Esempio n. 1
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def test_inverse():
    # Random circuit
    circ = qf.Circuit()
    circ += qf.TY(1 / 2, 0)
    circ += qf.H(0)
    circ += qf.TY(1 / 2, 1)
    circ += qf.TX(1.23123, 1)
    circ += qf.CNOT(0, 1)
    circ += qf.TX(-1 / 2, 1)
    circ += qf.TY(4.71572463191 / pi, 1)
    circ += qf.CNOT(0, 1)
    circ += qf.TX(-2 * 2.74973750579 / pi, 0)
    circ += qf.TX(-2 * 2.74973750579 / pi, 1)

    circ_inv = circ.H

    ket = circ.run()
    qf.print_state(ket)

    ket = circ_inv.run(ket)
    qf.print_state(ket)

    print(ket.qubits)
    print(true_ket().qubits)
    assert qf.states_close(ket, qf.zero_state(2))

    ket = qf.zero_state(2)
    circ.extend(circ_inv)
    ket = circ.run(ket)
    assert qf.states_close(ket, qf.zero_state(2))
Esempio n. 2
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def test_CH():
    # Construct a controlled Hadamard gate
    gate = qf.identity_gate(2)

    gate = qf.S(1).H @ gate
    gate = qf.H(1) @ gate
    gate = qf.T(1).H @ gate
    gate = qf.CNOT(0, 1) @ gate
    gate = qf.T(1) @ gate
    gate = qf.H(1) @ gate
    gate = qf.S(1) @ gate

    # Do nothing
    ket = qf.zero_state(2)
    ket = gate.run(ket)
    assert qf.states_close(ket, qf.zero_state(2))

    # Do nothing
    ket = qf.zero_state(2)
    ket = qf.X(0).run(ket)
    ket = gate.run(ket)

    ket = qf.H(1).run(ket)

    ket = qf.X(0).run(ket)
    assert qf.states_close(ket, qf.zero_state(2))
Esempio n. 3
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def test_inverse() -> None:
    # Random circuit
    circ = qf.Circuit()
    circ += qf.YPow(1 / 2, 0)
    circ += qf.H(0)
    circ += qf.YPow(1 / 2, 1)
    circ += qf.XPow(1.23123, 1)
    circ += qf.CNot(0, 1)
    circ += qf.XPow(-1 / 2, 1)
    circ += qf.YPow(4.71572463191 / np.pi, 1)
    circ += qf.CNot(0, 1)
    circ += qf.XPow(-2 * 2.74973750579 / np.pi, 0)
    circ += qf.XPow(-2 * 2.74973750579 / np.pi, 1)

    circ_inv = circ.H

    ket = circ.run()
    # qf.print_state(ket)

    ket = circ_inv.run(ket)
    # qf.print_state(ket)

    # print(ket.qubits)
    # print(true_ket().qubits)
    assert qf.states_close(ket, qf.zero_state(2))

    ket = qf.zero_state(2)
    circ += circ_inv
    ket = circ.run(ket)
    assert qf.states_close(ket, qf.zero_state(2))
Esempio n. 4
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def test_join_gates():
    gate = qf.join_gates(qf.H(0), qf.X(1))
    ket = qf.zero_state(2)
    ket = gate.run(ket)
    ket = qf.H(0).run(ket)
    ket = qf.X(1).run(ket)

    assert qf.states_close(ket, qf.zero_state(2))
Esempio n. 5
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def test_outer_product():
    with pytest.raises(ValueError):
        ket = qf.zero_state(1)
        gate = qf.I(2)
        qf.outer_product(ket.vec, gate.vec)

    with pytest.raises(ValueError):
        ket0 = qf.zero_state([0, 1, 2])
        ket1 = qf.zero_state([2, 3, 4])
        qf.outer_product(ket0.vec, ket1.vec)
Esempio n. 6
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def test_create():
    gen = [qf.H(i) for i in range(8)]

    circ1 = qf.Circuit(list(gen))
    circ1.run(qf.zero_state(8))

    circ2 = qf.Circuit(gen)
    circ2.run(qf.zero_state(8))

    circ3 = qf.Circuit(qf.H(i) for i in range(8))
    circ3.run(qf.zero_state(8))
Esempio n. 7
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def test_join_states() -> None:
    q0 = qf.zero_state([0])
    q1 = qf.zero_state([1, 2])
    q2 = qf.join_states(q0, q1)
    assert q2.qubit_nb == 3
    assert q2.tensor[0, 0, 0] == 1

