def test_rotation_gates(self):
"""Test controlled rotation gates"""
import qiskit.extensions.standard.u1 as u1
import qiskit.extensions.standard.rx as rx
import qiskit.extensions.standard.ry as ry
import qiskit.extensions.standard.rz as rz
num_ctrl = 2
num_target = 1
qreg = QuantumRegister(num_ctrl + num_target)
gu1 = u1.U1Gate(pi)
grx = rx.RXGate(pi)
gry = ry.RYGate(pi)
grz = rz.RZGate(pi)
ugu1 = ac._unroll_gate(gu1, ['u1', 'u3', 'cx'])
ugrx = ac._unroll_gate(grx, ['u1', 'u3', 'cx'])
ugry = ac._unroll_gate(gry, ['u1', 'u3', 'cx'])
ugrz = ac._unroll_gate(grz, ['u1', 'u3', 'cx'])
cgu1 = ugu1.q_if(num_ctrl)
cgrx = ugrx.q_if(num_ctrl)
cgry = ugry.q_if(num_ctrl)
cgrz = ugrz.q_if(num_ctrl)
simulator = BasicAer.get_backend('unitary_simulator')
for gate, cgate in zip([gu1, grx, gry, grz], [cgu1, cgrx, cgry, cgrz]):
with self.subTest(i=gate.name):
qc = QuantumCircuit(num_target)
qc.append(gate, qc.qregs[0])
op_mat = execute(qc, simulator).result().get_unitary(0)
cqc = QuantumCircuit(num_ctrl + num_target)
cqc.append(cgate, cqc.qregs[0])
ref_mat = execute(cqc, simulator).result().get_unitary(0)
cop_mat = _compute_control_matrix(op_mat, num_ctrl)
self.assertTrue(
matrix_equal(cop_mat, ref_mat, ignore_phase=True))
dag = circuit_to_dag(cqc)
unroller = Unroller(['u3', 'cx'])
uqc = dag_to_circuit(unroller.run(dag))
self.log.info('%s gate count: %d', cgate.name, uqc.size())
self.log.info('\n%s', str(uqc))
# these limits could be changed
if gate.name == 'ry':
self.assertTrue(uqc.size() <= 32)
else:
self.assertTrue(uqc.size() <= 20)
qc = QuantumCircuit(qreg, name='composite')
qc.append(grx.q_if(num_ctrl), qreg)
qc.append(gry.q_if(num_ctrl), qreg)
qc.append(gry, qreg[0:gry.num_qubits])
qc.append(grz.q_if(num_ctrl), qreg)
dag = circuit_to_dag(qc)
unroller = Unroller(['u3', 'cx'])
uqc = dag_to_circuit(unroller.run(dag))
self.log.info('%s gate count: %d', uqc.name, uqc.size())
self.assertTrue(uqc.size() <= 73) # this limit could be changed
def test_unroll_no_basis(self):
"""Test when a given gate has no decompositions."""
qr = QuantumRegister(1, "qr")
cr = ClassicalRegister(1, "cr")
circuit = QuantumCircuit(qr, cr)
circuit.h(qr)
dag = circuit_to_dag(circuit)
pass_ = Unroller(basis=[])
with self.assertRaises(QiskitError):
pass_.run(dag)
def _unroll_gate(operation, basis_gates):
from qiskit.converters.dag_to_circuit import dag_to_circuit
from qiskit.transpiler.passes import Unroller
unroller = Unroller(basis_gates)
dag = _gate_to_dag(operation)
qc = dag_to_circuit(unroller.run(dag))
return qc.to_gate()
def test_single_controlled_rotation_gates(self, gate, cgate):
"""Test the controlled rotation gates controlled on one qubit."""
if gate.name == 'rz':
iden = Operator.from_label('I')
zgen = Operator.from_label('Z')
op_mat = (np.cos(0.5 * self.theta) * iden -
1j * np.sin(0.5 * self.theta) * zgen).data
else:
op_mat = Operator(gate).data
ref_mat = Operator(cgate).data
cop_mat = _compute_control_matrix(op_mat, self.num_ctrl)
self.assertTrue(matrix_equal(cop_mat, ref_mat, ignore_phase=True))
cqc = QuantumCircuit(self.num_ctrl + self.num_target)
cqc.append(cgate, cqc.qregs[0])
dag = circuit_to_dag(cqc)
unroller = Unroller(['u3', 'cx'])
uqc = dag_to_circuit(unroller.run(dag))
self.log.info('%s gate count: %d', cgate.name, uqc.size())
self.log.info('\n%s', str(uqc))
# these limits could be changed
if gate.name == 'ry':
self.assertTrue(uqc.size() <= 32)
elif gate.name == 'rz':
self.assertTrue(uqc.size() <= 40)
else:
self.assertTrue(uqc.size() <= 20)
def test_unroll_1q_chain_conditional(self):
"""Test unroll chain of 1-qubit gates interrupted by conditional.
"""
qr = QuantumRegister(1, 'qr')
cr = ClassicalRegister(1, 'cr')
circuit = QuantumCircuit(qr, cr)
circuit.h(qr)
circuit.tdg(qr)
circuit.z(qr)
circuit.t(qr)
circuit.ry(0.5, qr)
circuit.rz(0.3, qr)
circuit.rx(0.1, qr)
circuit.measure(qr, cr)
circuit.x(qr).c_if(cr, 1)
circuit.y(qr).c_if(cr, 1)
circuit.z(qr).c_if(cr, 1)
dag = circuit_to_dag(circuit)
pass_ = Unroller(['u1', 'u2', 'u3'])
unrolled_dag = pass_.run(dag)
ref_circuit = QuantumCircuit(qr, cr)
ref_circuit.u2(0, pi, qr[0])
ref_circuit.u1(-pi / 4, qr[0])
ref_circuit.u1(pi, qr[0])
ref_circuit.u1(pi / 4, qr[0])
ref_circuit.u3(0.5, 0, 0, qr[0])
ref_circuit.u1(0.3, qr[0])
ref_circuit.u3(0.1, -pi / 2, pi / 2, qr[0])
ref_circuit.measure(qr[0], cr[0])
ref_circuit.u3(pi, 0, pi, qr[0]).c_if(cr, 1)
ref_circuit.u3(pi, pi / 2, pi / 2, qr[0]).c_if(cr, 1)
ref_circuit.u1(pi, qr[0]).c_if(cr, 1)
ref_dag = circuit_to_dag(ref_circuit)
self.assertEqual(unrolled_dag, ref_dag)
def get_controlled_circuit(circuit, ctl_qubit, tgt_circuit=None, use_basis_gates=True):
"""
Construct the controlled version of a given circuit.
