Exemplo n.º 1
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    def test_custom_usual_topologies(self) -> None:
        """
        Tests Sabre on common circuit for some usual custom topologies for different number of qubits.
        """

        for nbqbit in range(2 * min_nbqbit, max_nbqbit):
            nbqbit_circuit = rd.randint(nbqbit // 2, nbqbit)
            circuit = generate_random_circuit(nbqbit_circuit)

            observable = generate_random_observable(nbqbit_circuit)

            qpu_1 = PyLinalg()
            measure_1 = qpu_1.submit(
                circuit.to_job("OBS", observable=observable, nbshots=5))

            for topology in generate_custom_topologies(nbqbit):
                qpu_2 = Sabre() | (QuameleonPlugin(topology=topology)
                                   | PyLinalg())
                measure_2 = qpu_2.submit(
                    circuit.to_job("OBS", observable=observable, nbshots=5))

                check_measures_equality(measure_1, measure_2)

            if nbqbit % 2 == 0:
                topology = Topology.from_nx(
                    nx.grid_2d_graph(nbqbit // 2, nbqbit // 2))
                qpu_2 = Sabre() | (QuameleonPlugin(topology=topology)
                                   | PyLinalg())
                measure_2 = qpu_2.submit(
                    circuit.to_job("OBS", observable=observable, nbshots=5))

                check_measures_equality(measure_1, measure_2)
Exemplo n.º 2
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    def test_custom_usual_topologies(self) -> None:
        """
        Tests Sabre on common circuit for some usual custom topologies for different number of qubits.
        """

        for nbqbit in range(2 * min_nbqbit, max_nbqbit):
            nbqbit_circuit = rd.randint(nbqbit // 2, nbqbit)
            circuit = generate_random_circuit(nbqbit_circuit)

            nb_measured_qubits = rd.randint(1, nbqbit_circuit)
            measured_qubits = rd.sample(range(nbqbit_circuit),
                                        nb_measured_qubits)
            measured_qubits.sort()

            qpu_1 = PyLinalg()
            result_1 = qpu_1.submit(circuit.to_job(qubits=measured_qubits))

            for topology in generate_custom_topologies(nbqbit):
                qpu_2 = Sabre() | (QuameleonPlugin(topology=topology)
                                   | PyLinalg())
                result_2 = qpu_2.submit(circuit.to_job(qubits=measured_qubits))

                check_results_equality(result_1, result_2, amplitude=False)

            if nbqbit % 2 == 0:
                topology = Topology.from_nx(
                    nx.grid_2d_graph(nbqbit // 2, nbqbit // 2))
                qpu_2 = Sabre() | (QuameleonPlugin(topology=topology)
                                   | PyLinalg())
                result_2 = qpu_2.submit(circuit.to_job(qubits=measured_qubits))

                check_results_equality(result_1, result_2, amplitude=False)
Exemplo n.º 3
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    def test_sample_2qb(self):

        qpu = PyLinalg()
        prog = Program()
        qbits = prog.qalloc(2)
        prog.apply(X, qbits[0])
        circ = prog.to_circ()

        obs = Observable(2, pauli_terms=[Term(1., "ZZ", [0, 1])])
        job = circ.to_job("OBS", observable=obs)

        result = qpu.submit(job)
        self.assertAlmostEqual(result.value, -1)

        prog = Program()
        qbits = prog.qalloc(2)
        prog.apply(X, qbits[0])

        prog.apply(X, qbits[1])
        circ = prog.to_circ()

        obs = Observable(2, pauli_terms=[Term(1., "ZZ", [0, 1])])
        job = circ.to_job("OBS", observable=obs)

        result = qpu.submit(job)
        self.assertAlmostEqual(result.value, 1)
    def test_basic(self):
        with self.assertRaises(QPUException):
            prog = Program()
            qbits = prog.qalloc(1)
            prog.apply(X, qbits)
            circ = prog.to_circ()

            obs = Observable(1, pauli_terms=[Term(1., "Z", [0])])
            job = circ.to_job("OBS", observable=obs, nbshots=10)

            qpu = PyLinalg()

            result = qpu.submit(job)
    def check_basic(self, vec):

