def test_device_deprecated():
q = cirq.LineQubit(0)
a = cirq.FrozenCircuit(cirq.X(q))
with cirq.testing.assert_deprecated(
cirq.circuits.circuit._DEVICE_DEP_MESSAGE, deadline='v0.15'):
_ = a.device
def wrap(*ops):
return cirq.CircuitOperation(cirq.FrozenCircuit(*ops))
def test_mapped_circuit_preserves_moments():
q0, q1 = cirq.LineQubit.range(2)
fc = cirq.FrozenCircuit(cirq.Moment(cirq.X(q0)), cirq.Moment(cirq.X(q1)))
op = cirq.CircuitOperation(fc)
assert op.mapped_circuit() == fc
assert op.repeat(3).mapped_circuit(deep=True) == fc * 3
def test_decompose_nested():
a, b, c, d = cirq.LineQubit.range(4)
exp1 = sympy.Symbol('exp1')
exp_half = sympy.Symbol('exp_half')
exp_one = sympy.Symbol('exp_one')
exp_two = sympy.Symbol('exp_two')
circuit1 = cirq.FrozenCircuit(cirq.X(a)**exp1, cirq.measure(a, key='m1'))
op1 = cirq.CircuitOperation(circuit1)
circuit2 = cirq.FrozenCircuit(
op1.with_qubits(a).with_measurement_key_mapping({'m1': 'ma'}),
op1.with_qubits(b).with_measurement_key_mapping({'m1': 'mb'}),
op1.with_qubits(c).with_measurement_key_mapping({'m1': 'mc'}),
op1.with_qubits(d).with_measurement_key_mapping({'m1': 'md'}),
)
op2 = cirq.CircuitOperation(circuit2)
circuit3 = cirq.FrozenCircuit(
op2.with_params({exp1: exp_half}),
op2.with_params({exp1: exp_one}),
op2.with_params({exp1: exp_two}),
)
op3 = cirq.CircuitOperation(circuit3)
final_op = op3.with_params({exp_half: 0.5, exp_one: 1.0, exp_two: 2.0})
expected_circuit1 = cirq.Circuit(
op2.with_params({
exp1: 0.5,
exp_half: 0.5,
exp_one: 1.0,
exp_two: 2.0
}),
op2.with_params({
exp1: 1.0,
exp_half: 0.5,
exp_one: 1.0,
exp_two: 2.0
}),
op2.with_params({
exp1: 2.0,
exp_half: 0.5,
exp_one: 1.0,
exp_two: 2.0
}),
)
result_ops1 = cirq.decompose_once(final_op)
assert cirq.Circuit(result_ops1) == expected_circuit1
expected_circuit = cirq.Circuit(
cirq.X(a)**0.5,
cirq.measure(a, key='ma'),
cirq.X(b)**0.5,
cirq.measure(b, key='mb'),
cirq.X(c)**0.5,
cirq.measure(c, key='mc'),
cirq.X(d)**0.5,
cirq.measure(d, key='md'),
cirq.X(a)**1.0,
cirq.measure(a, key='ma'),
cirq.X(b)**1.0,
cirq.measure(b, key='mb'),
cirq.X(c)**1.0,
cirq.measure(c, key='mc'),
cirq.X(d)**1.0,
cirq.measure(d, key='md'),
cirq.X(a)**2.0,
cirq.measure(a, key='ma'),
cirq.X(b)**2.0,
cirq.measure(b, key='mb'),
cirq.X(c)**2.0,
cirq.measure(c, key='mc'),
cirq.X(d)**2.0,
cirq.measure(d, key='md'),
)
assert cirq.Circuit(cirq.decompose(final_op)) == expected_circuit
# Verify that mapped_circuit gives the same operations.
assert final_op.mapped_circuit(deep=True) == expected_circuit
def default_circuit():
return cirq.FrozenCircuit(
cirq.X(cirq.GridQubit(1, 1))**sympy.Symbol('k'),
cirq.measure(cirq.GridQubit(1, 1), key='m'),
)
def test_string_format():
x, y, z = cirq.LineQubit.range(3)
fc0 = cirq.FrozenCircuit()
op0 = cirq.CircuitOperation(fc0)
assert (str(op0) == f"""\
{op0.circuit.serialization_key()}:
[ ]""")
fc1 = cirq.FrozenCircuit(cirq.X(x), cirq.H(y), cirq.CX(y, z),
cirq.measure(x, y, z, key='m'))
op1 = cirq.CircuitOperation(fc1)
assert (str(op1) == f"""\
{op1.circuit.serialization_key()}:
[ 0: ───X───────M('m')─── ]
[ │ ]
[ 1: ───H───@───M──────── ]
[ │ │ ]
[ 2: ───────X───M──────── ]""")
assert (repr(op1) == f"""\
cirq.CircuitOperation(
circuit=cirq.FrozenCircuit([
cirq.Moment(
cirq.X(cirq.LineQubit(0)),
cirq.H(cirq.LineQubit(1)),
),
cirq.Moment(
cirq.CNOT(cirq.LineQubit(1), cirq.LineQubit(2)),
),
cirq.Moment(
cirq.measure(cirq.LineQubit(0), cirq.LineQubit(1), cirq.LineQubit(2), key='m'),
),
]),
)""")
fc2 = cirq.FrozenCircuit(cirq.X(x), cirq.H(y), cirq.CX(y, x))
op2 = cirq.CircuitOperation(circuit=fc2,
qubit_map=({
y: z
}),
repetitions=3,
repetition_ids=['a', 'b', 'c'])
assert (str(op2) == f"""\
{op2.circuit.serialization_key()}:
[ 0: ───X───X─── ]
[ │ ]