Args:
circuit (QuantumCircuit) : the base circuit
ctl_qubit (Qubit) : the control qubit to use
tgt_circuit (QuantumCircuit) : the target controlled circuit to be modified in-place
use_basis_gates (bool) : boolean flag to indicate whether or not
only basis gates should be used
Return:
QuantumCircuit: a QuantumCircuit object with the base circuit being controlled by ctl_qubit
Raises:
RuntimeError: unexpected operation
"""
if tgt_circuit is not None:
qc = tgt_circuit
else:
qc = QuantumCircuit()
# get all the qubits and clbits
qregs = circuit.qregs
qubits = []
for qreg in qregs:
if not qc.has_register(qreg):
qc.add_register(qreg)
qubits.extend(qreg)
cregs = circuit.cregs
clbits = []
for creg in cregs:
if not qc.has_register(creg):
qc.add_register(creg)
clbits.extend(creg)
# get all operations
unroller = Unroller(basis=['u', 'p', 'cx'])
ops = dag_to_circuit(unroller.run(circuit_to_dag(circuit))).data
# process all basis gates to add control
if not qc.has_register(ctl_qubit._register):
qc.add_register(ctl_qubit._register)
for op in ops:
if op[0].name == 'id':
apply_cu(qc, 0, 0, 0, ctl_qubit, op[1][0], use_basis_gates=use_basis_gates)
elif op[0].name == 'p':
apply_cp(qc, *op[0].params, ctl_qubit, op[1][0], use_basis_gates=use_basis_gates)
elif op[0].name == 'u':
apply_cu(qc, *op[0].params, ctl_qubit, op[1][0], use_basis_gates=use_basis_gates)
elif op[0].name == 'cx':
apply_ccx(qc, ctl_qubit, op[1][0], op[1][1], use_basis_gates=use_basis_gates)
elif op[0].name == 'measure':
qc.measure(op[1], op[2])
elif op[0].name == 'barrier':
qc.barrier(op[1])
else:
raise RuntimeError('Unexpected operation {}.'.format(op[0].name))
return qc
def _unroll_gate(operation, basis_gates):
from qiskit.converters.circuit_to_dag import circuit_to_dag
from qiskit.converters.dag_to_circuit import dag_to_circuit
from qiskit.converters.instruction_to_gate import instruction_to_gate
from qiskit.transpiler.passes import Unroller
unroller = Unroller(basis_gates)
dag = circuit_to_dag(_gate_to_circuit(operation))
qc = dag_to_circuit(unroller.run(dag))
return instruction_to_gate(qc.to_instruction())
def test_basic_unroll(self):
"""Test decompose a single H into u2."""
qr = QuantumRegister(1, "qr")
circuit = QuantumCircuit(qr)
circuit.h(qr[0])
dag = circuit_to_dag(circuit)
pass_ = Unroller(["u2"])
unrolled_dag = pass_.run(dag)
op_nodes = unrolled_dag.op_nodes()
self.assertEqual(len(op_nodes), 1)
self.assertEqual(op_nodes[0].name, "u2")
def test_basic_unroll(self):
"""Test decompose a single H into u2.
"""
qr = QuantumRegister(1, 'qr')
circuit = QuantumCircuit(qr)
circuit.h(qr[0])
dag = circuit_to_dag(circuit)
pass_ = Unroller(['u2'])
unrolled_dag = pass_.run(dag)
op_nodes = unrolled_dag.op_nodes(data=True)
self.assertEqual(len(op_nodes), 1)
self.assertEqual(op_nodes[0][1]["op"].name, 'u2')
def test_open_control_cy_unrolling(self):
"""test unrolling of open control gates when gate is in basis"""
qc = QuantumCircuit(2)
qc.cy(0, 1, ctrl_state=0)
dag = circuit_to_dag(qc)
unroller = Unroller(['u3', 'cy'])
uqc = dag_to_circuit(unroller.run(dag))
ref_circuit = QuantumCircuit(2)
ref_circuit.u3(np.pi, 0, np.pi, 0)
ref_circuit.cy(0, 1)
ref_circuit.u3(np.pi, 0, np.pi, 0)
self.assertEqual(uqc, ref_circuit)
def test_unroll_toffoli(self):
"""Test unroll toffoli on multi regs to h, t, tdg, cx."""
qr1 = QuantumRegister(2, "qr1")
qr2 = QuantumRegister(1, "qr2")
circuit = QuantumCircuit(qr1, qr2)
circuit.ccx(qr1[0], qr1[1], qr2[0])
dag = circuit_to_dag(circuit)
pass_ = Unroller(["h", "t", "tdg", "cx"])
unrolled_dag = pass_.run(dag)
op_nodes = unrolled_dag.op_nodes()
self.assertEqual(len(op_nodes), 15)
for node in op_nodes:
self.assertIn(node.name, ["h", "t", "tdg", "cx"])
def test_composite(self):
"""Test composite gate count."""
qreg = QuantumRegister(self.num_ctrl + self.num_target)
qc = QuantumCircuit(qreg, name='composite')
qc.append(self.grx.control(self.num_ctrl), qreg)
qc.append(self.gry.control(self.num_ctrl), qreg)
qc.append(self.gry, qreg[0:self.gry.num_qubits])
qc.append(self.grz.control(self.num_ctrl), qreg)
dag = circuit_to_dag(qc)
unroller = Unroller(['u3', 'cx'])
uqc = dag_to_circuit(unroller.run(dag))
self.log.info('%s gate count: %d', uqc.name, uqc.size())
self.assertTrue(uqc.size() <= 93) # this limit could be changed
def test_unroll_toffoli(self):
"""Test unroll toffoli on multi regs to h, t, tdg, cx.
"""
qr1 = QuantumRegister(2, 'qr1')
qr2 = QuantumRegister(1, 'qr2')
circuit = QuantumCircuit(qr1, qr2)
circuit.ccx(qr1[0], qr1[1], qr2[0])
dag = circuit_to_dag(circuit)
pass_ = Unroller(['h', 't', 'tdg', 'cx'])
unrolled_dag = pass_.run(dag)
op_nodes = unrolled_dag.op_nodes(data=True)
self.assertEqual(len(op_nodes), 15)
for node in op_nodes:
op = node[1]["op"]
self.assertIn(op.name, ['h', 't', 'tdg', 'cx'])
def test_unroll_no_basis(self):
"""Test no-basis unrolls all the way to U, CX.
"""
qr = QuantumRegister(2, 'qr')
circuit = QuantumCircuit(qr)
circuit.h(qr[0])
circuit.cx(qr[0], qr[1])
dag = circuit_to_dag(circuit)
pass_ = Unroller()
unrolled_dag = pass_.run(dag)
op_nodes = unrolled_dag.op_nodes(data=True)
self.assertEqual(len(op_nodes), 2)
for node in op_nodes:
op = node[1]["op"]
self.assertIn(op.name, ['U', 'CX'])
def test_open_control_cxx_unrolling(self):
"""test unrolling of open control gates when gate is in basis"""
qreg = QuantumRegister(3)
qc = QuantumCircuit(qreg)
ccx = CCXGate(ctrl_state=0)
qc.append(ccx, [0, 1, 2])
dag = circuit_to_dag(qc)
unroller = Unroller(['x', 'ccx'])
unrolled_dag = unroller.run(dag)
ref_circuit = QuantumCircuit(qreg)
ref_circuit.x(qreg[0])
ref_circuit.x(qreg[1])
ref_circuit.ccx(qreg[0], qreg[1], qreg[2])
ref_circuit.x(qreg[0])
ref_circuit.x(qreg[1])
ref_dag = circuit_to_dag(ref_circuit)
self.assertEqual(unrolled_dag, ref_dag)
def test_open_control_composite_unrolling(self):
"""test unrolling of open control gates when gate is in basis"""
# create composite gate
qreg = QuantumRegister(2)
qcomp = QuantumCircuit(qreg, name='bell')
qcomp.h(qreg[0])
qcomp.cx(qreg[0], qreg[1])
bell = qcomp.to_gate()
# create controlled composite gate
cqreg = QuantumRegister(3)
qc = QuantumCircuit(cqreg)
qc.append(bell.control(ctrl_state=0), qc.qregs[0][:])
dag = circuit_to_dag(qc)
unroller = Unroller(['x', 'u1', 'cbell'])
unrolled_dag = unroller.run(dag)
# create reference circuit
ref_circuit = QuantumCircuit(cqreg)
ref_circuit.x(cqreg[0])
ref_circuit.append(bell.control(), [cqreg[0], cqreg[1], cqreg[2]])
ref_circuit.x(cqreg[0])
ref_dag = circuit_to_dag(ref_circuit)
self.assertEqual(unrolled_dag, ref_dag)
def test_unroll_1q_chain_conditional(self):
"""Test unroll chain of 1-qubit gates interrupted by conditional.