        SP = AbstractGate("STATE_PREPARATION", [np.ndarray])

        prog = Program()
        reg = prog.qalloc(4)
        prog.apply(SP(vec), reg)
        qpu = PyLinalg()

        res = qpu.submit(prog.to_circ().to_job())

        statevec = np.zeros(2**4, np.complex)
        for sample in res:
            statevec[sample.state.int] = sample.amplitude

        assert (np.linalg.norm(vec - statevec) < 1e-16)
Exemplo n.º 6
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    def test_qft_lnn(self) -> None:
        """
        Tests Sabre on a QFT for LNN topologies for different number of qubits.
        """

        for nbqbit in range(3, max_nbqbit):
            circuit = generate_qft_circuit(nbqbit)

            qpu_1 = PyLinalg()
            result_1 = qpu_1.submit(circuit.to_job())

            qpu_2 = Sabre() | (QuameleonPlugin(topology=Topology(
                type=TopologyType.LNN)) | PyLinalg())
            result_2 = qpu_2.submit(circuit.to_job())

            check_results_equality(result_1, result_2)
Exemplo n.º 7
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    def test3_qlm_backend_run_2_circuit(self):
        """
        Here two circuits run into a QLM QPU by using the QLMBacked object.
        """
        nbqubits = 2
        qreg = QuantumRegister(nbqubits)
        creg = ClassicalRegister(nbqubits)

        qiskit_circuit_1 = QuantumCircuit(qreg, creg)
        qiskit_circuit_1.h(qreg[0])
        qiskit_circuit_1.cx(qreg[0], qreg[1])
        qiskit_circuit_1.measure(qreg, creg)

        qiskit_circuit_2 = QuantumCircuit(qreg, creg)
        qiskit_circuit_2.h(qreg[0])
        qiskit_circuit_2.h(qreg[1])
        qiskit_circuit_2.measure(qreg, creg)

        backend = QiskitConnector() | PyLinalg()
        qiskit_circuits = []
        qiskit_circuits.append(qiskit_circuit_1)
        qiskit_circuits.append(qiskit_circuit_2)

        qobj = assemble(qiskit_circuits)
        result = backend.run(qobj).result()

        LOGGER.debug(
            "\nQPUToBackend test with a list of QLM jobs sent into a QLM qpu:")
        LOGGER.debug(result.results)
        self.assertEqual(2, len(result.results))
Exemplo n.º 8
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    def test_lnn_topology(self) -> None:
        """
        Tests Sabre on common circuit for LNN topologies for different number of qubits.
        """

        for nbqbit in range(2 * min_nbqbit, max_nbqbit):
            circuit = generate_random_circuit(rd.randint(nbqbit // 2, nbqbit))

            qpu_1 = PyLinalg()
            result_1 = qpu_1.submit(circuit.to_job())

            qpu_2 = Sabre() | (QuameleonPlugin(topology=Topology(
                type=TopologyType.LNN)) | PyLinalg())
            result_2 = qpu_2.submit(circuit.to_job())

            check_results_equality(result_1, result_2)
Exemplo n.º 9
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    def test_no_state_modification_circuit(self) -> None:
        """
        We apply Sabre on a circuit which doesn't modify the initial state (|0^n> here) and we verify Sabre circuit
        modifications don't modify the state.
        """

        for nbqbit in range(min_nbqbit, max_nbqbit):
            prog = Program()
            qbits = prog.qalloc(nbqbit)

            random_angles = [
                rd.random() * 2 * np.pi for _ in range(3 * nbqbit)
            ]

            for i in range(len(qbits)):
                prog.apply(RX(random_angles[3 * i]), qbits[i])
                prog.apply(RX(random_angles[3 * i + 1]), qbits[i])
                prog.apply(RX(random_angles[3 * i + 2]), qbits[i])

            prog.apply(QFT(nbqbit), qbits)
            prog.apply(QFT(nbqbit).dag(), qbits)

            for i in range(len(qbits)):
                prog.apply(RX(random_angles[3 * i]).dag(), qbits[i])
                prog.apply(RX(random_angles[3 * i + 1]).dag(), qbits[i])
                prog.apply(RX(random_angles[3 * i + 2]).dag(), qbits[i])

            circuit = prog.to_circ(inline=True)

            for topology in generate_custom_topologies(nbqbit):
                qpu = Sabre() | (QuameleonPlugin(topology=topology)
                                 | PyLinalg())
                result = qpu.submit(circuit.to_job())
                assert result.raw_data[0].state.int == 0
Exemplo n.º 10
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    def test_normal_launch_mode_with_nbshots(self):

