def test_get_merged_different_hamiltonian():
hamiltonian = QubitOperator("Z2", 2)
gate = te.TimeEvolution(2, hamiltonian)
hamiltonian2 = QubitOperator("Y2", 2)
gate2 = te.TimeEvolution(2, hamiltonian2)
with pytest.raises(NotMergeable):
gate.get_merged(gate2)
def test_get_merged_not_close_enough():
hamiltonian = QubitOperator("Z2", 2)
hamiltonian += QubitOperator("X3", 1)
gate = te.TimeEvolution(2, hamiltonian)
hamiltonian2 = QubitOperator("Z2", 4)
hamiltonian2 += QubitOperator("X3", 2 + 1e-8)
gate2 = te.TimeEvolution(5, hamiltonian2)
with pytest.raises(NotMergeable):
gate.get_merged(gate2)
def test_get_merged_one_term():
hamiltonian = QubitOperator("Z2", 2)
gate = te.TimeEvolution(2, hamiltonian)
hamiltonian2 = QubitOperator("Z2", 4)
gate2 = te.TimeEvolution(5, hamiltonian2)
merged = gate.get_merged(gate2)
# This is not a requirement, the hamiltonian could also be the other
# if we change implementation
assert merged.hamiltonian.isclose(hamiltonian)
assert merged.time == pytest.approx(12)
def test_or_not_enough_qubits():
saving_backend = DummyEngine(save_commands=True)
eng = MainEngine(backend=saving_backend, engine_list=[])
qureg = eng.allocate_qureg(2)
hamiltonian = QubitOperator("Z0 X3", 2)
with pytest.raises(ValueError):
te.TimeEvolution(2.1, hamiltonian) | qureg
def test_or_two_qubits_error():
saving_backend = DummyEngine(save_commands=True)
eng = MainEngine(backend=saving_backend, engine_list=[])
qureg = eng.allocate_qureg(2)
hamiltonian = QubitOperator("Z0", 2)
with pytest.raises(TypeError):
te.TimeEvolution(2.1, hamiltonian) | (qureg[0], qureg[1])
def test_get_inverse():
hamiltonian = QubitOperator("Z2", 2)
gate = te.TimeEvolution(2, hamiltonian)
inverse = gate.get_inverse()
assert gate.time == 2
assert gate.hamiltonian.isclose(hamiltonian)
assert inverse.time == -2
assert inverse.hamiltonian.isclose(hamiltonian)
def test_or_one_qubit():
saving_backend = DummyEngine(save_commands=True)
eng = MainEngine(backend=saving_backend, engine_list=[])
qubit = eng.allocate_qubit()
hamiltonian = QubitOperator("Z0", 2)
te.TimeEvolution(2.1, hamiltonian) | qubit[0]
te.TimeEvolution(3, hamiltonian) | (qubit[0], )
eng.flush()
cmd1 = saving_backend.received_commands[1]
assert cmd1.gate.hamiltonian.isclose(hamiltonian)
assert cmd1.gate.time == pytest.approx(2.1)
assert len(cmd1.qubits) == 1 and len(cmd1.qubits[0]) == 1
assert cmd1.qubits[0][0].id == qubit[0].id
cmd2 = saving_backend.received_commands[2]
assert cmd2.gate.hamiltonian.isclose(hamiltonian)
assert cmd2.gate.time == pytest.approx(3)
assert len(cmd2.qubits) == 1 and len(cmd2.qubits[0]) == 1
assert cmd2.qubits[0][0].id == qubit[0].id
def test_or_one_qureg():
saving_backend = DummyEngine(save_commands=True)
eng = MainEngine(backend=saving_backend, engine_list=[])
qureg = eng.allocate_qureg(5)
hamiltonian = QubitOperator("X0 Z4", 2)
te.TimeEvolution(2.1, hamiltonian) | qureg
te.TimeEvolution(3, hamiltonian) | (qureg, )
eng.flush()
rescaled_h = QubitOperator("X0 Z1", 2)
cmd1 = saving_backend.received_commands[5]
assert cmd1.gate.hamiltonian.isclose(rescaled_h)
assert cmd1.gate.time == pytest.approx(2.1)
assert len(cmd1.qubits) == 1 and len(cmd1.qubits[0]) == 2
assert cmd1.qubits[0][0].id == qureg[0].id
assert cmd1.qubits[0][1].id == qureg[4].id
cmd2 = saving_backend.received_commands[6]
assert cmd2.gate.hamiltonian.isclose(rescaled_h)
assert cmd2.gate.time == pytest.approx(3)
assert len(cmd2.qubits) == 1 and len(cmd2.qubits[0]) == 2
assert cmd2.qubits[0][0].id == qureg[0].id
assert cmd2.qubits[0][1].id == qureg[4].id
def test_or_gate_not_mutated():
saving_backend = DummyEngine(save_commands=True)
eng = MainEngine(backend=saving_backend, engine_list=[])