"""
qr = QuantumRegister(1, 'qr')
cr = ClassicalRegister(1, 'cr')
circuit = QuantumCircuit(qr, cr)
circuit.h(qr)
circuit.tdg(qr)
circuit.z(qr)
circuit.t(qr)
circuit.ry(0.5, qr)
circuit.rz(0.3, qr)
circuit.rx(0.1, qr)
circuit.measure(qr, cr)
circuit.x(qr).c_if(cr, 1)
circuit.y(qr).c_if(cr, 1)
circuit.z(qr).c_if(cr, 1)
dag = circuit_to_dag(circuit)
pass_ = Unroller(['u1', 'u2', 'u3'])
unrolled_dag = pass_.run(dag)
# Pick up -1 * 0.3 / 2 global phase for one RZ -> U1.
ref_circuit = QuantumCircuit(qr, cr, global_phase=-0.3 / 2)
ref_circuit.append(U2Gate(0, pi), [qr[0]])
ref_circuit.append(U1Gate(-pi/4), [qr[0]])
ref_circuit.append(U1Gate(pi), [qr[0]])
ref_circuit.append(U1Gate(pi/4), [qr[0]])
ref_circuit.append(U3Gate(0.5, 0, 0), [qr[0]])
ref_circuit.append(U1Gate(0.3), [qr[0]])
ref_circuit.append(U3Gate(0.1, -pi/2, pi/2), [qr[0]])
ref_circuit.measure(qr[0], cr[0])
ref_circuit.append(U3Gate(pi, 0, pi), [qr[0]]).c_if(cr, 1)
ref_circuit.append(U3Gate(pi, pi/2, pi/2), [qr[0]]).c_if(cr, 1)
ref_circuit.append(U1Gate(pi), [qr[0]]).c_if(cr, 1)
ref_dag = circuit_to_dag(ref_circuit)
self.assertEqual(unrolled_dag, ref_dag)
def convert_to_basis_gates(circuit):
""" unroll the circuit using the basis ['u', 'cx'] """
unroller = Unroller(basis=['u', 'cx'])
return dag_to_circuit(unroller.run(circuit_to_dag(circuit)))
class TestUnrollAllInstructions(QiskitTestCase):
"""Test unrolling a circuit containing all standard instructions."""
def setUp(self):
super().setUp()
qr = self.qr = QuantumRegister(3, "qr")
cr = self.cr = ClassicalRegister(3, "cr")
self.circuit = QuantumCircuit(qr, cr)
self.ref_circuit = QuantumCircuit(qr, cr)
self.pass_ = Unroller(basis=["u3", "cx", "id"])
def compare_dags(self):
"""compare dags in class tests"""
dag = circuit_to_dag(self.circuit)
unrolled_dag = self.pass_.run(dag)
ref_dag = circuit_to_dag(self.ref_circuit)
self.assertEqual(unrolled_dag, ref_dag)
def test_unroll_crx(self):
"""test unroll crx"""
# qr_1: ─────■───── qr_1: ─────────────────■─────────────────────■─────────────────────
# ┌────┴────┐ = ┌─────────────┐┌─┴─┐┌───────────────┐┌─┴─┐┌─────────────────┐
# qr_2: ┤ Rx(0.5) ├ qr_2: ┤ U3(0,0,π/2) ├┤ X ├┤ U3(-0.25,0,0) ├┤ X ├┤ U3(0.25,-π/2,0) ├
# └─────────┘ └─────────────┘└───┘└───────────────┘└───┘└─────────────────┘
self.circuit.crx(0.5, 1, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 2), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(-0.25, 0, 0), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0.25, -pi / 2, 0), [2])
self.compare_dags()
def test_unroll_cry(self):
"""test unroll cry"""
# qr_1: ─────■───── qr_1: ──────────────────■─────────────────────■──
# ┌────┴────┐ = ┌──────────────┐┌─┴─┐┌───────────────┐┌─┴─┐
# qr_2: ┤ Ry(0.5) ├ qr_2: ┤ U3(0.25,0,0) ├┤ X ├┤ U3(-0.25,0,0) ├┤ X ├
# └─────────┘ └──────────────┘└───┘└───────────────┘└───┘
self.circuit.cry(0.5, 1, 2)
self.ref_circuit.append(U3Gate(0.25, 0, 0), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(-0.25, 0, 0), [2])
self.ref_circuit.cx(1, 2)
self.compare_dags()
def test_unroll_ccx(self):
"""test unroll ccx"""
# qr_0: ──■── qr_0: ──────────────────────────────────────■──────────────────────»
# │ │ »
# qr_1: ──■── = qr_1: ─────────────────■────────────────────┼───────────────────■──»
# ┌─┴─┐ ┌─────────────┐┌─┴─┐┌──────────────┐┌─┴─┐┌─────────────┐┌─┴─┐»
# qr_2: ┤ X ├ qr_2: ┤ U3(π/2,0,π) ├┤ X ├┤ U3(0,0,-π/4) ├┤ X ├┤ U3(0,0,π/4) ├┤ X ├»
# └───┘ └─────────────┘└───┘└──────────────┘└───┘└─────────────┘└───┘»
# « ┌─────────────┐
# «qr_0: ──────────────────■─────────■───────┤ U3(0,0,π/4) ├───■──
# « ┌─────────────┐ │ ┌─┴─┐ ├─────────────┴┐┌─┴─┐
# «qr_1: ┤ U3(0,0,π/4) ├───┼───────┤ X ├─────┤ U3(0,0,-π/4) ├┤ X ├
# « ├─────────────┴┐┌─┴─┐┌────┴───┴────┐├─────────────┬┘└───┘
# «qr_2: ┤ U3(0,0,-π/4) ├┤ X ├┤ U3(0,0,π/4) ├┤ U3(π/2,0,π) ├──────
# « └──────────────┘└───┘└─────────────┘└─────────────┘
self.circuit.ccx(0, 1, 2)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [1])
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.cx(0, 1)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [0])
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [1])
self.ref_circuit.cx(0, 1)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.compare_dags()
def test_unroll_ch(self):
"""test unroll ch"""
# qr_0: ──■── qr_0: ───────────────────────────────────────────────■──────────────────»
# ┌─┴─┐ = ┌─────────────┐┌─────────────┐┌─────────────┐┌─┴─┐┌──────────────┐»
# qr_2: ┤ H ├ qr_2: ┤ U3(0,0,π/2) ├┤ U3(π/2,0,π) ├┤ U3(0,0,π/4) ├┤ X ├┤ U3(0,0,-π/4) ├»
# └───┘ └─────────────┘└─────────────┘└─────────────┘└───┘└──────────────┘»
# «
# «qr_0: ───────────────────────────────
# « ┌─────────────┐┌──────────────┐
# «qr_2: ┤ U3(π/2,0,π) ├┤ U3(0,0,-π/2) ├
# « └─────────────┘└──────────────┘
self.circuit.ch(0, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 2), [2])
