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unary_iteration_gate_test.py
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unary_iteration_gate_test.py
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# Copyright 2023 The Cirq Developers
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# https://www.apache.org/licenses/LICENSE-2.0
#
# 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.
import itertools
from typing import Sequence, Tuple
import cirq
import cirq_ft
import pytest
from cirq._compat import cached_property
from cirq_ft import infra
from cirq_ft.infra.bit_tools import iter_bits
from cirq_ft.infra.jupyter_tools import execute_notebook
class ApplyXToLthQubit(cirq_ft.UnaryIterationGate):
def __init__(self, selection_bitsize: int, target_bitsize: int, control_bitsize: int = 1):
self._selection_bitsize = selection_bitsize
self._target_bitsize = target_bitsize
self._control_bitsize = control_bitsize
@cached_property
def control_registers(self) -> Tuple[cirq_ft.Register, ...]:
return (cirq_ft.Register('control', self._control_bitsize),)
@cached_property
def selection_registers(self) -> Tuple[cirq_ft.SelectionRegister, ...]:
return (
cirq_ft.SelectionRegister('selection', self._selection_bitsize, self._target_bitsize),
)
@cached_property
def target_registers(self) -> Tuple[cirq_ft.Register, ...]:
return (cirq_ft.Register('target', self._target_bitsize),)
def nth_operation( # type: ignore[override]
self,
context: cirq.DecompositionContext,
control: cirq.Qid,
selection: int,
target: Sequence[cirq.Qid],
) -> cirq.OP_TREE:
return cirq.CNOT(control, target[-(selection + 1)])
@pytest.mark.parametrize(
"selection_bitsize, target_bitsize, control_bitsize", [(3, 5, 1), (2, 4, 2), (1, 2, 3)]
)
def test_unary_iteration_gate(selection_bitsize, target_bitsize, control_bitsize):
greedy_mm = cirq.GreedyQubitManager(prefix="_a", maximize_reuse=True)
gate = ApplyXToLthQubit(selection_bitsize, target_bitsize, control_bitsize)
g = cirq_ft.testing.GateHelper(gate, context=cirq.DecompositionContext(greedy_mm))
assert len(g.all_qubits) <= 2 * (selection_bitsize + control_bitsize) + target_bitsize - 1
for n in range(target_bitsize):
# Initial qubit values
qubit_vals = {q: 0 for q in g.operation.qubits}
# All controls 'on' to activate circuit
qubit_vals.update({c: 1 for c in g.quregs['control']})
# Set selection according to `n`
qubit_vals.update(zip(g.quregs['selection'], iter_bits(n, selection_bitsize)))
initial_state = [qubit_vals[x] for x in g.operation.qubits]
qubit_vals[g.quregs['target'][-(n + 1)]] = 1
final_state = [qubit_vals[x] for x in g.operation.qubits]
cirq_ft.testing.assert_circuit_inp_out_cirqsim(
g.circuit, g.operation.qubits, initial_state, final_state
)
class ApplyXToIJKthQubit(cirq_ft.UnaryIterationGate):
def __init__(self, target_shape: Tuple[int, int, int]):
self._target_shape = target_shape
@cached_property
def control_registers(self) -> Tuple[cirq_ft.Register, ...]:
return ()
@cached_property
def selection_registers(self) -> Tuple[cirq_ft.SelectionRegister, ...]:
return tuple(
cirq_ft.SelectionRegister(
'ijk'[i], (self._target_shape[i] - 1).bit_length(), self._target_shape[i]
)
for i in range(3)
)
@cached_property
def target_registers(self) -> Tuple[cirq_ft.Register, ...]:
return tuple(
cirq_ft.Signature.build(
t1=self._target_shape[0], t2=self._target_shape[1], t3=self._target_shape[2]
)
)
def nth_operation( # type: ignore[override]
self,
context: cirq.DecompositionContext,
control: cirq.Qid,
