_value) self.assertEqual(expected_equals_actual, True)
def test_single_qubit_gates(self): test_q = __rand__(0,1024) expected_value = f"h q[{test_q}];" actual_value = __g__.gate('h', targetA=test_q) self.assertEqual(expected_value, actual_value)
def test_ry(self): nrand = 256 tgtA = __rand__(nrand) theta = float(__pi__ / 2) ry_gate = __g__.gate('ry', tgtA, theta=theta) expected_output = f'ry({theta}) q[{tgtA}];' self.assertEqual(expected_output, ry_gate)
def test_single_qubit_gates(self): test_q = __rand__(0, 1024) expected_value = f"h q[{test_q}];" actual_value = __g__.gate('h', targetA=test_q) actual_equals_expected = __tc__.compare(expected_value, actual_value) self.assertEqual(actual_equals_expected, True)