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.append(U3Gate(0, 0, -pi / 2), [2])
self.compare_dags()
def test_unroll_crz(self):
"""test unroll crz"""
# qr_1: ─────■───── qr_1: ──────────────────■─────────────────────■──
# ┌────┴────┐ = ┌──────────────┐┌─┴─┐┌───────────────┐┌─┴─┐
# qr_2: ┤ Rz(0.5) ├ qr_2: ┤ U3(0,0,0.25) ├┤ X ├┤ U3(0,0,-0.25) ├┤ X ├
# └─────────┘ └──────────────┘└───┘└───────────────┘└───┘
self.circuit.crz(0.5, 1, 2)
self.ref_circuit.append(U3Gate(0, 0, 0.25), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, -0.25), [2])
self.ref_circuit.cx(1, 2)
def test_unroll_cswap(self):
"""test unroll cswap"""
# ┌───┐ »
# qr_0: ─X─ qr_0: ┤ X ├─────────────────■────────────────────────────────────────■──»
# │ └─┬─┘ │ │ »
# qr_1: ─■─ = qr_1: ──┼───────────────────┼────────────────────■───────────────────┼──»
# │ │ ┌─────────────┐┌─┴─┐┌──────────────┐┌─┴─┐┌─────────────┐┌─┴─┐»
# qr_2: ─X─ qr_2: ──■──┤ U3(π/2,0,π) ├┤ X ├┤ U3(0,0,-π/4) ├┤ X ├┤ U3(0,0,π/4) ├┤ X ├»
# └─────────────┘└───┘└──────────────┘└───┘└─────────────┘└───┘»
# « ┌─────────────┐ ┌───┐ ┌──────────────┐┌───┐┌───┐
# «qr_0: ┤ U3(0,0,π/4) ├───────────┤ X ├─────┤ U3(0,0,-π/4) ├┤ X ├┤ X ├
# « └─────────────┘ └─┬─┘ ├─────────────┬┘└─┬─┘└─┬─┘
# «qr_1: ──────────────────■─────────■───────┤ U3(0,0,π/4) ├───■────┼──
# « ┌──────────────┐┌─┴─┐┌─────────────┐├─────────────┤ │
# «qr_2: ┤ U3(0,0,-π/4) ├┤ X ├┤ U3(0,0,π/4) ├┤ U3(π/2,0,π) ├────────■──
# « └──────────────┘└───┘└─────────────┘└─────────────┘
self.circuit.cswap(1, 0, 2)
self.ref_circuit.cx(2, 0)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [0])
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.cx(1, 0)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [0])
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [1])
self.ref_circuit.cx(1, 0)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.cx(2, 0)
self.compare_dags()
def test_unroll_cu1(self):
"""test unroll cu1"""
# ┌──────────────┐
# qr_0: ─■──────── qr_0: ┤ U3(0,0,0.05) ├──■─────────────────────■──────────────────
# │U1(0.1) = └──────────────┘┌─┴─┐┌───────────────┐┌─┴─┐┌──────────────┐
# qr_2: ─■──────── qr_2: ────────────────┤ X ├┤ U3(0,0,-0.05) ├┤ X ├┤ U3(0,0,0.05) ├
# └───┘└───────────────┘└───┘└──────────────┘
self.circuit.append(CU1Gate(0.1), [0, 2])
self.ref_circuit.append(U3Gate(0, 0, 0.05), [0])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, -0.05), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, 0.05), [2])
self.compare_dags()
def test_unroll_cu3(self):
"""test unroll cu3"""
# ┌──────────────┐
# q_1: ────────■──────── q_1: ─┤ U3(0,0,0.05) ├──■────────────────────────■───────────────────
# ┌───────┴───────┐ = ┌┴──────────────┤┌─┴─┐┌──────────────────┐┌─┴─┐┌───────────────┐
# q_2: ┤ U3(0.2,0.1,0) ├ q_2: ┤ U3(0,0,-0.05) ├┤ X ├┤ U3(-0.1,0,-0.05) ├┤ X ├┤ U3(0.1,0.1,0) ├
# └───────────────┘ └───────────────┘└───┘└──────────────────┘└───┘└───────────────┘
self.circuit.append(CU3Gate(0.2, 0.1, 0.0), [1, 2])
self.ref_circuit.append(U3Gate(0, 0, 0.05), [1])
self.ref_circuit.append(U3Gate(0, 0, -0.05), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(-0.1, 0, -0.05), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0.1, 0.1, 0), [2])
self.compare_dags()
def test_unroll_cx(self):
"""test unroll cx"""
self.circuit.cx(1, 0)
self.ref_circuit.cx(1, 0)
self.compare_dags()
def test_unroll_cy(self):
"""test unroll cy"""
# qr_1: ──■── qr_1: ──────────────────■─────────────────
# ┌─┴─┐ = ┌──────────────┐┌─┴─┐┌─────────────┐
# qr_2: ┤ Y ├ qr_2: ┤ U3(0,0,-π/2) ├┤ X ├┤ U3(0,0,π/2) ├
# └───┘ └──────────────┘└───┘└─────────────┘
self.circuit.cy(1, 2)
self.ref_circuit.append(U3Gate(0, 0, -pi / 2), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 2), [2])
self.compare_dags()
def test_unroll_cz(self):
"""test unroll cz"""
# ┌─────────────┐┌───┐┌─────────────┐
# qr_0: ─■─ qr_0: ┤ U3(π/2,0,π) ├┤ X ├┤ U3(π/2,0,π) ├
# │ = └─────────────┘└─┬─┘└─────────────┘
# qr_2: ─■─ qr_2: ─────────────────■─────────────────
self.circuit.cz(2, 0)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [0])
self.ref_circuit.cx(2, 0)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [0])
self.compare_dags()
def test_unroll_h(self):
"""test unroll h"""
self.circuit.h(1)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [1])
self.compare_dags()
def test_unroll_i(self):
"""test unroll i"""
self.circuit.i(0)
self.ref_circuit.i(0)
self.compare_dags()
def test_unroll_rx(self):
"""test unroll rx"""
self.circuit.rx(0.1, 0)
self.ref_circuit.append(U3Gate(0.1, -pi / 2, pi / 2), [0])
self.compare_dags()
def test_unroll_ry(self):
"""test unroll ry"""
self.circuit.ry(0.2, 1)
self.ref_circuit.append(U3Gate(0.2, 0, 0), [1])
self.compare_dags()
def test_unroll_rz(self):
"""test unroll rz"""
self.circuit.rz(0.3, 2)
self.ref_circuit.global_phase = -1 * 0.3 / 2
self.ref_circuit.append(U3Gate(0, 0, 0.3), [2])