    q3 = qf.zero_state([3, 4, 5])
    q3 = qf.X(4).run(q3)

    q4 = qf.join_states(qf.join_states(q0, q1), q3)
    assert q4.qubit_nb == 6
    assert q4.tensor[0, 0, 0, 0, 1, 0] == 1
Esempio n. 8
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def test_gradients() -> None:
    # This test only checks that code runs, not that we get correct answers
    # graph = nx.grid_graph([2, 3])
    graph = nx.grid_graph([2, 1])
    layers = 2
    params = qf.graph_circuit_params(graph, layers)
    circ = qf.graph_circuit(graph, layers, params)
    circ += qf.H((1, 1))  # add a non-parameterized gate. Should be ignored

    qubits = circ.qubits
    ket0 = qf.zero_state(qubits)
    ket1 = qf.random_state(qubits)

    grads0 = qf.state_fidelity_gradients(ket0, ket1, circ)
    # print(grads0)

    _ = qf.state_angle_gradients(ket0, ket1, circ)
    # print(grads1)

    proj = qf.Projection([ket1])
    grads2 = qf.expectation_gradients(ket0, circ, hermitian=proj)
    # print(grads2)

    # Check that qf.expectation_gradients() gives same answers for
    # fidelity as f.state_fidelity_gradients()
    for g0, g1 in zip(grads0, grads2):
        assert np.isclose(g0, g1)
        print(g0, g1)
Esempio n. 9
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def test_biased_coin():
    # sample from a 75% head and 25% tails coin
    rho = qf.zero_state(1).asdensity()
    chan = qf.RX(np.pi / 3, 0).aschannel()
    rho = chan.evolve(rho)
    prob = qf.asarray(rho.probabilities())
    assert np.allclose(prob, [0.75, 0.25])
Esempio n. 10
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def test_run() -> None:
    x = sX(1)
    y = sY(2, 1.2)
    s = x + y

    ket0 = qf.zero_state(3)
    _ = s.run(ket0)
Esempio n. 11
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def test_fubini_study_angle_states() -> None:
    # The state angle is half angle in Bloch sphere
    angle1 = 0.1324
    ket1 = qf.zero_state(1)
    ket2 = qf.Rx(angle1, 0).run(ket1)
    angle2 = qf.fubini_study_angle(ket1.tensor, ket2.tensor)
    assert np.isclose(angle1, angle2 * 2)
Esempio n. 12
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def test_inner_product():
    # also tested via test_gate_angle

    for _ in range(REPS):
        theta = random.uniform(-4 * pi, +4 * pi)

        hs = qf.asarray(qf.inner_product(qf.RX(theta).vec, qf.RX(theta).vec))
        print('RX({}), hilbert_schmidt = {}'.format(theta, hs))
        assert hs / 2 == ALMOST_ONE

        hs = qf.asarray(qf.inner_product(qf.RZ(theta).vec, qf.RZ(theta).vec))
        print('RZ({}), hilbert_schmidt = {}'.format(theta, hs))
        assert hs / 2 == ALMOST_ONE

        hs = qf.asarray(qf.inner_product(qf.RY(theta).vec, qf.RY(theta).vec))
        print('RY({}), hilbert_schmidt = {}'.format(theta, hs))
        assert hs / 2 == ALMOST_ONE

        hs = qf.asarray(
            qf.inner_product(qf.PSWAP(theta).vec,
                             qf.PSWAP(theta).vec))
        print('PSWAP({}), hilbert_schmidt = {}'.format(theta, hs))
        assert hs / 4 == ALMOST_ONE

    with pytest.raises(ValueError):
        qf.inner_product(qf.zero_state(0).vec, qf.X(0).vec)

    with pytest.raises(ValueError):
        qf.inner_product(qf.CNOT(0, 1).vec, qf.X(0).vec)
Esempio n. 13
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def test_qftgate() -> None:
    circ = qf.Circuit()
    circ += qf.X(2)
    circ += qf.QFTGate([0, 1, 2])

    ket = qf.zero_state(3)
    ket = circ.run(ket)

    true_qft = qf.State(
        [
            0.35355339 + 0.0j,
            0.25000000 + 0.25j,
            0.00000000 + 0.35355339j,
            -0.25000000 + 0.25j,
            -0.35355339 + 0.0j,
            -0.25000000 - 0.25j,
            0.00000000 - 0.35355339j,
            0.25000000 - 0.25j,
        ]
    )

    assert qf.states_close(ket, true_qft)