[ 1: ───H───@─── ](qubit_map={{1: 2}}, repetition_ids=['a', 'b', 'c'])"""
)
assert (repr(op2) == """\
cirq.CircuitOperation(
circuit=cirq.FrozenCircuit([
cirq.Moment(
cirq.X(cirq.LineQubit(0)),
cirq.H(cirq.LineQubit(1)),
),
cirq.Moment(
cirq.CNOT(cirq.LineQubit(1), cirq.LineQubit(0)),
),
]),
repetitions=3,
qubit_map={cirq.LineQubit(1): cirq.LineQubit(2)},
repetition_ids=['a', 'b', 'c'],
)""")
fc3 = cirq.FrozenCircuit(
cirq.X(x)**sympy.Symbol('b'),
cirq.measure(x, key='m'),
)
op3 = cirq.CircuitOperation(
circuit=fc3,
qubit_map={x: y},
measurement_key_map={'m': 'p'},
param_resolver={sympy.Symbol('b'): 2},
)
indented_fc3_repr = repr(fc3).replace('\n', '\n ')
assert (str(op3) == f"""\
{op3.circuit.serialization_key()}:
[ 0: ───X^b───M('m')─── ](qubit_map={{0: 1}}, \
key_map={{m: p}}, params={{b: 2}})""")
assert (repr(op3) == f"""\
cirq.CircuitOperation(
circuit={indented_fc3_repr},
qubit_map={{cirq.LineQubit(0): cirq.LineQubit(1)}},
measurement_key_map={{'m': 'p'}},
param_resolver=cirq.ParamResolver({{sympy.Symbol('b'): 2}}),
)""")
fc4 = cirq.FrozenCircuit(cirq.X(y))
op4 = cirq.CircuitOperation(fc4)
fc5 = cirq.FrozenCircuit(cirq.X(x), op4)
op5 = cirq.CircuitOperation(fc5)
assert (repr(op5) == f"""\
cirq.CircuitOperation(
circuit=cirq.FrozenCircuit([
cirq.Moment(
cirq.X(cirq.LineQubit(0)),
cirq.CircuitOperation(
circuit=cirq.FrozenCircuit([
cirq.Moment(
cirq.X(cirq.LineQubit(1)),
),
]),
),
),
]),
)""")
from google.protobuf import any_pb2
from google.protobuf.text_format import Merge
import cirq
import cirq_google
import cirq_google as cg
from cirq_google.api import v1, v2
from cirq_google.engine.engine import EngineContext
from cirq_google.engine.client.quantum_v1alpha1 import types as qtypes
_CIRCUIT = cirq.Circuit(
cirq.X(cirq.GridQubit(5, 2))**0.5,
cirq.measure(cirq.GridQubit(5, 2), key='result'))
_CIRCUIT2 = cirq.FrozenCircuit(
cirq.Y(cirq.GridQubit(5, 2))**0.5,
cirq.measure(cirq.GridQubit(5, 2), key='result'))
def _to_any(proto):
any_proto = qtypes.any_pb2.Any()
any_proto.Pack(proto)
return any_proto
def _to_timestamp(json_string):
timestamp_proto = qtypes.timestamp_pb2.Timestamp()
timestamp_proto.FromJsonString(json_string)
return timestamp_proto
def test_subcircuit_entanglement_causes_join():
args = create_container(qs2)
assert len(set(args.values())) == 3
args.apply_operation(cirq.CircuitOperation(cirq.FrozenCircuit(cirq.CNOT(q0, q1))))
assert len(set(args.values())) == 2
assert args[q0] is args[q1]
def test_merge_k_qubit_unitaries_deep():
q = cirq.LineQubit.range(2)
h_cz_y = [cirq.H(q[0]), cirq.CZ(*q), cirq.Y(q[1])]
c_orig = cirq.Circuit(
h_cz_y,
cirq.Moment(cirq.X(q[0]).with_tags("ignore"), cirq.Y(q[1])),
cirq.CircuitOperation(
cirq.FrozenCircuit(h_cz_y)).repeat(6).with_tags("ignore"),
[cirq.CNOT(*q), cirq.CNOT(*q)],
cirq.CircuitOperation(cirq.FrozenCircuit(h_cz_y)).repeat(4),
[cirq.CNOT(*q), cirq.CZ(*q), cirq.CNOT(*q)],
cirq.CircuitOperation(
cirq.FrozenCircuit(h_cz_y)).repeat(5).with_tags("preserve_tag"),
)
def _wrap_in_cop(ops: cirq.OP_TREE, tag: str):
return cirq.CircuitOperation(cirq.FrozenCircuit(ops)).with_tags(tag)
c_expected = cirq.Circuit(
_wrap_in_cop([h_cz_y, cirq.Y(q[1])], '1'),
cirq.Moment(cirq.X(q[0]).with_tags("ignore")),
cirq.CircuitOperation(
cirq.FrozenCircuit(h_cz_y)).repeat(6).with_tags("ignore"),
_wrap_in_cop([cirq.CNOT(*q), cirq.CNOT(*q)], '2'),
cirq.CircuitOperation(cirq.FrozenCircuit(_wrap_in_cop(h_cz_y,
'3'))).repeat(4),
_wrap_in_cop([cirq.CNOT(*q), cirq.CZ(*q),
cirq.CNOT(*q)], '4'),
cirq.CircuitOperation(cirq.FrozenCircuit(_wrap_in_cop(
h_cz_y, '5'))).repeat(5).with_tags("preserve_tag"),
strategy=cirq.InsertStrategy.NEW,
)
component_id = 0
def rewriter_merge_to_circuit_op(
op: 'cirq.CircuitOperation') -> 'cirq.OP_TREE':
nonlocal component_id