self.compare_dags()
def test_unroll_rzz(self):
"""test unroll rzz"""
# global phase: 5.9832
# ┌───┐┌─────────────┐┌───┐
# qr_0: ─■──────── qr_0: ┤ X ├┤ U3(0,0,0.6) ├┤ X ├
# │ZZ(0.6) = └─┬─┘└─────────────┘└─┬─┘
# qr_1: ─■──────── qr_1: ──■───────────────────■──
self.circuit.rzz(0.6, 1, 0)
self.ref_circuit.global_phase = -1 * 0.6 / 2
self.ref_circuit.cx(1, 0)
self.ref_circuit.append(U3Gate(0, 0, 0.6), [0])
self.ref_circuit.cx(1, 0)
self.compare_dags()
def test_unroll_s(self):
"""test unroll s"""
self.circuit.s(0)
self.ref_circuit.append(U3Gate(0, 0, pi / 2), [0])
self.compare_dags()
def test_unroll_sdg(self):
"""test unroll sdg"""
self.circuit.sdg(1)
self.ref_circuit.append(U3Gate(0, 0, -pi / 2), [1])
self.compare_dags()
def test_unroll_swap(self):
"""test unroll swap"""
# ┌───┐
# qr_1: ─X─ qr_1: ──■──┤ X ├──■──
# │ = ┌─┴─┐└─┬─┘┌─┴─┐
# qr_2: ─X─ qr_2: ┤ X ├──■──┤ X ├
# └───┘ └───┘
self.circuit.swap(1, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.cx(2, 1)
self.ref_circuit.cx(1, 2)
self.compare_dags()
def test_unroll_t(self):
"""test unroll t"""
self.circuit.t(2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.compare_dags()
def test_unroll_tdg(self):
"""test unroll tdg"""
self.circuit.tdg(0)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [0])
self.compare_dags()
def test_unroll_u1(self):
"""test unroll u1"""
self.circuit.append(U1Gate(0.1), [1])
self.ref_circuit.append(U3Gate(0, 0, 0.1), [1])
self.compare_dags()
def test_unroll_u2(self):
"""test unroll u2"""
self.circuit.append(U2Gate(0.2, -0.1), [0])
self.ref_circuit.append(U3Gate(pi / 2, 0.2, -0.1), [0])
self.compare_dags()
def test_unroll_u3(self):
"""test unroll u3"""
self.circuit.append(U3Gate(0.3, 0.0, -0.1), [2])
self.ref_circuit.append(U3Gate(0.3, 0.0, -0.1), [2])
self.compare_dags()
def test_unroll_x(self):
"""test unroll x"""
self.circuit.x(2)
self.ref_circuit.append(U3Gate(pi, 0, pi), [2])
self.compare_dags()
def test_unroll_y(self):
"""test unroll y"""
self.circuit.y(1)
self.ref_circuit.append(U3Gate(pi, pi / 2, pi / 2), [1])
self.compare_dags()
def test_unroll_z(self):
"""test unroll z"""
self.circuit.z(0)
self.ref_circuit.append(U3Gate(0, 0, pi), [0])
self.compare_dags()
def test_unroll_snapshot(self):
"""test unroll snapshot"""
num_qubits = self.circuit.num_qubits
instr = Snapshot("0", num_qubits=num_qubits)
self.circuit.append(instr, range(num_qubits))
self.ref_circuit.append(instr, range(num_qubits))
self.compare_dags()
def test_unroll_measure(self):
"""test unroll measure"""
self.circuit.measure(self.qr, self.cr)
self.ref_circuit.measure(self.qr, self.cr)
self.compare_dags()
def test_rotation_gates(self):
"""Test controlled rotation gates"""
import qiskit.extensions.standard.u1 as u1
import qiskit.extensions.standard.rx as rx
import qiskit.extensions.standard.ry as ry
import qiskit.extensions.standard.rz as rz
num_ctrl = 2
num_target = 1
qreg = QuantumRegister(num_ctrl + num_target)
theta = pi / 2
gu1 = u1.U1Gate(theta)
grx = rx.RXGate(theta)
gry = ry.RYGate(theta)
grz = rz.RZGate(theta)
ugu1 = ac._unroll_gate(gu1, ['u1', 'u3', 'cx'])
ugrx = ac._unroll_gate(grx, ['u1', 'u3', 'cx'])
ugry = ac._unroll_gate(gry, ['u1', 'u3', 'cx'])
ugrz = ac._unroll_gate(grz, ['u1', 'u3', 'cx'])
ugrz.params = grz.params
cgu1 = ugu1.control(num_ctrl)
cgrx = ugrx.control(num_ctrl)
cgry = ugry.control(num_ctrl)
cgrz = ugrz.control(num_ctrl)
for gate, cgate in zip([gu1, grx, gry, grz], [cgu1, cgrx, cgry, cgrz]):
with self.subTest(i=gate.name):
if gate.name == 'rz':
iden = Operator.from_label('I')
zgen = Operator.from_label('Z')
op_mat = (np.cos(0.5 * theta) * iden -
1j * np.sin(0.5 * theta) * zgen).data
else:
op_mat = Operator(gate).data
ref_mat = Operator(cgate).data
cop_mat = _compute_control_matrix(op_mat, num_ctrl)
self.assertTrue(
matrix_equal(cop_mat, ref_mat, ignore_phase=True))
cqc = QuantumCircuit(num_ctrl + num_target)
cqc.append(cgate, cqc.qregs[0])
dag = circuit_to_dag(cqc)
unroller = Unroller(['u3', 'cx'])
uqc = dag_to_circuit(unroller.run(dag))
self.log.info('%s gate count: %d', cgate.name, uqc.size())
self.log.info('\n%s', str(uqc))
# these limits could be changed
if gate.name == 'ry':
self.assertTrue(uqc.size() <= 32)
elif gate.name == 'rz':
self.assertTrue(uqc.size() <= 40)
else:
self.assertTrue(uqc.size() <= 20)
qc = QuantumCircuit(qreg, name='composite')
qc.append(grx.control(num_ctrl), qreg)
qc.append(gry.control(num_ctrl), qreg)
qc.append(gry, qreg[0:gry.num_qubits])
qc.append(grz.control(num_ctrl), qreg)
dag = circuit_to_dag(qc)
unroller = Unroller(['u3', 'cx'])
uqc = dag_to_circuit(unroller.run(dag))
print(uqc.size())
self.log.info('%s gate count: %d', uqc.name, uqc.size())
self.assertTrue(uqc.size() <= 93) # this limit could be changed
class TestUnrollAllInstructions(QiskitTestCase):
"""Test unrolling a circuit containing all standard instructions."""
