コード例 #1
0
ファイル: cirqSim.py プロジェクト: JanisM91/Quasim
    def buildCirqCircuit(self, qubits, circuit):
        cirqCircuit = cirq.Circuit()
        ## Instantiate a CNot Gate
        cNotGate = cirq.CNotGate()
        ## Instantiate a Swap Gate
        swapGate = cirq.SwapGate()
        control = 0
        controlFirst = False

        for j in range(len(circuit[0])):
            for i in range(len(circuit)):
                if circuit[i][j] == "Pauli-X-Gate":
                    cirqCircuit.append(cirq.X(qubits[i]))
                elif circuit[i][j] == "Pauli-Y-Gate":
                    cirqCircuit.append(cirq.Y(qubits[i]))
                elif circuit[i][j] == "Pauli-Z-Gate":
                    cirqCircuit.append(cirq.Z(qubits[i]))
                elif circuit[i][j] == "Hadamard Gate":
                    cirqCircuit.append(cirq.H(qubits[i]))
                elif circuit[i][j] == "S Gate":
                    cirqCircuit.append(cirq.S(qubits[i]))
                elif circuit[i][j] == "T Gate":
                    cirqCircuit.append(cirq.T(qubits[i]))
                elif circuit[i][j] == "Identity":
                    pass
                elif circuit[i][j] == "CNot Gate":
                    if controlFirst:
                        cirqCircuit.append(cNotGate(control, qubits[i]))
                    else:
                        cirqCircuit.append(cNotGate(qubits[i + 1], qubits[i]))
                elif circuit[i][j] == "Swap Gate":
                    cirqCircuit.append(cirq.swapGate(control, qubits[i]))
                elif circuit[i][j] == "Deutsch OracleC":
                    pass
                elif circuit[i][j] == "Deutsch Oracle":
                    if randint(0, 1) == 1:
                        cirqCircuit.append(cNotGate(qubits[i - 1], qubits[i]))
                    else:
                        pass
                elif circuit[i][j] == "Fredkin Gate":
                    cirqCircuit.append(
                        cirq.CSWAP(qubits[i], qubits[i + 1], qubits[i + 2]))
                elif circuit[i][j] == "Toffoli Gate":
                    cirqCircuit.append(
                        cirq.TOFFOLI(qubits[i - 2], qubits[i - 1], qubits[i]))
                elif "Control" in circuit[i][j]:
                    if not controlFirst:
                        control = qubits[i]
                        controlFirst = True
                elif "Measurement" in circuit[i][j]:
                    cirqCircuit.append(
                        cirq.measure(qubits[i], key=str(i) + " " + str(j)))

        if DEBUG:
            print(
                "Class: cirqSim Function: buildCirqCircuit Line: 42 Output: cirqCircuit after being completely build"
            )
            print(cirqCircuit)

        return cirqCircuit
コード例 #2
0
def test_text_to_qcircuit_diagrammable():
    qubits = cirq.NamedQubit('x'), cirq.NamedQubit('y')

    g = cirq.SwapGate(half_turns=0.5)
    f = _TextToQCircuitDiagrammable(g)
    qubit_map = {q: i for i, q in enumerate(qubits)}
    actual_info = f.qcircuit_diagram_info(
        cirq.CircuitDiagramInfoArgs(known_qubits=qubits,
                                    known_qubit_count=None,
                                    use_unicode_characters=True,
                                    precision=3,
                                    qubit_map=qubit_map))
    name = '{\\text{SWAP}^{0.5}}'
    expected_info = cirq.CircuitDiagramInfo(
        ('\multigate{1}' + name, '\ghost' + name),
        exponent=0.5,
        connected=False)
    assert actual_info == expected_info

    g = cirq.SWAP
    f = _TextToQCircuitDiagrammable(g)
    qubit_map = {q: i for q, i in zip(qubits, (4, 3))}
    actual_info = f.qcircuit_diagram_info(
        cirq.CircuitDiagramInfoArgs(known_qubits=qubits,
                                    known_qubit_count=None,
                                    use_unicode_characters=True,
                                    precision=3,
                                    qubit_map=qubit_map))
    expected_info = cirq.CircuitDiagramInfo(
        ('\ghost{\\text{SWAP}}', '\multigate{1}{\\text{SWAP}}'),
        connected=False)
    assert actual_info == expected_info

    qubit_map = {q: i for q, i in zip(qubits, (2, 5))}
    actual_info = f.qcircuit_diagram_info(
        cirq.CircuitDiagramInfoArgs(known_qubits=qubits,
                                    known_qubit_count=None,
                                    use_unicode_characters=True,
                                    precision=3,
                                    qubit_map=qubit_map))
    expected_info = cirq.CircuitDiagramInfo(('\\gate{\\text{×}}', ) * 2)
    assert actual_info == expected_info

    actual_info = f.qcircuit_diagram_info(
        cirq.CircuitDiagramInfoArgs.UNINFORMED_DEFAULT)
    assert actual_info == expected_info
コード例 #3
0
def main():
    # Pick a qubit.
    q0 = cirq.GridQubit(0, 0)
    q1 = cirq.GridQubit(0, 1)

    q2 = cirq.GridQubit(1, 0)
    q3 = cirq.GridQubit(1, 1)

    q4 = cirq.GridQubit(2, 0)
    q5 = cirq.GridQubit(2, 1)

    Swap = cirq.SwapGate()

    # Create a circuit
    circuit = cirq.Circuit.from_ops(cirq.measure(q0, key='q0 before swap'),
                                    cirq.measure(q1, key='q1 before swap'),
                                    Swap(q0, q1),
                                    cirq.measure(q0, key='q0 after swap'),
                                    cirq.measure(q1, key='q1 after swap'),
                                    cirq.X(q2),
                                    cirq.measure(q2, key='q2 before swap'),
                                    cirq.measure(q3, key='q3 before swap'),
                                    Swap(q2, q3),
                                    cirq.measure(q2, key='q2 after swap'),
                                    cirq.measure(q3, key='q3 after swap'),
                                    cirq.X(q5),
                                    cirq.measure(q4, key='q4 before swap'),
                                    cirq.measure(q5, key='q5 before swap'),
                                    Swap(q4, q5),
                                    cirq.measure(q4, key='q4 after swap'),
                                    cirq.measure(q5, key='q5 after swap'))
    print("Circuit:")
    print(circuit)

    # Simulate the circuit 50 times.
    simulator = cirq.google.XmonSimulator()
    result = simulator.run(circuit, repetitions=50)
    print("Results of simulation:")
    print(result)

    # Run the simulator with direct access to the wave function of the quantum processor
    resultw = simulator.simulate(circuit)
    print("Result from wave function:")
    print(resultw)