        # Create a small program
        prog = Program()
        qubits = prog.qalloc(2)
        prog.apply(H, qubits[0])
        prog.apply(CNOT, qubits)

        circ = prog.to_circ()

        # Simulate
        job = circ.to_job(nbshots=4, aggregate_data=False)
        qpu = PyLinalg()
        result = qpu.submit_job(job)

        self.assertEqual(len(result.raw_data), 4)
        self.assertEqual(result.raw_data[0].probability,
                         None)  #no prob if not aggregating data
Exemplo n.º 11
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 def test_unknown_topology_type(self) -> None:
     """
     Checks Sabre raises PluginException for an unknown topology type.
     """
     with pytest.raises(PluginException):
         circuit = generate_qft_circuit(max_nbqbit)
         qpu = Sabre() | (QuameleonPlugin(topology=Topology(type=-5))
                          | PyLinalg())
         qpu.submit(circuit.to_job())
Exemplo n.º 12
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def test_algorithm(circuit, iterations=(1000000)):
    """
    Tests a circuit by submitting it to both aer_simulator and PyLinalg.
    """
    linalg = PyLinalg()
    qlm_circ, _ = qiskit_to_qlm(circuit, sep_measures=True)
    test_job = qlm_circ.to_job(nbshots=0, aggregate_data=False)
    expected = linalg.submit(test_job)

    qiskit_qpu = BackendToQPU(Aer.get_backend('aer_simulator'))

    test_job.nbshots = iterations
    result = qiskit_qpu.submit(test_job)

    dist_calc = compare_results(expected, result, aggregate=False)
    distance = analyze_distance(dist_calc)
    print("Distance is {}".format(distance))
    return distance
Exemplo n.º 13
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 def test_gate_more_two_qubits(self) -> None:
     """
     Checks Sabre raises PluginException if there is a circuit containing a gate with more than two qubits.
     """
     with pytest.raises(PluginException):
         circuit = generate_qft_circuit(max_nbqbit, inline=False)
         qpu = Sabre() | (QuameleonPlugin(topology=Topology(
             type=TopologyType.LNN)) | PyLinalg())
         qpu.submit(circuit.to_job())
Exemplo n.º 14
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    def test_qft_custom_usual_topologies(self) -> None:
        """
        Tests Sabre on a QFT for some usual custom topologies for different number of qubits.
        """

        for nbqbit in range(5, max_nbqbit):
            circuit = generate_qft_circuit(nbqbit)

            qpu_1 = PyLinalg()
            result_1 = qpu_1.submit(circuit.to_job())

            for topology in generate_custom_topologies(nbqbit):
                print('Number of qubits : ', nbqbit)
                print('Current topology : ', topology)
                qpu_2 = Sabre() | (QuameleonPlugin(topology=topology)
                                   | PyLinalg())
                result_2 = qpu_2.submit(circuit.to_job())
                check_results_equality(result_1, result_2)
Exemplo n.º 15
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 def test_custom_topology_without_graph(self) -> None:
     """
     Checks Sabre raises PluginException if TopologyType is CUSTOM but no graph is provided.
     """
     with pytest.raises(PluginException):
         circuit = generate_qft_circuit(max_nbqbit)
         qpu = Sabre() | (QuameleonPlugin(topology=Topology(
             type=TopologyType.CUSTOM)) | PyLinalg())
         qpu.submit(circuit.to_job())
Exemplo n.º 16
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    def test_measure(self):
        """test that state indexing is same as other simulation services"""
        # program with final state: qbit 0 : 0 or 1 with 50% proba
        prog = Program()
        reg = prog.qalloc(1)
        creg = prog.calloc(1)
        prog.apply(H, reg)
        prog.measure(reg, creg)
        circ = prog.to_circ()

        qpu = PyLinalg()

        result = qpu.submit(circ.to_job(nbshots=5, aggregate_data=False))
        for res in result:

            self.assertAlmostEqual(
                res.intermediate_measurements[0].probability, 0.5, delta=1e-10)
            self.assertEqual(res.intermediate_measurements[0].cbits[0],
                             res.state.int)
Exemplo n.º 17
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    def test_normal_launch_mode(self):