qureg = eng.allocate_qureg(4)
hamiltonian = QubitOperator("X0 Z3", 2)
hamiltonian += QubitOperator("Y1", 0.5)
correct_h = copy.deepcopy(hamiltonian)
gate = te.TimeEvolution(2.1, hamiltonian)
gate | qureg
eng.flush()
assert gate.hamiltonian.isclose(correct_h)
assert gate.time == pytest.approx(2.1)
def test_or_gate_identity():
saving_backend = DummyEngine(save_commands=True)
eng = MainEngine(backend=saving_backend, engine_list=[])
qureg = eng.allocate_qureg(4)
hamiltonian = QubitOperator((), 3.4)
correct_h = copy.deepcopy(hamiltonian) # noqa: F841
gate = te.TimeEvolution(2.1, hamiltonian)
gate | qureg
eng.flush()
cmd = saving_backend.received_commands[4]
assert isinstance(cmd.gate, Ph)
assert cmd.gate == Ph(-3.4 * 2.1)
correct = numpy.array([[cmath.exp(-1j * 3.4 * 2.1), 0],
[0, cmath.exp(-1j * 3.4 * 2.1)]])
print(correct)
print(cmd.gate.matrix)
assert numpy.allclose(cmd.gate.matrix, correct)
def test_or_multiple_terms():
saving_backend = DummyEngine(save_commands=True)
eng = MainEngine(backend=saving_backend, engine_list=[])
qureg = eng.allocate_qureg(4)
hamiltonian = QubitOperator("X0 Z3", 2)
hamiltonian += QubitOperator("Y1", 0.5)
te.TimeEvolution(2.1, hamiltonian) | qureg
eng.flush()
rescaled_h = QubitOperator("X0 Z2", 2)
rescaled_h += QubitOperator("Y1", 0.5)
cmd1 = saving_backend.received_commands[4]
assert cmd1.gate.hamiltonian.isclose(rescaled_h)
assert cmd1.gate.time == pytest.approx(2.1)
assert len(cmd1.qubits) == 1 and len(cmd1.qubits[0]) == 3
assert cmd1.qubits[0][0].id == qureg[0].id
assert cmd1.qubits[0][1].id == qureg[1].id
assert cmd1.qubits[0][2].id == qureg[3].id
def test_init_not_hermitian():
hamiltonian = QubitOperator("Z2", 1e-12j)
with pytest.raises(te.NotHermitianOperatorError):
te.TimeEvolution(1, hamiltonian)
def test_init_bad_hamiltonian():
with pytest.raises(TypeError):
te.TimeEvolution(2, "something else")
def test_init_bad_time():
hamiltonian = QubitOperator("Z2", 0.5)
with pytest.raises(TypeError):
te.TimeEvolution(1.5j, hamiltonian)
def test_init_makes_copy():
hamiltonian = QubitOperator("X0 Z1")
gate = te.TimeEvolution(2.1, hamiltonian)
hamiltonian = None
assert gate.hamiltonian is not None
def test_init_float_time(coefficient):
hamiltonian = coefficient * QubitOperator("X0 Z1")
hamiltonian += QubitOperator("Z2", 0.5)
gate2 = te.TimeEvolution(2.1, hamiltonian)
assert gate2.hamiltonian.isclose(hamiltonian)
assert gate2.time == pytest.approx(2.1)
def test_ne_not_implemented():
hamiltonian = QubitOperator("X0 Z1")
gate = te.TimeEvolution(2.1, hamiltonian)
assert gate.__ne__("0") == NotImplemented
def test_init_cast_complex_to_float():
hamiltonian = QubitOperator("Z2", 2 + 0j)
gate = te.TimeEvolution(1, hamiltonian)
assert isinstance(gate.hamiltonian.terms[((2, 'Z'), )], float)
pytest.approx(gate.hamiltonian.terms[((2, 'Z'), )]) == 2.0
def test_init_negative_time():
hamiltonian = QubitOperator("Z2", 2)
gate = te.TimeEvolution(-1, hamiltonian)
assert gate.time == -1
def test_get_merged_bad_gate():
hamiltonian = QubitOperator("Z2", 2)
gate = te.TimeEvolution(2, hamiltonian)
other = BasicGate()
with pytest.raises(NotMergeable):
gate.get_merged(other)
def test_str():
hamiltonian = QubitOperator("X0 Z1")
hamiltonian += QubitOperator("Y1", 0.5)
gate = te.TimeEvolution(2.1, hamiltonian)
assert str(gate) == "exp(-2.1j * (0.5 Y1 +\n1.0 X0 Z1))" or str(
gate) == "exp(-2.1j * (1.0 X0 Z1 +\n0.5 Y1))"
def test_time_evolution_init_int_time(coefficient):
hamiltonian = coefficient * QubitOperator("X0 Z1")
hamiltonian += QubitOperator("Z2", 0.5)
gate1 = te.TimeEvolution(2, hamiltonian)
assert gate1.hamiltonian.isclose(hamiltonian)
assert gate1.time == 2