component_id = component_id + 1
return op.with_tags(f'{component_id}')
context = cirq.TransformerContext(tags_to_ignore=("ignore", ), deep=True)
c_new = cirq.merge_k_qubit_unitaries(c_orig,
k=2,
context=context,
rewriter=rewriter_merge_to_circuit_op)
cirq.testing.assert_same_circuits(c_new, c_expected)
def _wrap_in_matrix_gate(ops: cirq.OP_TREE):
op = _wrap_in_cop(ops, 'temp')
return cirq.MatrixGate(cirq.unitary(op)).on(*op.qubits)
c_expected_matrix = cirq.Circuit(
_wrap_in_matrix_gate([h_cz_y, cirq.Y(q[1])]),
cirq.Moment(cirq.X(q[0]).with_tags("ignore")),
cirq.CircuitOperation(
cirq.FrozenCircuit(h_cz_y)).repeat(6).with_tags("ignore"),
_wrap_in_matrix_gate([cirq.CNOT(*q), cirq.CNOT(*q)]),
cirq.CircuitOperation(cirq.FrozenCircuit(
_wrap_in_matrix_gate(h_cz_y))).repeat(4),
_wrap_in_matrix_gate([cirq.CNOT(*q),
cirq.CZ(*q),
cirq.CNOT(*q)]),
cirq.CircuitOperation(cirq.FrozenCircuit(
_wrap_in_matrix_gate(h_cz_y))).repeat(5).with_tags("preserve_tag"),
strategy=cirq.InsertStrategy.NEW,
)
c_new_matrix = cirq.merge_k_qubit_unitaries(c_orig, k=2, context=context)
cirq.testing.assert_same_circuits(c_new_matrix, c_expected_matrix)
def test_serialize_non_gate_op_invalid():
q0 = cirq.LineQubit(0)
circuit = cirq.Circuit(cirq.X(q0), cirq.CircuitOperation(cirq.FrozenCircuit()))
serializer = ionq.Serializer()
with pytest.raises(ValueError, match='CircuitOperation'):
_ = serializer.serialize(circuit)
def test_subcircuit_identity_does_not_join():
args = create_container(qs2)
assert len(set(args.values())) == 3
args.apply_operation(cirq.CircuitOperation(cirq.FrozenCircuit(cirq.IdentityGate(2)(q0, q1))))
assert len(set(args.values())) == 3
assert args[q0] is not args[q1]
def test_immutable():
q = cirq.LineQubit(0)
c = cirq.FrozenCircuit(cirq.X(q), cirq.H(q))
with pytest.raises(AttributeError, match="can't set attribute"):
c.moments = (cirq.Moment(cirq.H(q)), cirq.Moment(cirq.X(q)))
def test_expands_composite_recursively_preserving_structur():
q = cirq.LineQubit.range(2)
c_nested = cirq.FrozenCircuit(cirq.SWAP(*q[:2]),
cirq.SWAP(*q[:2]).with_tags("ignore"),
cirq.SWAP(*q[:2]))
c_nested_expanded = cirq.FrozenCircuit(
[cirq.CNOT(*q), cirq.CNOT(*q[::-1]),
cirq.CNOT(*q)],
cirq.SWAP(*q[:2]).with_tags("ignore"),
[cirq.CNOT(*q), cirq.CNOT(*q[::-1]),
cirq.CNOT(*q)],
)
c_orig = cirq.Circuit(
c_nested,
cirq.CircuitOperation(
cirq.FrozenCircuit(
c_nested,
cirq.CircuitOperation(c_nested).repeat(5).with_tags("ignore"),
cirq.CircuitOperation(c_nested).repeat(6).with_tags(
"preserve_tag"),
cirq.CircuitOperation(c_nested).repeat(7),
c_nested,
)).repeat(4).with_tags("ignore"),
c_nested,
cirq.CircuitOperation(
cirq.FrozenCircuit(
c_nested,
cirq.CircuitOperation(c_nested).repeat(5).with_tags("ignore"),
cirq.CircuitOperation(c_nested).repeat(6).with_tags(
"preserve_tag"),
cirq.CircuitOperation(c_nested).repeat(7),
c_nested,
)).repeat(5).with_tags("preserve_tag"),
c_nested,
)
c_expected = cirq.Circuit(
c_nested_expanded,
cirq.CircuitOperation(
cirq.FrozenCircuit(
c_nested,
cirq.CircuitOperation(c_nested).repeat(5).with_tags("ignore"),
cirq.CircuitOperation(c_nested).repeat(6).with_tags(
"preserve_tag"),
cirq.CircuitOperation(c_nested).repeat(7),
c_nested,
)).repeat(4).with_tags("ignore"),
c_nested_expanded,
cirq.CircuitOperation(
cirq.FrozenCircuit(
c_nested_expanded,
cirq.CircuitOperation(c_nested).repeat(5).with_tags("ignore"),
cirq.CircuitOperation(c_nested_expanded).repeat(6).with_tags(
"preserve_tag"),
cirq.CircuitOperation(c_nested_expanded).repeat(7),
c_nested_expanded,
)).repeat(5).with_tags("preserve_tag"),
c_nested_expanded,
)
context = cirq.TransformerContext(tags_to_ignore=["ignore"], deep=True)
c_expanded = cirq.expand_composite(
c_orig, no_decomp=lambda op: op.gate == cirq.CNOT, context=context)