def setUp(self):
qr = self.qr = QuantumRegister(3, 'qr')
cr = self.cr = ClassicalRegister(3, 'cr')
self.circuit = QuantumCircuit(qr, cr)
self.ref_circuit = QuantumCircuit(qr, cr)
self.pass_ = Unroller(basis=['u3', 'cx', 'id'])
def compare_dags(self):
"""compare dags in class tests"""
dag = circuit_to_dag(self.circuit)
unrolled_dag = self.pass_.run(dag)
ref_dag = circuit_to_dag(self.ref_circuit)
self.assertEqual(unrolled_dag, ref_dag)
def test_unroll_crx(self):
"""test unroll crx"""
self.circuit.crx(0.5, 1, 2)
self.ref_circuit.u3(0, 0, pi/2, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(-0.25, 0, 0, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(0.25, -pi/2, 0, 2)
self.compare_dags()
def test_unroll_cry(self):
"""test unroll cry"""
self.circuit.cry(0.5, 1, 2)
self.ref_circuit.u3(0.25, 0, 0, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(-0.25, 0, 0, 2)
self.ref_circuit.cx(1, 2)
self.compare_dags()
def test_unroll_ccx(self):
"""test unroll ccx"""
self.circuit.ccx(0, 1, 2)
self.ref_circuit.u3(pi/2, 0, pi, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(0, 0, -pi/4, 2)
self.ref_circuit.cx(0, 2)
self.ref_circuit.u3(0, 0, pi/4, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(0, 0, pi/4, 1)
self.ref_circuit.u3(0, 0, -pi/4, 2)
self.ref_circuit.cx(0, 2)
self.ref_circuit.cx(0, 1)
self.ref_circuit.u3(0, 0, pi/4, 0)
self.ref_circuit.u3(0, 0, -pi/4, 1)
self.ref_circuit.cx(0, 1)
self.ref_circuit.u3(0, 0, pi/4, 2)
self.ref_circuit.u3(pi/2, 0, pi, 2)
self.compare_dags()
def test_unroll_ch(self):
"""test unroll ch"""
self.circuit.ch(0, 2)
self.ref_circuit.u3(0, 0, pi/2, 2)
self.ref_circuit.u3(pi/2, 0, pi, 2)
self.ref_circuit.u3(0, 0, pi/4, 2)
self.ref_circuit.cx(0, 2)
self.ref_circuit.u3(0, 0, -pi/4, 2)
self.ref_circuit.u3(pi/2, 0, pi, 2)
self.ref_circuit.u3(0, 0, -pi/2, 2)
self.compare_dags()
def test_unroll_crz(self):
"""test unroll crz"""
self.circuit.crz(0.5, 1, 2)
self.ref_circuit.u3(0, 0, 0.25, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(0, 0, -0.25, 2)
self.ref_circuit.cx(1, 2)
def test_unroll_cswap(self):
"""test unroll cswap"""
self.circuit.cswap(1, 0, 2)
self.ref_circuit.cx(2, 0)
self.ref_circuit.u3(pi/2, 0, pi, 2)
self.ref_circuit.cx(0, 2)
self.ref_circuit.u3(0, 0, -pi/4, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(0, 0, pi/4, 2)
self.ref_circuit.cx(0, 2)
self.ref_circuit.u3(0, 0, pi/4, 0)
self.ref_circuit.u3(0, 0, -pi/4, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.cx(1, 0)
self.ref_circuit.u3(0, 0, -pi/4, 0)
self.ref_circuit.u3(0, 0, pi/4, 1)
self.ref_circuit.cx(1, 0)
self.ref_circuit.u3(0, 0, pi/4, 2)
self.ref_circuit.u3(pi/2, 0, pi, 2)
self.ref_circuit.cx(2, 0)
self.compare_dags()
def test_unroll_cu1(self):
"""test unroll cu1"""
self.circuit.cu1(0.1, 0, 2)
self.ref_circuit.u3(0, 0, 0.05, 0)
self.ref_circuit.cx(0, 2)
self.ref_circuit.u3(0, 0, -0.05, 2)
self.ref_circuit.cx(0, 2)
self.ref_circuit.u3(0, 0, 0.05, 2)
self.compare_dags()
def test_unroll_cu3(self):
"""test unroll cu3"""
self.circuit.cu3(0.2, 0.1, 0.0, 1, 2)
self.ref_circuit.u3(0, 0, 0.05, 1)
self.ref_circuit.u3(0, 0, -0.05, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(-0.1, 0, -0.05, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(0.1, 0.1, 0, 2)
self.compare_dags()
def test_unroll_cx(self):
"""test unroll cx"""
self.circuit.cx(1, 0)
self.ref_circuit.cx(1, 0)
self.compare_dags()
def test_unroll_cy(self):
"""test unroll cy"""
self.circuit.cy(1, 2)
self.ref_circuit.u3(0, 0, -pi/2, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.u3(0, 0, pi/2, 2)
self.compare_dags()
def test_unroll_cz(self):
"""test unroll cz"""
self.circuit.cz(2, 0)
self.ref_circuit.u3(pi/2, 0, pi, 0)
self.ref_circuit.cx(2, 0)
self.ref_circuit.u3(pi/2, 0, pi, 0)
self.compare_dags()
def test_unroll_h(self):
"""test unroll h"""
self.circuit.h(1)
self.ref_circuit.u3(pi/2, 0, pi, 1)
self.compare_dags()
def test_unroll_i(self):
"""test unroll i"""
self.circuit.i(0)
self.ref_circuit.i(0)
self.compare_dags()
def test_unroll_rx(self):
"""test unroll rx"""
self.circuit.rx(0.1, 0)
self.ref_circuit.u3(0.1, -pi/2, pi/2, 0)
self.compare_dags()
def test_unroll_ry(self):
"""test unroll ry"""
self.circuit.ry(0.2, 1)
self.ref_circuit.u3(0.2, 0, 0, 1)
self.compare_dags()
def test_unroll_rz(self):
"""test unroll rz"""
self.circuit.rz(0.3, 2)
self.ref_circuit.u3(0, 0, 0.3, 2)
self.compare_dags()
def test_unroll_rzz(self):
"""test unroll rzz"""
self.circuit.rzz(0.6, 1, 0)
self.ref_circuit.cx(1, 0)
self.ref_circuit.u3(0, 0, 0.6, 0)
self.ref_circuit.cx(1, 0)
self.compare_dags()
def test_unroll_s(self):
"""test unroll s"""
self.circuit.s(0)
self.ref_circuit.u3(0, 0, pi/2, 0)
self.compare_dags()
def test_unroll_sdg(self):
"""test unroll sdg"""
self.circuit.sdg(1)
self.ref_circuit.u3(0, 0, -pi/2, 1)
self.compare_dags()
def test_unroll_swap(self):
"""test unroll swap"""
self.circuit.swap(1, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.cx(2, 1)
self.ref_circuit.cx(1, 2)
self.compare_dags()
def test_unroll_t(self):
"""test unroll t"""
self.circuit.t(2)
self.ref_circuit.u3(0, 0, pi/4, 2)
self.compare_dags()
def test_unroll_tdg(self):
"""test unroll tdg"""
self.circuit.tdg(0)
self.ref_circuit.u3(0, 0, -pi/4, 0)
self.compare_dags()
def test_unroll_u1(self):
"""test unroll u1"""
self.circuit.u1(0.1, 1)
self.ref_circuit.u3(0, 0, 0.1, 1)
self.compare_dags()
def test_unroll_u2(self):
"""test unroll u2"""
self.circuit.u2(0.2, -0.1, 0)
self.ref_circuit.u3(pi/2, 0.2, -0.1, 0)
self.compare_dags()
def test_unroll_u3(self):
"""test unroll u3"""
self.circuit.u3(0.3, 0.0, -0.1, 2)
self.ref_circuit.u3(0.3, 0.0, -0.1, 2)
self.compare_dags()
def test_unroll_x(self):
"""test unroll x"""
self.circuit.x(2)
self.ref_circuit.u3(pi, 0, pi, 2)
self.compare_dags()
def test_unroll_y(self):
"""test unroll y"""
self.circuit.y(1)
self.ref_circuit.u3(pi, pi/2, pi/2, 1)
self.compare_dags()
def test_unroll_z(self):
"""test unroll z"""
self.circuit.z(0)
self.ref_circuit.u3(0, 0, pi, 0)
self.compare_dags()
def test_unroll_snapshot(self):
"""test unroll snapshot"""
self.circuit.snapshot('0')
self.ref_circuit.snapshot('0')
self.compare_dags()
def test_unroll_measure(self):
"""test unroll measure"""
self.circuit.measure(self.qr, self.cr)
self.ref_circuit.measure(self.qr, self.cr)
self.compare_dags()
def test_unroll_all_instructions(self):
"""Test unrolling a circuit containing all standard instructions.