    assert isinstance(qf.QFTGate([0, 1, 2]).H, qf.InvQFTGate)
    assert isinstance(qf.QFTGate([0, 1, 2]).H.H, qf.QFTGate)

    qf.QFTGate([0, 1, 2]).H.tensor
Esempio n. 14
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def test_fubini_study_angle_states():
    # The state angle is half angle in Bloch sphere
    angle1 = 0.1324
    ket1 = qf.zero_state(1)
    ket2 = qf.RX(angle1, 0).run(ket1)
    angle2 = qf.asarray(qf.fubini_study_angle(ket1.vec, ket2.vec))
    assert angle1 - angle2 * 2 == ALMOST_ZERO
Esempio n. 15
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def test_inner_product() -> None:
    # also tested via fubini_study_angle

    for _ in range(REPS):
        theta = random.uniform(-4 * pi, +4 * pi)

        hs = tensors.inner(qf.Rx(theta, 0).tensor, qf.Rx(theta, 0).tensor)
        print(f"Rx({theta}), hilbert_schmidt = {hs}")
        assert np.isclose(hs / 2, 1.0)

        hs = tensors.inner(qf.Rz(theta, 0).tensor, qf.Rz(theta, 0).tensor)
        print(f"Rz({theta}), hilbert_schmidt = {hs}")
        assert np.isclose(hs / 2, 1.0)

        hs = tensors.inner(qf.Ry(theta, 0).tensor, qf.Ry(theta, 0).tensor)
        print(f"Ry({theta}), hilbert_schmidt = {hs}")
        assert np.isclose(hs / 2, 1.0)

        hs = tensors.inner(
            qf.PSwap(theta, 0, 1).tensor,
            qf.PSwap(theta, 0, 1).tensor)
        print(f"PSwap({theta}), hilbert_schmidt = {hs}")
        assert np.isclose(hs / 4, 1.0)

    with pytest.raises(ValueError):
        tensors.inner(qf.zero_state(0).tensor, qf.X(0).tensor)

    with pytest.raises(ValueError):
        tensors.inner(qf.CNot(0, 1).tensor, qf.X(0).tensor)
Esempio n. 16
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def test_sample() -> None:
    ket = qf.zero_state(2)
    ket = qf.H(0).run(ket)
    ket = qf.CNot(0, 1).run(ket)

    samples = ket.sample(10)
    assert samples.sum() == 10
Esempio n. 17
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def test_expectation() -> None:
    ket = qf.zero_state(1)
    ket = qf.H(0).run(ket)

    m = ket.expectation([0.4, 0.6])
    assert np.isclose(m, 0.5)

    ket.expectation([0.4, 0.6], 10)
Esempio n. 18
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def test_expectation():
    ket = qf.zero_state(1)
    ket = qf.H(0).run(ket)

    m = ket.expectation([0.4, 0.6])
    assert qf.asarray(m) - 0.5 == ALMOST_ZERO

    m = ket.expectation([0.4, 0.6], 10)
Esempio n. 19
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def test_join_states():
    q0 = qf.zero_state([0])
    q1 = qf.zero_state([1, 2])
    q2 = qf.join_states(q0, q1)
    assert q2.qubit_nb == 3
    assert q2.vec.asarray()[0, 0, 0] == ALMOST_ONE

    q3 = qf.zero_state([3, 4, 5])
    q3 = qf.X(4).run(q3)

    print(q0)
    print(q1)
    print(q3)

    q4 = qf.join_states(qf.join_states(q0, q1), q3)
    assert q4.qubit_nb == 6
    assert q4.vec.asarray()[0, 0, 0, 0, 1, 0] == ALMOST_ONE
Esempio n. 20
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def test_CZ() -> None:
    ket = qf.zero_state(2)
    ket = qf.CZ(0, 1).run(ket)
    assert ket.tensor[0, 0] == 1.0

    ket = qf.X(0).run(ket)
    ket = qf.X(1).run(ket)
    ket = qf.CZ(0, 1).run(ket)
    assert -ket.tensor[1, 1] == 1.0
Esempio n. 21
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def test_bits() -> None:

    ket = qf.X(0).run(qf.zero_state(4))
    assert ket.tensor[1, 0, 0, 0] == 1
    ket = qf.X(1).run(qf.zero_state(4))
    assert ket.tensor[0, 1, 0, 0] == 1
    ket = qf.X(2).run(qf.zero_state(4))
    assert ket.tensor[0, 0, 1, 0] == 1
    ket = qf.X(3).run(qf.zero_state(4))
    assert ket.tensor[0, 0, 0, 1] == 1