cirq.testing.assert_same_circuits(c_expanded, c_expected)
assert sum(1 for _ in circuit.findall_operations(lambda e: len(e.qubits) > 2)) <= 6
circuit.append(cirq.I.on_each(*target_op.qubits))
cirq.testing.assert_allclose_up_to_global_phase(
cirq.unitary(circuit), cirq.unitary(target_op), atol=1e-7
)
theta = sympy.Symbol('theta')
all_exps = np.linspace(0, 1, 10)
q = cirq.LineQubit.range(2)
@pytest.mark.parametrize(
'op, theta_range',
[
(cirq.CircuitOperation(cirq.FrozenCircuit(cirq.SWAP(*q), cirq.ZZ(*q) ** theta)), all_exps),
(cirq.CircuitOperation(cirq.FrozenCircuit(cirq.ZZ(*q) ** theta, cirq.SWAP(*q))), all_exps),
(cirq.PhasedISwapPowGate(exponent=1, phase_exponent=theta).on(*q), all_exps),
(cirq.PhasedISwapPowGate(exponent=theta, phase_exponent=0.25).on(*q), all_exps),
(cirq.CNOT(*q) ** theta, all_exps),
(cirq.CZ(*q) ** theta, all_exps),
(cirq.ZZ(*q) ** theta, all_exps),
(cirq.SWAP(*q) ** theta, [1]),
(cirq.ISWAP(*q) ** theta, [1]),
],
)
def test_known_two_qubit_op_decomposition(op, theta_range):
for theta_val in theta_range:
op_resolved = cirq.resolve_parameters(op, {'theta': theta_val}, recursive=False)
known_2q_circuit = cirq.Circuit(cg.known_2q_op_to_sycamore_operations(op_resolved))
matrix_2q_circuit = cirq.Circuit(
gateset=cirq_google.SycamoreTargetGateset(
tabulation=sycamore_tabulation))
u1 = cirq.unitary(circuit)
u2 = cirq.unitary(converted_circuit)
overlap = abs(np.trace(u1.conj().T @ u2))
assert np.isclose(overlap, 4.0, 0.1)
q = cirq.GridQubit.rect(1, 3)
matrix_gate = cirq.MatrixGate(cirq.testing.random_unitary(2))
@pytest.mark.parametrize(
'op',
[
cirq.CircuitOperation(cirq.FrozenCircuit(matrix_gate(q[0]))),
matrix_gate(q[0]),
matrix_gate(q[0]).with_tags('test_tags'),
matrix_gate(q[0]).controlled_by(q[1]),
matrix_gate(q[0]).controlled_by(q[1]).with_tags('test_tags'),
matrix_gate(q[0]).with_tags('test_tags').controlled_by(q[1]),
],
)
def test_supported_operation(op):
circuit = cirq.Circuit(op)
converted_circuit = cirq.optimize_for_target_gateset(
circuit, gateset=cirq_google.SycamoreTargetGateset())
cirq.testing.assert_circuits_with_terminal_measurements_are_equivalent(
circuit, converted_circuit, atol=1e-8)
multi_qubit_ops = [
e for e in converted_circuit.all_operations() if len(e.qubits) > 1
def _wrap_in_cop(ops: cirq.OP_TREE, tag: str):
return cirq.CircuitOperation(cirq.FrozenCircuit(ops)).with_tags(tag)
def test_parameterized_repeat_side_effects():
q = cirq.LineQubit(0)
op = cirq.CircuitOperation(
cirq.FrozenCircuit(
cirq.X(q).with_classical_controls('c'), cirq.measure(q, key='m')),
repetitions=sympy.Symbol('a'),
)
# Control keys can be calculated because they only "lift" if there's a matching
# measurement, in which case they're not returned here.
assert cirq.control_keys(op) == {cirq.MeasurementKey('c')}
# "local" params do not bind to the repetition param.
assert cirq.parameter_names(op.with_params({'a': 1})) == {'a'}
# Check errors that require unrolling the circuit.
with pytest.raises(
ValueError,
match='Cannot unroll circuit due to nondeterministic repetitions'):
cirq.measurement_key_objs(op)
with pytest.raises(
ValueError,
match='Cannot unroll circuit due to nondeterministic repetitions'):
cirq.measurement_key_names(op)
with pytest.raises(
ValueError,
match='Cannot unroll circuit due to nondeterministic repetitions'):
op.mapped_circuit()
with pytest.raises(
ValueError,
match='Cannot unroll circuit due to nondeterministic repetitions'):
cirq.decompose(op)
# Not compatible with repetition ids
with pytest.raises(ValueError,
match='repetition ids with parameterized repetitions'):
op.with_repetition_ids(['x', 'y'])
with pytest.raises(ValueError,
match='repetition ids with parameterized repetitions'):
op.repeat(repetition_ids=['x', 'y'])
