# qiskit.circuit.random.utils의 소스 코드

```
# This code is part of Qiskit.
#
# (C) Copyright IBM 2017.
#
# This code is licensed under the Apache License, Version 2.0. You may
# obtain a copy of this license in the LICENSE.txt file in the root directory
# of this source tree or at http://www.apache.org/licenses/LICENSE-2.0.
#
# Any modifications or derivative works of this code must retain this
# copyright notice, and modified files need to carry a notice indicating
# that they have been altered from the originals.
"""Utility functions for generating random circuits."""
import numpy as np
from qiskit.circuit import QuantumRegister, ClassicalRegister, QuantumCircuit
from qiskit.circuit import Reset
from qiskit.circuit.library.standard_gates import (
IGate,
U1Gate,
U2Gate,
U3Gate,
XGate,
YGate,
ZGate,
HGate,
SGate,
SdgGate,
TGate,
TdgGate,
RXGate,
RYGate,
RZGate,
CXGate,
CYGate,
CZGate,
CHGate,
CRZGate,
CU1Gate,
CU3Gate,
SwapGate,
RZZGate,
CCXGate,
CSwapGate,
)
from qiskit.circuit.exceptions import CircuitError
[문서]def random_circuit(
num_qubits, depth, max_operands=3, measure=False, conditional=False, reset=False, seed=None
):
"""Generate random circuit of arbitrary size and form.
This function will generate a random circuit by randomly selecting gates
from the set of standard gates in :mod:`qiskit.extensions`. For example:
.. jupyter-execute::
from qiskit.circuit.random import random_circuit
circ = random_circuit(2, 2, measure=True)
circ.draw(output='mpl')
Args:
num_qubits (int): number of quantum wires
depth (int): layers of operations (i.e. critical path length)
max_operands (int): maximum operands of each gate (between 1 and 3)
measure (bool): if True, measure all qubits at the end
conditional (bool): if True, insert middle measurements and conditionals
reset (bool): if True, insert middle resets
seed (int): sets random seed (optional)
Returns:
QuantumCircuit: constructed circuit
Raises:
CircuitError: when invalid options given
"""
if max_operands < 1 or max_operands > 3:
raise CircuitError("max_operands must be between 1 and 3")
one_q_ops = [
IGate,
U1Gate,
U2Gate,
U3Gate,
XGate,
YGate,
ZGate,
HGate,
SGate,
SdgGate,
TGate,
TdgGate,
RXGate,
RYGate,
RZGate,
]
one_param = [U1Gate, RXGate, RYGate, RZGate, RZZGate, CU1Gate, CRZGate]
two_param = [U2Gate]
three_param = [U3Gate, CU3Gate]
two_q_ops = [CXGate, CYGate, CZGate, CHGate, CRZGate, CU1Gate, CU3Gate, SwapGate, RZZGate]
three_q_ops = [CCXGate, CSwapGate]
qr = QuantumRegister(num_qubits, "q")
qc = QuantumCircuit(num_qubits)
if measure or conditional:
cr = ClassicalRegister(num_qubits, "c")
qc.add_register(cr)
if reset:
one_q_ops += [Reset]
if seed is None:
seed = np.random.randint(0, np.iinfo(np.int32).max)
rng = np.random.default_rng(seed)
# apply arbitrary random operations at every depth
for _ in range(depth):
# choose either 1, 2, or 3 qubits for the operation
remaining_qubits = list(range(num_qubits))
rng.shuffle(remaining_qubits)
while remaining_qubits:
max_possible_operands = min(len(remaining_qubits), max_operands)
num_operands = rng.choice(range(max_possible_operands)) + 1
operands = [remaining_qubits.pop() for _ in range(num_operands)]
if num_operands == 1:
operation = rng.choice(one_q_ops)
elif num_operands == 2:
operation = rng.choice(two_q_ops)
elif num_operands == 3:
operation = rng.choice(three_q_ops)
if operation in one_param:
num_angles = 1
elif operation in two_param:
num_angles = 2
elif operation in three_param:
num_angles = 3
else:
num_angles = 0
angles = [rng.uniform(0, 2 * np.pi) for x in range(num_angles)]
register_operands = [qr[i] for i in operands]
op = operation(*angles)
# with some low probability, condition on classical bit values
if conditional and rng.choice(range(10)) == 0:
value = rng.integers(0, np.power(2, num_qubits))
op.condition = (cr, value)
qc.append(op, register_operands)
if measure:
qc.measure(qr, cr)
return qc
```