i: int,
j: int,
k: int,
t1: Sequence[cirq.Qid],
t2: Sequence[cirq.Qid],
t3: Sequence[cirq.Qid],
) -> cirq.OP_TREE:
yield [cirq.CNOT(control, t1[i]), cirq.CNOT(control, t2[j]), cirq.CNOT(control, t3[k])]
@pytest.mark.parametrize(
"target_shape", [pytest.param((2, 3, 2), marks=pytest.mark.slow), (2, 2, 2)]
)
def test_multi_dimensional_unary_iteration_gate(target_shape: Tuple[int, int, int]):
greedy_mm = cirq.GreedyQubitManager(prefix="_a", maximize_reuse=True)
gate = ApplyXToIJKthQubit(target_shape)
g = cirq_ft.testing.GateHelper(gate, context=cirq.DecompositionContext(greedy_mm))
assert (
len(g.all_qubits)
<= infra.total_bits(gate.signature) + infra.total_bits(gate.selection_registers) - 1
)
max_i, max_j, max_k = target_shape
i_len, j_len, k_len = tuple(reg.total_bits() for reg in gate.selection_registers)
for i, j, k in itertools.product(range(max_i), range(max_j), range(max_k)):
qubit_vals = {x: 0 for x in g.operation.qubits}
# Initialize selection bits appropriately:
qubit_vals.update(zip(g.quregs['i'], iter_bits(i, i_len)))
qubit_vals.update(zip(g.quregs['j'], iter_bits(j, j_len)))
qubit_vals.update(zip(g.quregs['k'], iter_bits(k, k_len)))
# Construct initial state
initial_state = [qubit_vals[x] for x in g.operation.qubits]
# Build correct statevector with selection_integer bit flipped in the target register:
for reg_name, idx in zip(['t1', 't2', 't3'], [i, j, k]):
qubit_vals[g.quregs[reg_name][idx]] = 1
final_state = [qubit_vals[x] for x in g.operation.qubits]
cirq_ft.testing.assert_circuit_inp_out_cirqsim(
g.circuit, g.operation.qubits, initial_state, final_state
)
def test_unary_iteration_loop():
n_range, m_range = (3, 5), (6, 8)
selection_registers = [
cirq_ft.SelectionRegister('n', 3, 5),
cirq_ft.SelectionRegister('m', 3, 8),
]
selection = infra.get_named_qubits(selection_registers)
target = {(n, m): cirq.q(f't({n}, {m})') for n in range(*n_range) for m in range(*m_range)}
qm = cirq.GreedyQubitManager("ancilla", maximize_reuse=True)
circuit = cirq.Circuit()
i_ops = []
# Build the unary iteration circuit
for i_optree, i_ctrl, i in cirq_ft.unary_iteration(
n_range[0], n_range[1], i_ops, [], selection['n'], qm
):
circuit.append(i_optree)
j_ops = []
for j_optree, j_ctrl, j in cirq_ft.unary_iteration(
m_range[0], m_range[1], j_ops, [i_ctrl], selection['m'], qm
):
circuit.append(j_optree)
# Conditionally perform operations on target register using `j_ctrl`, `i` & `j`.
circuit.append(cirq.CNOT(j_ctrl, target[(i, j)]))
circuit.append(j_ops)
circuit.append(i_ops)
all_qubits = sorted(circuit.all_qubits())
i_len, j_len = 3, 3
for i, j in itertools.product(range(*n_range), range(*m_range)):
qubit_vals = {x: 0 for x in all_qubits}
# Initialize selection bits appropriately:
qubit_vals.update(zip(selection['n'], iter_bits(i, i_len)))
qubit_vals.update(zip(selection['m'], iter_bits(j, j_len)))
# Construct initial state
initial_state = [qubit_vals[x] for x in all_qubits]
# Build correct statevector with selection_integer bit flipped in the target register:
qubit_vals[target[(i, j)]] = 1
final_state = [qubit_vals[x] for x in all_qubits]
cirq_ft.testing.assert_circuit_inp_out_cirqsim(
circuit, all_qubits, initial_state, final_state
)
def test_unary_iteration_loop_empty_range():
qm = cirq.ops.SimpleQubitManager()
assert list(cirq_ft.unary_iteration(4, 4, [], [], [cirq.q('s')], qm)) == []
assert list(cirq_ft.unary_iteration(4, 3, [], [], [cirq.q('s')], qm)) == []
def test_notebook():
execute_notebook('unary_iteration')