Python QuantumCircuit.rz方法代码示例

# 需要导入模块: from qiskit import QuantumCircuit [as 别名]
# 或者: from qiskit.QuantumCircuit import rz [as 别名]
def trial_circuit_ryrz(n, m, theta, entangler_map, meas_string=None,
                       measurement=True):
    """Creates a QuantumCircuit object ocnsisting in layers of
    parametrized single-qubit Y and Z rotations and CZ two-qubit gates

    Args:
        n (int) : number of qubits
        m (int) : depth of the circuit
        theta array[float] : angles that parametrize the Y and Z rotations
        entangler_map : CZ connectivity, e.g. {0: [1], 1: [2]}
        meas_string (str) : measure a given Pauli operator at the end of the
            circuit
        measurement (bool) : whether to measure the qubit (register "q")
            on classical bits (register "c")
    Returns:
        A QuantumCircuit object
    """
    q = QuantumRegister("q", n)
    c = ClassicalRegister("c", n)
    trial_circuit = QuantumCircuit(q, c)
    trial_circuit.h(q)
    if meas_string is None:
        meas_string = [None for x in range(n)]
    for i in range(m):
        trial_circuit.barrier(q)
        for node in entangler_map:
            for j in entangler_map[node]:
                trial_circuit.cz(q[node], q[j])
        for j in range(n):
            trial_circuit.ry(theta[n * i * 2 + 2 * j], q[j])
            trial_circuit.rz(theta[n * i * 2 + 2 * j + 1], q[j])
    trial_circuit.barrier(q)
    for j in range(n):
        if meas_string[j] == 'X':
            trial_circuit.h(q[j])
        elif meas_string[j] == 'Y':
            trial_circuit.s(q[j]).inverse()
            trial_circuit.h(q[j])
    if measurement:
        for j in range(n):
            trial_circuit.measure(q[j], c[j])
    return trial_circuit

# 需要导入模块: from qiskit import QuantumCircuit [as 别名]
# 或者: from qiskit.QuantumCircuit import rz [as 别名]
def trial_circuit_ryrz(n, m, theta, entangler_map, meas_string = None, measurement = True):
    """Trial function for classical optimization problems.

    n = number of qubits
    m = depth
    theta = control vector of size n*m*2 stacked as theta[n*i*2+2*j+p] where j
    counts the qubits and i the depth and p if y and z.
    entangler_map = {0: [2, 1],
                     1: [2],
                     3: [2],
                     4: [2]}
    control is the key and values are the target
    pauli_string = length of number of qubits string
    """
    q = QuantumRegister("q", n)
    c = ClassicalRegister("c", n)
    trial_circuit = QuantumCircuit(q, c)
    trial_circuit.h(q)
    if meas_string is None:
        meas_string = [None for x in range(n)]
    for i in range(m):
        trial_circuit.barrier(q)
        for node in entangler_map:
            for j in entangler_map[node]:
                trial_circuit.cz(q[node], q[j])
        for j in range(n):
            trial_circuit.ry(theta[n * i * 2 + 2*j], q[j])
            trial_circuit.rz(theta[n * i * 2 + 2*j + 1], q[j])
    trial_circuit.barrier(q)
    for j in range(n):
        if meas_string[j] == 'X':
            trial_circuit.h(q[j])
        elif meas_string[j] == 'Y':
            trial_circuit.s(q[j]).inverse()
            trial_circuit.h(q[j])
    if measurement:
        for j in range(n):
            trial_circuit.measure(q[j], c[j])
    return trial_circuit

# 需要导入模块: from qiskit import QuantumCircuit [as 别名]
# 或者: from qiskit.QuantumCircuit import rz [as 别名]
class TestStandard1Q(StandardExtensionTest):
    """Standard Extension Test. Gates with a single Qubit"""

    def setUp(self):
        self.q = QuantumRegister(3, "q")
        self.r = QuantumRegister(3, "r")
        self.c = ClassicalRegister(3, "c")
        self.circuit = QuantumCircuit(self.q, self.r, self.c)
        self.c_header = 69  # lenght of the header

    def test_barrier(self):
        self.circuit.barrier(self.q[1])
        qasm_txt = 'barrier q[1];'
        self.assertResult(Barrier, qasm_txt, qasm_txt)