"""
qr = QuantumRegister(3, 'qr')
cr = ClassicalRegister(3, 'cr')
circuit = QuantumCircuit(qr, cr)
circuit.crx(0.5, qr[1], qr[2])
circuit.cry(0.5, qr[1], qr[2])
circuit.ccx(qr[0], qr[1], qr[2])
circuit.ch(qr[0], qr[2])
circuit.crz(0.5, qr[1], qr[2])
circuit.cswap(qr[1], qr[0], qr[2])
circuit.cu1(0.1, qr[0], qr[2])
circuit.cu3(0.2, 0.1, 0.0, qr[1], qr[2])
circuit.cx(qr[1], qr[0])
circuit.cy(qr[1], qr[2])
circuit.cz(qr[2], qr[0])
circuit.h(qr[1])
circuit.iden(qr[0])
circuit.rx(0.1, qr[0])
circuit.ry(0.2, qr[1])
circuit.rz(0.3, qr[2])
circuit.rzz(0.6, qr[1], qr[0])
circuit.s(qr[0])
circuit.sdg(qr[1])
circuit.swap(qr[1], qr[2])
circuit.t(qr[2])
circuit.tdg(qr[0])
circuit.u1(0.1, qr[1])
circuit.u2(0.2, -0.1, qr[0])
circuit.u3(0.3, 0.0, -0.1, qr[2])
circuit.x(qr[2])
circuit.y(qr[1])
circuit.z(qr[0])
circuit.snapshot('0')
circuit.measure(qr, cr)
dag = circuit_to_dag(circuit)
pass_ = Unroller(basis=['u3', 'cx', 'id'])
unrolled_dag = pass_.run(dag)
ref_circuit = QuantumCircuit(qr, cr)
ref_circuit.u3(0, 0, pi / 2, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(-0.25, 0, 0, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(0.25, -pi / 2, 0, qr[2])
ref_circuit.u3(0.25, 0, 0, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(-0.25, 0, 0, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(pi / 2, 0, pi, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(0, 0, -pi / 4, qr[2])
ref_circuit.cx(qr[0], qr[2])
ref_circuit.u3(0, 0, pi / 4, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(0, 0, pi / 4, qr[1])
ref_circuit.u3(0, 0, -pi / 4, qr[2])
ref_circuit.cx(qr[0], qr[2])
ref_circuit.cx(qr[0], qr[1])
ref_circuit.u3(0, 0, pi / 4, qr[0])
ref_circuit.u3(0, 0, -pi / 4, qr[1])
ref_circuit.cx(qr[0], qr[1])
ref_circuit.u3(0, 0, pi / 4, qr[2])
ref_circuit.u3(pi / 2, 0, pi, qr[2])
ref_circuit.u3(0, 0, pi / 2, qr[2])
ref_circuit.u3(pi / 2, 0, pi, qr[2])
ref_circuit.u3(0, 0, pi / 4, qr[2])
ref_circuit.cx(qr[0], qr[2])
ref_circuit.u3(0, 0, -pi / 4, qr[2])
ref_circuit.u3(pi / 2, 0, pi, qr[2])
ref_circuit.u3(0, 0, -pi / 2, qr[2])
ref_circuit.u3(0, 0, 0.25, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(0, 0, -0.25, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.cx(qr[2], qr[0])
ref_circuit.u3(pi / 2, 0, pi, qr[2])
ref_circuit.cx(qr[0], qr[2])
ref_circuit.u3(0, 0, -pi / 4, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(0, 0, pi / 4, qr[2])
ref_circuit.cx(qr[0], qr[2])
ref_circuit.u3(0, 0, pi / 4, qr[0])
ref_circuit.u3(0, 0, -pi / 4, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.cx(qr[1], qr[0])
ref_circuit.u3(0, 0, -pi / 4, qr[0])
ref_circuit.u3(0, 0, pi / 4, qr[1])
ref_circuit.cx(qr[1], qr[0])
ref_circuit.u3(0, 0, 0.05, qr[1])
ref_circuit.u3(0, 0, pi / 4, qr[2])
ref_circuit.u3(pi / 2, 0, pi, qr[2])
ref_circuit.cx(qr[2], qr[0])
ref_circuit.u3(0, 0, 0.05, qr[0])
ref_circuit.cx(qr[0], qr[2])
ref_circuit.u3(0, 0, -0.05, qr[2])
ref_circuit.cx(qr[0], qr[2])
ref_circuit.u3(0, 0, 0.05, qr[2])
ref_circuit.u3(0, 0, -0.05, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(-0.1, 0, -0.05, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.cx(qr[1], qr[0])
ref_circuit.u3(pi / 2, 0, pi, qr[0])
ref_circuit.u3(0.1, 0.1, 0, qr[2])
ref_circuit.u3(0, 0, -pi / 2, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(pi / 2, 0, pi, qr[1])
ref_circuit.u3(0.2, 0, 0, qr[1])
ref_circuit.u3(0, 0, pi / 2, qr[2])
ref_circuit.cx(qr[2], qr[0])
ref_circuit.u3(pi / 2, 0, pi, qr[0])
ref_circuit.iden(qr[0])
ref_circuit.u3(0.1, -pi / 2, pi / 2, qr[0])
ref_circuit.cx(qr[1], qr[0])
ref_circuit.u3(0, 0, 0.6, qr[0])
ref_circuit.cx(qr[1], qr[0])
ref_circuit.u3(0, 0, pi / 2, qr[0])
ref_circuit.u3(0, 0, -pi / 4, qr[0])
ref_circuit.u3(pi / 2, 0.2, -0.1, qr[0])
ref_circuit.u3(0, 0, pi, qr[0])
ref_circuit.u3(0, 0, -pi / 2, qr[1])
ref_circuit.u3(0, 0, 0.3, qr[2])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.cx(qr[2], qr[1])
ref_circuit.cx(qr[1], qr[2])
ref_circuit.u3(0, 0, 0.1, qr[1])
ref_circuit.u3(pi, pi / 2, pi / 2, qr[1])
ref_circuit.u3(0, 0, pi / 4, qr[2])
ref_circuit.u3(0.3, 0.0, -0.1, qr[2])
ref_circuit.u3(pi, 0, pi, qr[2])
ref_circuit.snapshot('0')
ref_circuit.measure(qr, cr)
ref_dag = circuit_to_dag(ref_circuit)
self.assertEqual(unrolled_dag, ref_dag)
def convert_to_basis_gates(circuit):
""" unroll the circuit using the basis u1, u2, u3, cx gates """
unroller = Unroller(basis=['u1', 'u2', 'u3', 'cx'])
return dag_to_circuit(unroller.run(circuit_to_dag(circuit)))
class TestUnrollAllInstructions(QiskitTestCase):
"""Test unrolling a circuit containing all standard instructions."""