# TODO(daxfohl): This should work, but likely requires a new protocol that returns *just* the
# name of the measurement keys. (measurement_key_names returns the full serialized string).
with pytest.raises(
ValueError,
match='Cannot unroll circuit due to nondeterministic repetitions'):
cirq.with_measurement_key_mapping(op, {'m': 'm2'})
# Everything should work once resolved
op = cirq.resolve_parameters(op, {'a': 2})
assert set(map(str, cirq.measurement_key_objs(op))) == {'0:m', '1:m'}
assert op.mapped_circuit() == cirq.Circuit(
cirq.X(q).with_classical_controls('c'),
cirq.measure(q, key=cirq.MeasurementKey.parse_serialized('0:m')),
cirq.X(q).with_classical_controls('c'),
cirq.measure(q, key=cirq.MeasurementKey.parse_serialized('1:m')),
)
assert cirq.decompose(op) == cirq.decompose(
cirq.Circuit(
cirq.X(q).with_classical_controls('c'),
cirq.measure(q, key=cirq.MeasurementKey.parse_serialized('0:m')),
cirq.X(q).with_classical_controls('c'),
cirq.measure(q, key=cirq.MeasurementKey.parse_serialized('1:m')),
))
def test_map_operations_deep_subcircuits():
q = cirq.LineQubit.range(5)
c_orig = cirq.Circuit(cirq.CX(q[0], q[1]), cirq.CX(q[3], q[2]), cirq.CX(q[3], q[4]))
c_orig_with_circuit_ops = cirq.Circuit(
cirq.CircuitOperation(
cirq.FrozenCircuit(
[
cirq.CircuitOperation(cirq.FrozenCircuit(op)).repeat(2).with_tags("internal")
for op in c_orig.all_operations()
]
)
)
.repeat(6)
.with_tags("external")
)
def map_func(op: cirq.Operation, _: int) -> cirq.OP_TREE:
yield [
cirq.Z.on_each(*op.qubits),
cirq.CX(*op.qubits),
cirq.Z.on_each(*op.qubits),
] if op.gate == cirq.CX else op
cirq.testing.assert_has_diagram(
c_orig_with_circuit_ops,
'''
[ [ 0: ───@─── ] ]
[ 0: ───[ │ ]────────────────────────────────────────────────────────────── ]
[ [ 1: ───X─── ](loops=2)['internal'] ]
[ │ ]
[ 1: ───#2────────────────────────────────────────────────────────────────────────── ]
[ ]
[ [ 2: ───X─── ] ]
0: ───[ 2: ───[ │ ]────────────────────────────────────────────────────────────── ]────────────────────────
[ [ 3: ───@─── ](loops=2)['internal'] ]
[ │ ]
[ │ [ 3: ───@─── ] ]
[ 3: ───#2────────────────────────────────────[ │ ]──────────────────────── ]
[ [ 4: ───X─── ](loops=2)['internal'] ]
[ │ ]
[ 4: ─────────────────────────────────────────#2──────────────────────────────────── ](loops=6)['external']
│
1: ───#2────────────────────────────────────────────────────────────────────────────────────────────────────────────
│
2: ───#3────────────────────────────────────────────────────────────────────────────────────────────────────────────
│
3: ───#4────────────────────────────────────────────────────────────────────────────────────────────────────────────
│
4: ───#5────────────────────────────────────────────────────────────────────────────────────────────────────────────
''',
)
c_mapped = cirq.map_operations(c_orig_with_circuit_ops, map_func, deep=True)
for unroller in [
cirq.unroll_circuit_op,
cirq.unroll_circuit_op_greedy_earliest,
cirq.unroll_circuit_op_greedy_frontier,
]:
cirq.testing.assert_has_diagram(
unroller(c_mapped, deep=True),
'''
[ [ 0: ───Z───@───Z─── ] ]
[ 0: ───[ │ ]────────────────────────────────────────────────────────────────────── ]
[ [ 1: ───Z───X───Z─── ](loops=2)['internal'] ]
[ │ ]
[ 1: ───#2────────────────────────────────────────────────────────────────────────────────────────── ]
[ ]
[ [ 2: ───Z───X───Z─── ] ]
0: ───[ 2: ───[ │ ]────────────────────────────────────────────────────────────────────── ]────────────────────────
[ [ 3: ───Z───@───Z─── ](loops=2)['internal'] ]
[ │ ]
[ │ [ 3: ───Z───@───Z─── ] ]
[ 3: ───#2────────────────────────────────────────────[ │ ]──────────────────────── ]
[ [ 4: ───Z───X───Z─── ](loops=2)['internal'] ]
[ │ ]
[ 4: ─────────────────────────────────────────────────#2──────────────────────────────────────────── ](loops=6)['external']
│
1: ───#2────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
│
2: ───#3────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
│
3: ───#4────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
│
4: ───#5────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
''',
)
def test_validate_operation_no_gate():
device = ionq.IonQAPIDevice(qubits=[])
with pytest.raises(ValueError, match='no gates'):
device.validate_operation(cirq.CircuitOperation(cirq.FrozenCircuit()))
def test_unroll_circuit_op_and_variants():
q = cirq.LineQubit.range(2)