    def test_barrier_invalid(self):
        c = self.circuit
        self.assertRaises(QISKitError, c.barrier, self.c[0])
        self.assertRaises(QISKitError, c.barrier, self.c)
        self.assertRaises(QISKitError, c.barrier, (self.q, 3))
        self.assertRaises(QISKitError, c.barrier, (self.q, 'a'))
        self.assertRaises(QISKitError, c.barrier, 0)

    def test_barrier_reg(self):
        self.circuit.barrier(self.q)
        qasm_txt = 'barrier q[0],q[1],q[2];'
        self.assertResult(Barrier, qasm_txt, qasm_txt)

    def test_barrier_None(self):
        self.circuit.barrier()
        qasm_txt = 'barrier q[0],q[1],q[2],r[0],r[1],r[2];'
        self.assertResult(Barrier, qasm_txt, qasm_txt)

    def test_ccx(self):
        self.circuit.ccx(self.q[0], self.q[1], self.q[2])
        qasm_txt = 'ccx q[0],q[1],q[2];'
        self.assertResult(ToffoliGate, qasm_txt, qasm_txt)

    def test_ccx_invalid(self):
        c = self.circuit
        self.assertRaises(QISKitError, c.ccx, self.c[0], self.c[1], self.c[2])
        self.assertRaises(QISKitError, c.ccx, self.q[0], self.q[0], self.q[2])
        self.assertRaises(QISKitError, c.ccx, 0, self.q[0], self.q[2])
        self.assertRaises(QISKitError, c.ccx, (self.q, 3), self.q[1], self.q[2])
        self.assertRaises(QISKitError, c.ccx, self.c, self.q, self.q)
        self.assertRaises(QISKitError, c.ccx, 'a', self.q[1], self.q[2])

    def test_ch(self):
        self.circuit.ch(self.q[0], self.q[1])
        qasm_txt = 'ch q[0],q[1];'
        self.assertResult(CHGate, qasm_txt, qasm_txt)

    def test_ch_invalid(self):
        c = self.circuit
        self.assertRaises(QISKitError, c.ch, self.c[0], self.c[1])
        self.assertRaises(QISKitError, c.ch, self.q[0], self.q[0])
        self.assertRaises(QISKitError, c.ch, 0, self.q[0])
        self.assertRaises(QISKitError, c.ch, (self.q, 3), self.q[0])
        self.assertRaises(QISKitError, c.ch, self.c, self.q)
        self.assertRaises(QISKitError, c.ch, 'a', self.q[1])

    def test_crz(self):
        self.circuit.crz(1, self.q[0], self.q[1])
        self.assertResult(CrzGate, 'crz(1) q[0],q[1];', 'crz(-1) q[0],q[1];')

    def test_crz_invalid(self):
        c = self.circuit
        self.assertRaises(QISKitError, c.crz, 0, self.c[0], self.c[1])
        self.assertRaises(QISKitError, c.crz, 0, self.q[0], self.q[0])
        self.assertRaises(QISKitError, c.crz, 0, 0, self.q[0])
        # TODO self.assertRaises(QISKitError, c.crz, self.q[2], self.q[1], self.q[0])
        self.assertRaises(QISKitError, c.crz, 0, self.q[1], self.c[2])
        self.assertRaises(QISKitError, c.crz, 0, (self.q, 3), self.q[1])
        self.assertRaises(QISKitError, c.crz, 0, self.c, self.q)
        # TODO self.assertRaises(QISKitError, c.crz, 'a', self.q[1], self.q[2])

    def test_cswap(self):
        self.circuit.cswap(self.q[0], self.q[1], self.q[2])
        qasm_txt = 'cx q[2],q[1];\nccx q[0],q[1],q[2];\ncx q[2],q[1];'
        self.assertResult(FredkinGate, qasm_txt, qasm_txt)

    def test_cswap_invalid(self):
        c = self.circuit
        self.assertRaises(QISKitError, c.cswap, self.c[0], self.c[1], self.c[2])
        self.assertRaises(QISKitError, c.cswap, self.q[1], self.q[0], self.q[0])
        self.assertRaises(QISKitError, c.cswap, self.q[1], 0, self.q[0])
        self.assertRaises(QISKitError, c.cswap, self.c[0], self.c[1], self.q[0])
        self.assertRaises(QISKitError, c.cswap, self.q[0], self.q[0], self.q[1])
        self.assertRaises(QISKitError, c.cswap, 0, self.q[0], self.q[1])
        self.assertRaises(QISKitError, c.cswap, (self.q, 3), self.q[0], self.q[1])
        self.assertRaises(QISKitError, c.cswap, self.c, self.q[0], self.q[1])
        self.assertRaises(QISKitError, c.cswap, 'a', self.q[1], self.q[2])