        # Create a small program
        prog = Program()
        qubits = prog.qalloc(2)
        prog.apply(H, qubits[0])
        prog.apply(CNOT, qubits)

        circ = prog.to_circ()

        # Simulate
        job = circ.to_job()
        qpu = PyLinalg()
        result = qpu.submit_job(job)

        self.assertEqual(len(result.raw_data), 2)

        self.assertAlmostEqual(result.raw_data[0].probability, 0.5)
        self.assertTrue(result.raw_data[0].state.int in [0, 3])
        self.assertTrue(result.raw_data[1].state.int in [0, 3])
Exemplo n.º 18
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    def test_normal_launch_mode_with_nbshots_and_qbs(self):

        # Create a small program
        prog = Program()
        qubits = prog.qalloc(2)
        prog.apply(H, qubits[0])
        prog.apply(CNOT, qubits)

        circ = prog.to_circ()

        # Simulate
        job = circ.to_job(nbshots=4, qubits=[0], aggregate_data=False)
        qpu = PyLinalg()
        result = qpu.submit_job(job)

        self.assertEqual(len(result.raw_data), 4)

        self.assertEqual(result.raw_data[0].probability,
                         None)  #No probability if not aggregating data
        for rd in result.raw_data:
            self.assertTrue(rd.state.int in [0, 1], msg="state= %s" % rd.state)
Exemplo n.º 19
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    def test_lnn_topology(self) -> None:
        """
        Tests Sabre on common circuit for LNN topologies for different number of qubits.
        """

        for nbqbit in range(2 * min_nbqbit, max_nbqbit):
            nbqbit_circuit = rd.randint(nbqbit // 2, nbqbit)
            circuit = generate_random_circuit(nbqbit_circuit)

            observable = generate_random_observable(nbqbit_circuit)

            qpu_1 = PyLinalg()
            measure_1 = qpu_1.submit(
                circuit.to_job("OBS", observable=observable))

            qpu_2 = Sabre() | (QuameleonPlugin(topology=Topology(
                type=TopologyType.LNN)) | PyLinalg())
            measure_2 = qpu_2.submit(
                circuit.to_job("OBS", observable=observable))

            check_measures_equality(measure_1, measure_2)
Exemplo n.º 20
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 def test_too_much_qubits(self) -> None:
     """
     Checks Sabre raises PluginException if there are more qubits in the circuit than in the topology.
     """
     with pytest.raises(PluginException):
         circuit = generate_qft_circuit(max_nbqbit)
         qpu = Sabre() | (QuameleonPlugin(topology=Topology(
             type=TopologyType.CUSTOM, graph={
                 0: [1],
                 1: [0]
             })) | PyLinalg())
         qpu.submit(circuit.to_job())
Exemplo n.º 21
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    def test_lnn_topology(self) -> None:
        """
        Tests Sabre on common circuit for LNN topologies for different number of qubits.
        """

        for nbqbit in range(2 * min_nbqbit, max_nbqbit):
            nbqbit_circuit = rd.randint(nbqbit // 2, nbqbit)
            circuit = generate_random_circuit(nbqbit_circuit)

            nb_measured_qubits = rd.randint(1, nbqbit_circuit)
            measured_qubits = rd.sample(range(nbqbit_circuit),
                                        nb_measured_qubits)
            measured_qubits.sort()

            qpu_1 = PyLinalg()
            result_1 = qpu_1.submit(circuit.to_job(qubits=measured_qubits))

            qpu_2 = Sabre() | (QuameleonPlugin(topology=Topology(
                type=TopologyType.LNN)) | PyLinalg())
            result_2 = qpu_2.submit(circuit.to_job(qubits=measured_qubits))