c = cirq.Circuit(cirq.X(q[0]), cirq.CNOT(q[0], q[1]), cirq.X(q[0]))
cirq.testing.assert_has_diagram(
c,
'''
0: ───X───@───X───
│
1: ───────X───────
''',
)
mapped_circuit = cirq.map_operations(
c, lambda op, i: [cirq.Z(q[1])] * 2 if op.gate == cirq.CNOT else op
)
mapped_circuit_deep = cirq.Circuit(
[cirq.Moment(cirq.CircuitOperation(cirq.FrozenCircuit(m))) for m in mapped_circuit[:-1]],
mapped_circuit[-1],
)
cirq.testing.assert_has_diagram(
mapped_circuit_deep,
'''
0: ───[ 0: ───X─── ]────────────────────────────────────────────────────────────X───
1: ────────────────────[ 1: ───[ 1: ───Z───Z─── ]['<mapped_circuit_op>']─── ]───────
''',
)
for unroller in [
cirq.unroll_circuit_op_greedy_earliest,
cirq.unroll_circuit_op_greedy_frontier,
cirq.unroll_circuit_op,
]:
cirq.testing.assert_same_circuits(
unroller(mapped_circuit), unroller(mapped_circuit_deep, deep=True, tags_to_check=None)
)
cirq.testing.assert_has_diagram(
unroller(mapped_circuit_deep, deep=True),
'''
0: ───[ 0: ───X─── ]────────────────────────X───
1: ────────────────────[ 1: ───Z───Z─── ]───────
''',
)
cirq.testing.assert_has_diagram(
cirq.unroll_circuit_op(mapped_circuit),
'''
0: ───X───────────X───
1: ───────Z───Z───────
''',
)
cirq.testing.assert_has_diagram(
cirq.unroll_circuit_op_greedy_earliest(mapped_circuit),
'''
0: ───X───────X───
1: ───Z───Z───────
''',
)
cirq.testing.assert_has_diagram(
cirq.unroll_circuit_op_greedy_frontier(mapped_circuit),
'''
0: ───X───────X───
1: ───────Z───Z───
''',
)
def test_string_format():
x, y, z = cirq.LineQubit.range(3)
fc0 = cirq.FrozenCircuit()
op0 = cirq.CircuitOperation(fc0)
assert str(op0) == f"[ ]"
fc0_global_phase_inner = cirq.FrozenCircuit(cirq.GlobalPhaseOperation(1j),
cirq.GlobalPhaseOperation(1j))
op0_global_phase_inner = cirq.CircuitOperation(fc0_global_phase_inner)
fc0_global_phase_outer = cirq.FrozenCircuit(op0_global_phase_inner,
cirq.GlobalPhaseOperation(1j))
op0_global_phase_outer = cirq.CircuitOperation(fc0_global_phase_outer)
assert (str(op0_global_phase_outer) == f"""\
[ ]
[ ]
[ global phase: -0.5π ]""")
fc1 = cirq.FrozenCircuit(cirq.X(x), cirq.H(y), cirq.CX(y, z),
cirq.measure(x, y, z, key='m'))
op1 = cirq.CircuitOperation(fc1)
assert (str(op1) == f"""\
[ 0: ───X───────M('m')─── ]
[ │ ]
[ 1: ───H───@───M──────── ]
[ │ │ ]
[ 2: ───────X───M──────── ]""")
assert (repr(op1) == """\
cirq.CircuitOperation(
circuit=cirq.FrozenCircuit([
cirq.Moment(
cirq.X(cirq.LineQubit(0)),
cirq.H(cirq.LineQubit(1)),
),
cirq.Moment(
cirq.CNOT(cirq.LineQubit(1), cirq.LineQubit(2)),
),
cirq.Moment(
cirq.measure(cirq.LineQubit(0), cirq.LineQubit(1), cirq.LineQubit(2), key=cirq.MeasurementKey(name='m')),
),
]),
)""")
fc2 = cirq.FrozenCircuit(cirq.X(x), cirq.H(y), cirq.CX(y, x))
op2 = cirq.CircuitOperation(
circuit=fc2,
qubit_map=({
y: z
}),
repetitions=3,
parent_path=('outer', 'inner'),
repetition_ids=['a', 'b', 'c'],
)
assert (str(op2) == f"""\
[ 0: ───X───X─── ]
[ │ ]
[ 1: ───H───@─── ](qubit_map={{1: 2}}, parent_path=('outer', 'inner'),\
repetition_ids=['a', 'b', 'c'])""")
assert (repr(op2) == """\
cirq.CircuitOperation(
circuit=cirq.FrozenCircuit([
cirq.Moment(
cirq.X(cirq.LineQubit(0)),
cirq.H(cirq.LineQubit(1)),
),
cirq.Moment(
cirq.CNOT(cirq.LineQubit(1), cirq.LineQubit(0)),
),
]),
repetitions=3,
qubit_map={cirq.LineQubit(1): cirq.LineQubit(2)},
parent_path=('outer', 'inner'),
repetition_ids=['a', 'b', 'c'],
)""")
fc3 = cirq.FrozenCircuit(
cirq.X(x)**sympy.Symbol('b'),
cirq.measure(x, key='m'),
)
op3 = cirq.CircuitOperation(
circuit=fc3,
qubit_map={x: y},
measurement_key_map={'m': 'p'},
param_resolver={sympy.Symbol('b'): 2},
)
indented_fc3_repr = repr(fc3).replace('\n', '\n ')
assert (str(op3) == f"""\
[ 0: ───X^b───M('m')─── ](qubit_map={{0: 1}}, \
key_map={{m: p}}, params={{b: 2}})""")
assert (repr(op3) == f"""\
cirq.CircuitOperation(
circuit={indented_fc3_repr},
qubit_map={{cirq.LineQubit(0): cirq.LineQubit(1)}},
measurement_key_map={{'m': 'p'}},
param_resolver=cirq.ParamResolver({{sympy.Symbol('b'): 2}}),
)""")
fc4 = cirq.FrozenCircuit(cirq.X(y))
op4 = cirq.CircuitOperation(fc4)
fc5 = cirq.FrozenCircuit(cirq.X(x), op4)
op5 = cirq.CircuitOperation(fc5)
assert (repr(op5) == """\
cirq.CircuitOperation(
circuit=cirq.FrozenCircuit([
cirq.Moment(
cirq.X(cirq.LineQubit(0)),
cirq.CircuitOperation(
circuit=cirq.FrozenCircuit([
cirq.Moment(
cirq.X(cirq.LineQubit(1)),
),
]),
),
),