    ket = qf.zero_state(8)
    ket = qf.X(2).run(ket)
    ket = qf.X(4).run(ket)
    ket = qf.X(6).run(ket)

    res = ket.tensor
    assert res[0, 0, 1, 0, 1, 0, 1, 0]
Esempio n. 22
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def test_CZ():
    ket = qf.zero_state(2)
    ket = qf.CZ(0, 1).run(ket)
    assert ket.vec.asarray()[0, 0] == ALMOST_ONE

    ket = qf.X(0).run(ket)
    ket = qf.X(1).run(ket)
    ket = qf.CZ(0, 1).run(ket)
    assert -ket.vec.asarray()[1, 1] == ALMOST_ONE
Esempio n. 23
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def test_sample_bell() -> None:
    rho = qf.zero_state(2).asdensity()
    chan = qf.H(0).aschannel()
    rho = chan.evolve(rho)
    chan = qf.CNot(0, 1).aschannel()
    rho = chan.evolve(rho)
    prob = rho.probabilities()

    assert np.allclose(prob, [[0.5, 0], [0, 0.5]])
Esempio n. 24
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def test_cswap():
    ket = qf.zero_state(3)
    ket = qf.X(1).run(ket)
    ket = qf.CSWAP(0, 1, 2).run(ket)
    assert ket.vec.asarray()[0, 1, 0] == ALMOST_ONE

    ket = qf.X(0).run(ket)
    ket = qf.CSWAP(0, 1, 2).run(ket)
    assert ket.vec.asarray()[1, 0, 1] == ALMOST_ONE
Esempio n. 25
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def test_sample_bell():
    rho = qf.zero_state(2).asdensity()
    chan = qf.H(0).aschannel()
    rho = chan.evolve(rho)
    chan = qf.CNOT(0, 1).aschannel()  # TODO: chanmul
    rho = chan.evolve(rho)
    prob = qf.asarray(rho.probabilities())

    assert np.allclose(prob, [[0.5, 0], [0, 0.5]])
Esempio n. 26
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def test_bits():

    ket = qf.X(0).run(qf.zero_state(4))
    assert ket.vec.asarray()[1, 0, 0, 0] == ALMOST_ONE
    ket = qf.X(1).run(qf.zero_state(4))
    assert ket.vec.asarray()[0, 1, 0, 0] == ALMOST_ONE
    ket = qf.X(2).run(qf.zero_state(4))
    assert ket.vec.asarray()[0, 0, 1, 0] == ALMOST_ONE
    ket = qf.X(3).run(qf.zero_state(4))
    assert ket.vec.asarray()[0, 0, 0, 1] == ALMOST_ONE

    ket = qf.zero_state(8)
    ket = qf.X(2).run(ket)
    ket = qf.X(4).run(ket)
    ket = qf.X(6).run(ket)

    res = ket.vec.asarray()

    assert res[0, 0, 1, 0, 1, 0, 1, 0]
Esempio n. 27
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def test_conditional_gate() -> None:
    controlled_gate = qf.conditional_gate(0, qf.X(1), qf.Y(1))

    state = qf.zero_state(2)
    state = controlled_gate.run(state)
    assert state.tensor[0, 1] == 1.0

    state = qf.X(0).run(state)
    state = controlled_gate.run(state)
    assert 1.0j * state.tensor[1, 0] == 1.0
Esempio n. 28
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def prepare_w16():
    """
    Prepare a 16-qubit W state using sqrt(iswaps) and local gates,
    respecting linear topology

    """
    ket = qf.zero_state(16)
    circ = w16_circuit()
    ket = circ.run(ket)
    return ket
Esempio n. 29
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def test_conditional_gate():
    controlled_gate = qf.conditional_gate(0, qf.X(1), qf.Y(1))

    state = qf.zero_state(2)
    state = controlled_gate.run(state)
    assert state.vec.asarray()[0, 1] == ALMOST_ONE

    state = qf.X(0).run(state)
    state = controlled_gate.run(state)
    assert 1.0j * state.vec.asarray()[1, 0] == ALMOST_ONE
Esempio n. 30
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def test_projectors() -> None:
    ket = qf.zero_state(1)
    assert qf.P0(0).run(ket).norm() == 1.0

    ket = qf.H(0).run(ket)

    measure0 = qf.P0(0).run(ket)
    assert np.isclose(measure0.norm(), 0.5)

    measure1 = qf.P1(0).run(ket)
    assert np.isclose(measure1.norm(), 0.5)