def test_rotated_toric_pauli_path(size, a_index, b_index):
code = RotatedToricCode(*size)
pauli = code.new_pauli().path(a_index, b_index)
syndrome = pt.bsp(pauli.to_bsf(), code.stabilizers.T)
syndrome_indices = code.syndrome_to_plaquette_indices(syndrome)
if a_index == b_index:
assert len(syndrome_indices) == 0, 'Unexpected syndrome for null path'
else:
dim_y, dim_x = code.size
a_index = tuple(np.mod(a_index, (dim_x, dim_y)))
b_index = tuple(np.mod(b_index, (dim_x, dim_y)))
assert syndrome_indices == {a_index, b_index
}, 'Path does not give expected syndrome'
def test_run_ftp_measurement_error_probability_defaults(time_steps, error_probability, measurement_error_probability,
expected):
code = RotatedToricCode(4, 4)
error_model = BitPhaseFlipErrorModel()
decoder = RotatedToricSMWPMDecoder()
max_runs = 2
data = app.run_ftp(code, time_steps, error_model, decoder, error_probability, measurement_error_probability,
max_runs=max_runs)
assert data['measurement_error_probability'] == expected
def test_run_once_ftp_seeded():
code = RotatedToricCode(4, 4)
time_steps = 4
error_model = BitPhaseFlipErrorModel()
decoder = RotatedToricSMWPMDecoder()
error_probability = 0.15
data1 = app.run_once_ftp(code, time_steps, error_model, decoder, error_probability, rng=np.random.default_rng(5))
data2 = app.run_once_ftp(code, time_steps, error_model, decoder, error_probability, rng=np.random.default_rng(5))
assert data1['error_weight'] == data2['error_weight']
assert data1['success'] == data2['success']
assert np.array_equal(data1['logical_commutations'], data2['logical_commutations'])
assert np.array_equal(data1['custom_values'], data2['custom_values'])
def test_run_ftp_count(max_runs, max_failures):
code = RotatedToricCode(6, 6)
time_steps = 6
error_model = BitPhaseFlipErrorModel()
decoder = RotatedToricSMWPMDecoder()
error_probability = 0.05
data = app.run_ftp(code, time_steps, error_model, decoder, error_probability,
max_runs=max_runs, max_failures=max_failures) # no error raised
assert {'n_run', 'n_fail'} <= data.keys(), 'data={} missing count keys'
if max_runs is None and max_failures is None:
assert data['n_run'] == 1, 'n_run does not equal 1 when max_runs and max_failures unspecified'
if max_runs is not None:
assert data['n_run'] <= max_runs, ('n_run is not <= requested max_runs (data={}).'.format(data))
if max_failures is not None:
assert data['n_fail'] <= max_failures, ('n_fail is not <= requested max_failures (data={}).'.format(data))
def test_run_ftp_seeded():
code = RotatedToricCode(4, 4)
time_steps = 4
error_model = BitPhaseFlipErrorModel()
decoder = RotatedToricSMWPMDecoder()
error_probability = 0.15
max_runs = 5
random_seed = 5
data1 = app.run_ftp(code, time_steps, error_model, decoder, error_probability, max_runs=max_runs,
random_seed=random_seed)
data2 = app.run_ftp(code, time_steps, error_model, decoder, error_probability, max_runs=max_runs,
random_seed=random_seed)
# remove wall_time from data
for data in (data1, data2):
del data['wall_time']
assert data1 == data2, 'Identically seeded runs are not the same. '
def test_rotated_toric_code_new_invalid_parameters(rows, columns):
with pytest.raises((ValueError, TypeError),
match=r"^RotatedToricCode") as exc_info:
RotatedToricCode(rows, columns)
print(exc_info)
def test_rotated_toric_lattice_translation(size, a_index, b_index, expected):
assert RotatedToricCode(*size).translation(a_index, b_index) == expected
def test_rotated_toric_lattice_is_in_bounds(index, expected):
lattice = RotatedToricCode(4, 6)
assert lattice.is_in_bounds(index) == expected
def test_rotated_toric_code_properties(size):
code = RotatedToricCode(*size)
assert isinstance(code.label, str)
assert isinstance(repr(code), str)
def test_rotated_toric_lattice_is_x_plaquette(index, expected):
lattice = RotatedToricCode(2, 4)
assert lattice.is_x_plaquette(index) == expected
def test_rotated_toric_pauli_properties(size):
code = RotatedToricCode(*size)
pauli = code.new_pauli()
assert pauli.code == code
assert isinstance(repr(pauli), str)
assert isinstance(str(pauli), str)
def test_rotated_toric_code_logicals():
assert len(RotatedToricCode(4, 4).logicals) == 4
def test_run_ftp_invalid_parameters(time_steps, error_probability, measurement_error_probability):
with pytest.raises(ValueError) as exc_info:
app.run_ftp(RotatedToricCode(6, 6), time_steps, BitPhaseFlipErrorModel(), RotatedToricSMWPMDecoder(),
error_probability, measurement_error_probability, max_runs=2)
print(exc_info)
return 'fixed'
@pytest.mark.parametrize('code, error_model, decoder', [
# each code with each valid decoder
(Color666Code(5), DepolarizingErrorModel(), Color666MPSDecoder(chi=8)),
(FiveQubitCode(), DepolarizingErrorModel(), NaiveDecoder()),
(PlanarCode(5, 5), DepolarizingErrorModel(), PlanarCMWPMDecoder()),
(PlanarCode(5, 5), DepolarizingErrorModel(), PlanarMPSDecoder(chi=6)),
(PlanarCode(5, 5), DepolarizingErrorModel(), PlanarMWPMDecoder()),
(PlanarCode(5, 5), DepolarizingErrorModel(), PlanarRMPSDecoder(chi=6)),
(PlanarCode(4, 5), BitPhaseFlipErrorModel(), PlanarYDecoder()),
(RotatedPlanarCode(7, 7), DepolarizingErrorModel(), RotatedPlanarMPSDecoder(chi=8)),
(RotatedPlanarCode(7, 7), DepolarizingErrorModel(), RotatedPlanarRMPSDecoder(chi=8)),
(RotatedPlanarCode(7, 7), BiasedDepolarizingErrorModel(100), RotatedPlanarSMWPMDecoder()),
(RotatedToricCode(6, 6), BiasedDepolarizingErrorModel(100), RotatedToricSMWPMDecoder()),
(SteaneCode(), DepolarizingErrorModel(), NaiveDecoder()),
(ToricCode(5, 5), DepolarizingErrorModel(), ToricMWPMDecoder()),
# each generic noise model
(PlanarCode(5, 5), BiasedDepolarizingErrorModel(10), PlanarMPSDecoder(chi=6)),
(PlanarCode(5, 5), BiasedYXErrorModel(10), PlanarMPSDecoder(chi=6)),
(PlanarCode(5, 5), BitFlipErrorModel(), PlanarMPSDecoder(chi=6)),
(PlanarCode(5, 5), BitPhaseFlipErrorModel(), PlanarMPSDecoder(chi=6)),
(PlanarCode(5, 5), CenterSliceErrorModel((0.2, 0.8, 0), 0.5), PlanarMPSDecoder(chi=6)),
(PlanarCode(5, 5), DepolarizingErrorModel(), PlanarMPSDecoder(chi=6)),
(PlanarCode(5, 5), PhaseFlipErrorModel(), PlanarMPSDecoder(chi=6)),
])
def test_run_once(code, error_model, decoder):
error_probability = 0.15
data = app.run_once(code, error_model, decoder, error_probability) # no error raised
expected_key_cls = {'error_weight': int, 'success': bool, 'logical_commutations': np.ndarray,
def test_rotated_toric_code_n_k_d(size, expected):
code = RotatedToricCode(*size)
assert code.n_k_d == expected
((3, 0), True), # boundary x plaquette
((3, 2), True), # out-bounds x plaquette
((0, 0), False), # in-bounds z plaquette
((1, 1), False), # boundary z plaquette
((3, 1), False), # out-bounds z plaquette
])
def test_rotated_toric_lattice_is_x_plaquette(index, expected):
lattice = RotatedToricCode(2, 4)
assert lattice.is_x_plaquette(index) == expected
@pytest.mark.parametrize(
'lattice, expected',
[
# RotatedToricCode(row, cols), (max_site_x, max_site_y)
(RotatedToricCode(2, 2), (1, 1)),
(RotatedToricCode(4, 4), (3, 3)),
(RotatedToricCode(2, 4), (3, 1)),
(RotatedToricCode(4, 2), (1, 3)),
(RotatedToricCode(6, 6), (5, 5)),
(RotatedToricCode(4, 6), (5, 3)),
(RotatedToricCode(6, 4), (3, 5)),
])
def test_rotated_toric_lattice_bounds(lattice, expected):
assert lattice.bounds == expected
@pytest.mark.parametrize(
'index, expected',
[
((0, 1), True), # in-bounds left
def test_rotated_toric_code_stabilizers(size, expected):
assert len(RotatedToricCode(*size).stabilizers) == expected
def test_rotated_toric_lattice_size(size):
lattice = RotatedToricCode(*size)
assert lattice.size == size
def test_rotated_toric_code_validate(size):
code = RotatedToricCode(*size)
code.validate() # no error raised
(2, 4),
(4, 2),
(6, 6),
(4, 6),
(6, 4),
])
def test_rotated_toric_pauli_properties(size):
code = RotatedToricCode(*size)
pauli = code.new_pauli()
assert pauli.code == code
assert isinstance(repr(pauli), str)
assert isinstance(str(pauli), str)
@pytest.mark.parametrize('pauli', [
RotatedToricCode(4, 4).new_pauli(),
RotatedToricCode(4, 6).new_pauli().plaquette((1, 1)).plaquette((3, 2)),
RotatedToricCode(6, 6).new_pauli().logical_x1().plaquette(
(-1, 0)).plaquette((4, 1)),
RotatedToricCode(6, 4).new_pauli().logical_z1().plaquette(
(1, 5)).plaquette((3, -1)),
RotatedToricCode(8, 6).new_pauli().logical_x2().plaquette(
(0, 2)).plaquette((1, 1)),
RotatedToricCode(6, 8).new_pauli().logical_z2().plaquette(
(1, -1)).plaquette((2, 4)),
])
def test_rotated_toric_pauli_new_to_bsf(pauli):
assert pauli.code.new_pauli(pauli.to_bsf()) == pauli, (
'Conversion to_bsf+from_bsf does not result in equality.')