def setUp(self):
super().setUp()
qr = self.qr = QuantumRegister(3, "qr")
cr = self.cr = ClassicalRegister(3, "cr")
self.circuit = QuantumCircuit(qr, cr)
self.ref_circuit = QuantumCircuit(qr, cr)
self.pass_ = Unroller(basis=["u3", "cx", "id"])
def compare_dags(self):
"""compare dags in class tests"""
dag = circuit_to_dag(self.circuit)
unrolled_dag = self.pass_.run(dag)
ref_dag = circuit_to_dag(self.ref_circuit)
self.assertEqual(unrolled_dag, ref_dag)
def test_unroll_crx(self):
"""test unroll crx"""
self.circuit.crx(0.5, 1, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 2), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(-0.25, 0, 0), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0.25, -pi / 2, 0), [2])
self.compare_dags()
def test_unroll_cry(self):
"""test unroll cry"""
self.circuit.cry(0.5, 1, 2)
self.ref_circuit.append(U3Gate(0.25, 0, 0), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(-0.25, 0, 0), [2])
self.ref_circuit.cx(1, 2)
self.compare_dags()
def test_unroll_ccx(self):
"""test unroll ccx"""
self.circuit.ccx(0, 1, 2)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [1])
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.cx(0, 1)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [0])
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [1])
self.ref_circuit.cx(0, 1)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.compare_dags()
def test_unroll_ch(self):
"""test unroll ch"""
self.circuit.ch(0, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 2), [2])
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.append(U3Gate(0, 0, -pi / 2), [2])
self.compare_dags()
def test_unroll_crz(self):
"""test unroll crz"""
self.circuit.crz(0.5, 1, 2)
self.ref_circuit.append(U3Gate(0, 0, 0.25), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, -0.25), [2])
self.ref_circuit.cx(1, 2)
def test_unroll_cswap(self):
"""test unroll cswap"""
self.circuit.cswap(1, 0, 2)
self.ref_circuit.cx(2, 0)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [0])
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.cx(1, 0)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [0])
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [1])
self.ref_circuit.cx(1, 0)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [2])
self.ref_circuit.cx(2, 0)
self.compare_dags()
def test_unroll_cu1(self):
"""test unroll cu1"""
self.circuit.append(CU1Gate(0.1), [0, 2])
self.ref_circuit.append(U3Gate(0, 0, 0.05), [0])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, -0.05), [2])
self.ref_circuit.cx(0, 2)
self.ref_circuit.append(U3Gate(0, 0, 0.05), [2])
self.compare_dags()
def test_unroll_cu3(self):
"""test unroll cu3"""
self.circuit.append(CU3Gate(0.2, 0.1, 0.0), [1, 2])
self.ref_circuit.append(U3Gate(0, 0, 0.05), [1])
self.ref_circuit.append(U3Gate(0, 0, -0.05), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(-0.1, 0, -0.05), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0.1, 0.1, 0), [2])
self.compare_dags()
def test_unroll_cx(self):
"""test unroll cx"""
self.circuit.cx(1, 0)
self.ref_circuit.cx(1, 0)
self.compare_dags()
def test_unroll_cy(self):
"""test unroll cy"""
self.circuit.cy(1, 2)
self.ref_circuit.append(U3Gate(0, 0, -pi / 2), [2])
self.ref_circuit.cx(1, 2)
self.ref_circuit.append(U3Gate(0, 0, pi / 2), [2])
self.compare_dags()
def test_unroll_cz(self):
"""test unroll cz"""
self.circuit.cz(2, 0)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [0])
self.ref_circuit.cx(2, 0)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [0])
self.compare_dags()
def test_unroll_h(self):
"""test unroll h"""
self.circuit.h(1)
self.ref_circuit.append(U3Gate(pi / 2, 0, pi), [1])
self.compare_dags()
def test_unroll_i(self):
"""test unroll i"""
self.circuit.i(0)
self.ref_circuit.i(0)
self.compare_dags()
def test_unroll_rx(self):
"""test unroll rx"""
self.circuit.rx(0.1, 0)
self.ref_circuit.append(U3Gate(0.1, -pi / 2, pi / 2), [0])
self.compare_dags()
def test_unroll_ry(self):
"""test unroll ry"""
self.circuit.ry(0.2, 1)
self.ref_circuit.append(U3Gate(0.2, 0, 0), [1])
self.compare_dags()
def test_unroll_rz(self):
"""test unroll rz"""
self.circuit.rz(0.3, 2)
self.ref_circuit.global_phase = -1 * 0.3 / 2
self.ref_circuit.append(U3Gate(0, 0, 0.3), [2])
self.compare_dags()
def test_unroll_rzz(self):
"""test unroll rzz"""
self.circuit.rzz(0.6, 1, 0)
self.ref_circuit.global_phase = -1 * 0.6 / 2
self.ref_circuit.cx(1, 0)
self.ref_circuit.append(U3Gate(0, 0, 0.6), [0])
self.ref_circuit.cx(1, 0)
self.compare_dags()
def test_unroll_s(self):
"""test unroll s"""
self.circuit.s(0)
self.ref_circuit.append(U3Gate(0, 0, pi / 2), [0])
self.compare_dags()
def test_unroll_sdg(self):
"""test unroll sdg"""
self.circuit.sdg(1)
self.ref_circuit.append(U3Gate(0, 0, -pi / 2), [1])
self.compare_dags()
def test_unroll_swap(self):
"""test unroll swap"""
self.circuit.swap(1, 2)
self.ref_circuit.cx(1, 2)
self.ref_circuit.cx(2, 1)
self.ref_circuit.cx(1, 2)
self.compare_dags()
def test_unroll_t(self):
"""test unroll t"""
self.circuit.t(2)
self.ref_circuit.append(U3Gate(0, 0, pi / 4), [2])
self.compare_dags()
def test_unroll_tdg(self):
"""test unroll tdg"""
self.circuit.tdg(0)
self.ref_circuit.append(U3Gate(0, 0, -pi / 4), [0])
self.compare_dags()
def test_unroll_u1(self):
"""test unroll u1"""
self.circuit.append(U1Gate(0.1), [1])
self.ref_circuit.append(U3Gate(0, 0, 0.1), [1])
self.compare_dags()
def test_unroll_u2(self):
"""test unroll u2"""
self.circuit.append(U2Gate(0.2, -0.1), [0])
self.ref_circuit.append(U3Gate(pi / 2, 0.2, -0.1), [0])
self.compare_dags()
def test_unroll_u3(self):
"""test unroll u3"""
self.circuit.append(U3Gate(0.3, 0.0, -0.1), [2])
self.ref_circuit.append(U3Gate(0.3, 0.0, -0.1), [2])
self.compare_dags()
def test_unroll_x(self):
"""test unroll x"""
self.circuit.x(2)
self.ref_circuit.append(U3Gate(pi, 0, pi), [2])
self.compare_dags()
def test_unroll_y(self):
"""test unroll y"""
self.circuit.y(1)
self.ref_circuit.append(U3Gate(pi, pi / 2, pi / 2), [1])
self.compare_dags()
def test_unroll_z(self):
"""test unroll z"""
self.circuit.z(0)
self.ref_circuit.append(U3Gate(0, 0, pi), [0])
self.compare_dags()
def test_unroll_snapshot(self):
"""test unroll snapshot"""
num_qubits = self.circuit.num_qubits
instr = Snapshot("0", num_qubits=num_qubits)
self.circuit.append(instr, range(num_qubits))
self.ref_circuit.append(instr, range(num_qubits))
self.compare_dags()
def test_unroll_measure(self):
"""test unroll measure"""
self.circuit.measure(self.qr, self.cr)
self.ref_circuit.measure(self.qr, self.cr)
self.compare_dags()