]),
)""")
def test_serialize_deserialize_circuit_with_subcircuit():
q0 = cirq.GridQubit(1, 1)
q1 = cirq.GridQubit(1, 2)
tag1 = cg.CalibrationTag('abc123')
fcircuit = cirq.FrozenCircuit(cirq.X(q0))
circuit = cirq.Circuit(
cirq.X(q1).with_tags(tag1),
cirq.CircuitOperation(fcircuit).repeat(repetition_ids=['a', 'b']),
cirq.CircuitOperation(fcircuit).with_qubit_mapping({q0: q1}),
cirq.X(q0),
)
op1 = v2.program_pb2.Operation()
op1.gate.id = 'x_pow'
op1.args['half_turns'].arg_value.float_value = 1.0
op1.qubits.add().id = '1_2'
op1.token_constant_index = 0
c_op1 = v2.program_pb2.CircuitOperation()
c_op1.circuit_constant_index = 1
rep_spec = c_op1.repetition_specification
rep_spec.repetition_count = 2
rep_spec.repetition_ids.ids.extend(['a', 'b'])
c_op2 = v2.program_pb2.CircuitOperation()
c_op2.circuit_constant_index = 1
c_op2.repetition_specification.repetition_count = 1
qmap = c_op2.qubit_map.entries.add()
qmap.key.id = '1_1'
qmap.value.id = '1_2'
proto = v2.program_pb2.Program(
language=v2.program_pb2.Language(arg_function_language='', gate_set='my_gate_set'),
circuit=v2.program_pb2.Circuit(
scheduling_strategy=v2.program_pb2.Circuit.MOMENT_BY_MOMENT,
moments=[
v2.program_pb2.Moment(
operations=[op1],
circuit_operations=[c_op1],
),
v2.program_pb2.Moment(
operations=[X_SERIALIZER.to_proto(cirq.X(q0))],
circuit_operations=[c_op2],
),
],
),
constants=[
v2.program_pb2.Constant(string_value='abc123'),
v2.program_pb2.Constant(
circuit_value=v2.program_pb2.Circuit(
scheduling_strategy=v2.program_pb2.Circuit.MOMENT_BY_MOMENT,
moments=[
v2.program_pb2.Moment(
operations=[X_SERIALIZER.to_proto(cirq.X(q0))],
)
],
)
),
],
)
assert proto == MY_GATE_SET.serialize(circuit)
assert MY_GATE_SET.deserialize(proto) == circuit
def test_serialize_deserialize_circuit_with_subcircuit():
serializer = cg.CircuitSerializer('my_gate_set')
tag1 = cg.CalibrationTag('abc123')
fcircuit = cirq.FrozenCircuit(
cirq.XPowGate(exponent=2 * sympy.Symbol('t'))(Q0))
circuit = cirq.Circuit(
cirq.X(Q1).with_tags(tag1),
cirq.CircuitOperation(fcircuit).repeat(repetition_ids=['a', 'b']),
cirq.CircuitOperation(fcircuit).with_qubit_mapping({Q0: Q1}),
cirq.X(Q0),
)
op_x = v2.program_pb2.Operation()
op_x.xpowgate.exponent.float_value = 1.0
op_x.qubit_constant_index.append(2)
op_tag = v2.program_pb2.Operation()
op_tag.xpowgate.exponent.float_value = 1.0
op_tag.qubit_constant_index.append(0)
op_tag.token_constant_index = 1
op_symbol = v2.program_pb2.Operation()
op_symbol.xpowgate.exponent.func.type = 'mul'
op_symbol.xpowgate.exponent.func.args.add().arg_value.float_value = 2.0
op_symbol.xpowgate.exponent.func.args.add().symbol = 't'
op_symbol.qubit_constant_index.append(2)
c_op1 = v2.program_pb2.CircuitOperation()
c_op1.circuit_constant_index = 3
rep_spec = c_op1.repetition_specification
rep_spec.repetition_count = 2
rep_spec.repetition_ids.ids.extend(['a', 'b'])
c_op2 = v2.program_pb2.CircuitOperation()
c_op2.circuit_constant_index = 3
c_op2.repetition_specification.repetition_count = 1
qmap = c_op2.qubit_map.entries.add()
qmap.key.id = '2_4'
qmap.value.id = '2_5'
proto = v2.program_pb2.Program(
language=v2.program_pb2.Language(arg_function_language='exp',
gate_set='my_gate_set'),
circuit=v2.program_pb2.Circuit(
scheduling_strategy=v2.program_pb2.Circuit.MOMENT_BY_MOMENT,
moments=[
v2.program_pb2.Moment(
operations=[op_tag],
circuit_operations=[c_op1],
),
v2.program_pb2.Moment(
operations=[op_x],
circuit_operations=[c_op2],
),
],
),
constants=[
v2.program_pb2.Constant(qubit=v2.program_pb2.Qubit(id='2_5')),
v2.program_pb2.Constant(string_value='abc123'),
v2.program_pb2.Constant(qubit=v2.program_pb2.Qubit(id='2_4')),
v2.program_pb2.Constant(circuit_value=v2.program_pb2.Circuit(
scheduling_strategy=v2.program_pb2.Circuit.MOMENT_BY_MOMENT,
moments=[v2.program_pb2.Moment(operations=[op_symbol], )],
)),
],
)
assert proto == serializer.serialize(circuit)
assert serializer.deserialize(proto) == circuit
def _wrap_cop(c: cirq.FrozenCircuit, *tags) -> cirq.FrozenCircuit:
return cirq.FrozenCircuit(cirq.CircuitOperation(c).with_tags(*tags, t_all))
def test_gateset_validate_circuit_op_negative_reps():
gate = CustomXPowGate(exponent=0.5)
op = cirq.CircuitOperation(cirq.FrozenCircuit(gate.on(cirq.LineQubit(0))),
repetitions=-1)
assert op not in cirq.Gateset(gate)
assert op**-1 in cirq.Gateset(gate)
def default_circuit():
return cirq.FrozenCircuit(