            check_results_equality(result_1, result_2, amplitude=False)
Exemplo n.º 22
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    def test_qft(self):
        """ Testing simulation of inlined/not-inlined QFT """
        prog = Program()
        qbits = prog.qalloc(5)
        prog.apply(QFT(5), qbits)
        circuit_default = prog.to_circ()
        circuit_inlined = prog.to_circ(inline=True)

        qpu = PyLinalg()

        psi_d = wavefunction(circuit_default, qpu)
        psi_i = wavefunction(circuit_inlined, qpu)

        self.assertAlmostEqual(np.linalg.norm(psi_d - psi_i), 0.)
Exemplo n.º 23
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    def test2_qlm_backend_run_1_circuit(self):
        """
        Here a circuit runs into a QLM QPU by using the QLMBacked object.
        """
        nbqubits = 2
        qreg = QuantumRegister(nbqubits)
        creg = ClassicalRegister(nbqubits)

        qiskit_circuit = QuantumCircuit(qreg, creg)

        qiskit_circuit.h(qreg[0])
        qiskit_circuit.cx(qreg[0], qreg[1])
        qiskit_circuit.measure(qreg, creg)

        backend = QiskitConnector() | PyLinalg()
        result = backend.run(qiskit_circuit).result()

        LOGGER.debug("\nQPUToBackend test with a QLM job sent into a QLM qpu:")
        LOGGER.debug(result.results)
        self.assertEqual(1, len(result.results))
Exemplo n.º 24
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    def test1_qlm_backend_connector(self):
        """
        The QPUToBackend object is here generated by using the QiskitConnector.
        """
        nbqubits = 2

        qreg = QuantumRegister(nbqubits)
        creg = ClassicalRegister(nbqubits)

        qiskit_circuit = QuantumCircuit(qreg, creg)

        qiskit_circuit.h(qreg[0])
        qiskit_circuit.cx(qreg[0], qreg[1])
        qiskit_circuit.measure(qreg, creg)

        backend = QiskitConnector() | PyLinalg()

        result = execute(qiskit_circuit, backend, shots=15).result()

        LOGGER.debug("\nQPUToBackend test via QiskitConnector:")
        LOGGER.debug(result.results)
        self.assertEqual(1, len(result.results))
Exemplo n.º 25
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    def test0_qlm_backend(self):
        """
        Simple test for QPUToBackend object generation and basic use.
        """
        nbqubits = 2

        qreg = QuantumRegister(nbqubits)
        creg = ClassicalRegister(nbqubits)

        qiskit_circuit = QuantumCircuit(qreg, creg)

        qiskit_circuit.h(qreg[0])
        qiskit_circuit.cx(qreg[0], qreg[1])
        qiskit_circuit.measure(qreg, creg)

        qpu = PyLinalg()
        backend = QPUToBackend(qpu)

        result = execute(qiskit_circuit, backend, shots=15).result()

        LOGGER.debug("\nQPUToBackend test:")
        LOGGER.debug(result.results)
        self.assertEqual(1, len(result.results))
Exemplo n.º 26
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    def test_sample_1qb_Y(self):

        prog = Program()
        qbits = prog.qalloc(1)
        prog.apply(H, qbits)
        prog.apply(PH(-np.pi / 2), qbits)
        circ = prog.to_circ()

        obs = Observable(1, pauli_terms=[Term(1., "Y", [0])])
        job = circ.to_job("OBS", observable=obs)

        qpu = PyLinalg()
        result = qpu.submit(job)
        self.assertAlmostEqual(result.value, -1)

        obs = Observable(1, pauli_terms=[Term(18., "Y", [0])])
        job = circ.to_job("OBS", observable=obs)

        result = qpu.submit(job)
        self.assertAlmostEqual(result.value, -18)

        prog = Program()
        qbits = prog.qalloc(1)
        prog.apply(H, qbits)
        prog.apply(PH(np.pi / 2), qbits)
        circ = prog.to_circ()

        obs = Observable(1, pauli_terms=[Term(1., "Y", [0])])
        job = circ.to_job("OBS", observable=obs)

        result = qpu.submit(job)
        self.assertAlmostEqual(result.value, 1)

        obs = Observable(1, pauli_terms=[Term(18., "Y", [0])])
        job = circ.to_job("OBS", observable=obs)

        result = qpu.submit(job)
        self.assertAlmostEqual(result.value, 18)