    def test_cu1(self):
        self.circuit.cu1(1, self.q[1], self.q[2])
        self.assertResult(Cu1Gate, 'cu1(1) q[1],q[2];', 'cu1(-1) q[1],q[2];')

    def test_cu1_invalid(self):
        c = self.circuit
        self.assertRaises(QISKitError, c.cu1, self.c[0], self.c[1], self.c[2])
#.........这里部分代码省略.........

# 需要导入模块: from qiskit import QuantumCircuit [as 别名]
# 或者: from qiskit.QuantumCircuit import rz [as 别名]

#.........这里部分代码省略.........
        creg is a name string.
        cval is the integer value for the test.
        """
        self.creg = creg
        self.cval = cval

    def drop_condition(self):
        """Drop the current condition."""
        self.creg = None
        self.cval = None

    def start_gate(self, name, args, qubits, nested_scope=None):
        """Begin a custom gate.

        name is name string.
        args is list of Node expression objects.
        qubits is list of (regname, idx) tuples.
        nested_scope is a list of dictionaries mapping expression variables
        to Node expression objects in order of increasing nesting depth.
        """
        if self.listen and name not in self.basis \
           and self.gates[name]["opaque"]:
            raise BackendError("opaque gate %s not in basis" % name)
        if self.listen and name in self.basis:
            self.in_gate = name
            self.listen = False
            # Gate names mapped to number of arguments and qubits
            # and method to invoke on [args, qubits]
            lut = {"ccx": [(0, 3),
                           lambda x: self.circuit.ccx(x[1][0], x[1][1],
                                                      x[1][2])],
                   "ch": [(0, 2),
                          lambda x: self.circuit.ch(x[1][0], x[1][1])],
                   "crz": [(1, 2),
                           lambda x: self.circuit.crz(x[0][0], x[1][0],
                                                      x[1][1])],
                   "cswap": [(0, 3),
                             lambda x: self.circuit.cswap(x[1][0],
                                                          x[1][1],
                                                          x[1][2])],
                   "cu1": [(1, 2),
                           lambda x: self.circuit.cu1(x[0][0], x[1][0],
                                                      x[1][1])],
                   "cu3": [(3, 2), lambda x: self.circuit.cu3(x[0][0],
                                                              x[0][1],
                                                              x[0][2],
                                                              x[1][0],
                                                              x[1][1])],
                   "cx": [(0, 2), lambda x: self.circuit.cx(x[1][0], x[1][1])],
                   "cy": [(0, 2), lambda x: self.circuit.cy(x[1][0], x[1][1])],
                   "cz": [(0, 2), lambda x: self.circuit.cz(x[1][0], x[1][1])],
                   "swap": [(0, 2), lambda x: self.circuit.swap(x[1][0], x[1][1])],
                   "h": [(0, 1), lambda x: self.circuit.h(x[1][0])],
                   "id": [(0, 1), lambda x: self.circuit.iden(x[1][0])],
                   "rx": [(1, 1), lambda x: self.circuit.rx(x[0][0], x[1][0])],
                   "ry": [(1, 1), lambda x: self.circuit.ry(x[0][0], x[1][0])],
                   "rz": [(1, 1), lambda x: self.circuit.rz(x[0][0], x[1][0])],
                   "s": [(0, 1), lambda x: self.circuit.s(x[1][0])],
                   "sdg": [(0, 1), lambda x: self.circuit.s(x[1][0]).inverse()],
                   "t": [(0, 1), lambda x: self.circuit.t(x[1][0]).inverse()],
                   "tdg": [(0, 1), lambda x: self.circuit.t(x[1][0]).inverse()],
                   "u1": [(1, 1), lambda x: self.circuit.u1(x[0][0], x[1][0])],
                   "u2": [(2, 1), lambda x: self.circuit.u2(x[0][0], x[0][1],
                                                            x[1][0])],
                   "u3": [(3, 1), lambda x: self.circuit.u3(x[0][0], x[0][1],
                                                            x[0][2], x[1][0])],