cirq.X(cirq.GridQubit(1, 1))**sympy.Symbol('k'),
cirq.X(cirq.GridQubit(1, 2)).with_tags(DEFAULT_TOKEN),
cirq.measure(cirq.GridQubit(1, 1), key='m'),
)
def wrap_frozen(*ops):
return cirq.FrozenCircuit(wrap(*ops))
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from unittest import mock
import pytest
import cirq
import cirq_google as cg
import cirq_google.engine.client.quantum
@pytest.mark.parametrize('circuit', [cirq.Circuit(), cirq.FrozenCircuit()])
def test_run_circuit(circuit):
engine = mock.Mock()
sampler = cg.QuantumEngineSampler(engine=engine,
processor_id='tmp',
gate_set=cg.XMON)
params = [cirq.ParamResolver({'a': 1})]
sampler.run_sweep(circuit, params, 5)
engine.run_sweep.assert_called_with(
gate_set=cg.XMON,
params=params,
processor_ids=['tmp'],
program=circuit,
repetitions=5,
)
def test_parameterized_repeat():
q = cirq.LineQubit(0)
op = cirq.CircuitOperation(cirq.FrozenCircuit(
cirq.X(q)))**sympy.Symbol('a')
assert cirq.parameter_names(op) == {'a'}
assert not cirq.has_unitary(op)
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={'a': 0})
assert np.allclose(result.state_vector(), [1, 0])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={'a': 1})
assert np.allclose(result.state_vector(), [0, 1])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={'a': 2})
assert np.allclose(result.state_vector(), [1, 0])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={'a': -1})
assert np.allclose(result.state_vector(), [0, 1])
with pytest.raises(TypeError,
match='Only integer or sympy repetitions are allowed'):
cirq.Simulator().simulate(cirq.Circuit(op), param_resolver={'a': 1.5})
with pytest.raises(
ValueError,
match='Circuit contains ops whose symbols were not specified'):
cirq.Simulator().simulate(cirq.Circuit(op))
op = op**-1
assert cirq.parameter_names(op) == {'a'}
assert not cirq.has_unitary(op)
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={'a': 0})
assert np.allclose(result.state_vector(), [1, 0])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={'a': 1})
assert np.allclose(result.state_vector(), [0, 1])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={'a': 2})
assert np.allclose(result.state_vector(), [1, 0])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={'a': -1})
assert np.allclose(result.state_vector(), [0, 1])
with pytest.raises(TypeError,
match='Only integer or sympy repetitions are allowed'):
cirq.Simulator().simulate(cirq.Circuit(op), param_resolver={'a': 1.5})
with pytest.raises(
ValueError,
match='Circuit contains ops whose symbols were not specified'):
cirq.Simulator().simulate(cirq.Circuit(op))
op = op**sympy.Symbol('b')
assert cirq.parameter_names(op) == {'a', 'b'}
assert not cirq.has_unitary(op)
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={
'a': 1,
'b': 1
})
assert np.allclose(result.state_vector(), [0, 1])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={
'a': 2,
'b': 1
})
assert np.allclose(result.state_vector(), [1, 0])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={
'a': 1,
'b': 2
})
assert np.allclose(result.state_vector(), [1, 0])
with pytest.raises(TypeError,
match='Only integer or sympy repetitions are allowed'):
cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={
'a': 1.5,
'b': 1
})
with pytest.raises(
ValueError,
match='Circuit contains ops whose symbols were not specified'):
cirq.Simulator().simulate(cirq.Circuit(op))
op = op**2.0
assert cirq.parameter_names(op) == {'a', 'b'}
assert not cirq.has_unitary(op)
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={
'a': 1,
'b': 1
})
assert np.allclose(result.state_vector(), [1, 0])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={
'a': 1.5,
'b': 1
})
assert np.allclose(result.state_vector(), [0, 1])
result = cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={
'a': 1,
'b': 1.5
})
assert np.allclose(result.state_vector(), [0, 1])
with pytest.raises(TypeError,
match='Only integer or sympy repetitions are allowed'):
cirq.Simulator().simulate(cirq.Circuit(op),
param_resolver={
'a': 1.5,
'b': 1.5
})
with pytest.raises(
ValueError,
match='Circuit contains ops whose symbols were not specified'):
cirq.Simulator().simulate(cirq.Circuit(op))
def test_init_device_deprecated():
q = cirq.LineQubit(0)
with cirq.testing.assert_deprecated(
cirq.circuits.circuit._DEVICE_DEP_MESSAGE, deadline='v0.15'):
_ = cirq.FrozenCircuit(cirq.X(q), device=cirq.UNCONSTRAINED_DEVICE)
