Esempio n. 1
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def test_add_circuit_with_target_and_non_continuous_qubits():
    widget = Circuit().h(5).h(50).h(100)
    circ = Circuit().add_circuit(widget, target=[1, 3, 5])
    expected = (Circuit().add_instruction(Instruction(
        Gate.H(), 1)).add_instruction(Instruction(
            Gate.H(), 3)).add_instruction(Instruction(Gate.H(), 5)))
    assert circ == expected
def test_equality():
    instr_1 = Instruction(Gate.H(), 0)
    instr_2 = Instruction(Gate.H(), 0)
    other_instr = Instruction(Gate.CNot(), [0, 1])
    non_instr = "non instruction"

    assert instr_1 == instr_2
    assert instr_1 is not instr_2
    assert instr_1 != other_instr
    assert instr_1 != non_instr
Esempio n. 3
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def test_basis_rotation_instructions_all():
    circ = Circuit().h(0).cnot(0, 1).sample(observable=Observable.Y())
    expected = [
        Instruction(Gate.Z(), 0),
        Instruction(Gate.S(), 0),
        Instruction(Gate.H(), 0),
        Instruction(Gate.Z(), 1),
        Instruction(Gate.S(), 1),
        Instruction(Gate.H(), 1),
    ]
    assert circ.basis_rotation_instructions == expected
Esempio n. 4
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def test_add_verbatim_box_different_qubits():
    circ = Circuit().h(1).add_verbatim_box(Circuit().h(0)).cnot(3, 4)
    expected = (Circuit().add_instruction(Instruction(
        Gate.H(),
        1)).add_instruction(Instruction(
            compiler_directives.StartVerbatimBox())).add_instruction(
                Instruction(Gate.H(), 0)).add_instruction(
                    Instruction(
                        compiler_directives.EndVerbatimBox())).add_instruction(
                            Instruction(Gate.CNot(), [3, 4])))
    assert circ == expected
Esempio n. 5
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def test_basis_rotation_instructions_tensor_product():
    circ = (Circuit().h(0).cnot(0, 1).expectation(
        observable=Observable.X() @ Observable.Y() @ Observable.Y(),
        target=[0, 1, 2]))
    expected = [
        Instruction(Gate.H(), 0),
        Instruction(Gate.Z(), 1),
        Instruction(Gate.S(), 1),
        Instruction(Gate.H(), 1),
        Instruction(Gate.Z(), 2),
        Instruction(Gate.S(), 2),
        Instruction(Gate.H(), 2),
    ]
    assert circ.basis_rotation_instructions == expected
Esempio n. 6
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def many_layers(n_qubits: int, n_layers: int) -> Circuit:
    """
    Function to return circuit with many layers.

    :param int n_qubits: number of qubits
    :param int n_layers: number of layers
    :return: Constructed easy circuit
    :rtype: Circuit
    """
    qubits = range(n_qubits)
    circuit = Circuit()  # instantiate circuit object
    for q in range(n_qubits):
        circuit.h(q)
    for layer in range(n_layers):
        if (layer + 1) % 100 != 0:
            for qubit in range(len(qubits)):
                angle = np.random.uniform(0, 2 * math.pi)
                gate = np.random.choice(
                    [Gate.Rx(angle), Gate.Ry(angle), Gate.Rz(angle), Gate.H()], 1, replace=True
                )[0]
                circuit.add_instruction(Instruction(gate, qubit))
        else:
            for q in range(0, n_qubits, 2):
                circuit.cnot(q, q + 1)
            for q in range(1, n_qubits - 1, 2):
                circuit.cnot(q, q + 1)
    return circuit
Esempio n. 7
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def test_subroutine_returns_instruction():
    @circuit.subroutine()
    def foo(target):
        return Instruction(Gate.H(), 0)

    circ = Circuit().add(foo, 0)
    assert circ == Circuit(Instruction(Gate.H(), 0))
Esempio n. 8
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def test_add_circuit_with_target(bell_pair):
    circ = Circuit().add_circuit(bell_pair, target=[10, 11])
    expected = (Circuit().add_instruction(Instruction(
        Gate.H(),
        10)).add_instruction(Instruction(Gate.CNot(),
                                         [10, 11])).add_result_type(
                                             ResultType.Probability([10, 11])))
    assert circ == expected
Esempio n. 9
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def test_subroutine_returns_iterable():
    @circuit.subroutine()
    def foo(target):
        for qubit in range(1):
            yield Instruction(Gate.H(), qubit)

    circ = Circuit().add(foo, 0)
    assert circ == Circuit(Instruction(Gate.H(), 0))
Esempio n. 10
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def test_basis_rotation_instructions_multiple_result_types_same_targets():
    circ = (Circuit().h(0).cnot(0, 1).expectation(
        observable=Observable.H() @ Observable.X(),
        target=[0, 1]).sample(observable=Observable.H() @ Observable.X(),
                              target=[0, 1]).variance(
                                  observable=Observable.H() @ Observable.X(),
                                  target=[0, 1]))
    expected = [Instruction(Gate.Ry(-np.pi / 4), 0), Instruction(Gate.H(), 1)]
    assert circ.basis_rotation_instructions == expected
Esempio n. 11
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def test_add_verbatim_box_no_preceding():
    circ = Circuit().add_verbatim_box(Circuit().h(0)).cnot(2, 3)
    expected = (Circuit().add_instruction(
        Instruction(compiler_directives.StartVerbatimBox())).add_instruction(
            Instruction(Gate.H(), 0)).add_instruction(
                Instruction(
                    compiler_directives.EndVerbatimBox())).add_instruction(
                        Instruction(Gate.CNot(), [2, 3])))
    assert circ == expected
Esempio n. 12
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def test_subroutine_register():
    # register a private method to avoid Sphinx docs picking this up
    @circuit.subroutine(register=True)
    def _foo(target):
        """this docstring will be added to the registered attribute"""
        return Instruction(Gate.H(), target)

    circ = Circuit()._foo(0)
    assert circ == Circuit(Instruction(Gate.H(), 0))
    assert Circuit._foo.__doc__ == _foo.__doc__
Esempio n. 13
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def test_basis_rotation_instructions_identity():
    circ = (Circuit().h(0).cnot(0, 1).cnot(1, 2).cnot(2, 3).cnot(
        3, 4).expectation(observable=Observable.X(), target=[
            0
        ]).expectation(observable=Observable.I(), target=[2]).expectation(
            observable=Observable.I() @ Observable.Y(),
            target=[1, 3]).expectation(observable=Observable.I(), target=[
                0
            ]).expectation(observable=Observable.X() @ Observable.I(),
                           target=[1,
                                   3]).expectation(observable=Observable.Y(),
                                                   target=[2]))
    expected = [
        Instruction(Gate.H(), 0),
        Instruction(Gate.H(), 1),
        Instruction(Gate.Z(), 2),
        Instruction(Gate.S(), 2),
        Instruction(Gate.H(), 2),
        Instruction(Gate.Z(), 3),
        Instruction(Gate.S(), 3),
        Instruction(Gate.H(), 3),
    ]
    assert circ.basis_rotation_instructions == expected
Esempio n. 14
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def test_subroutine_nested():
    @circuit.subroutine()
    def h(target):
        for qubit in target:
            yield Instruction(Gate.H(), qubit)

    @circuit.subroutine()
    def h_nested(target):
        for qubit in target:
            yield h(target)

    circ = Circuit().add(h_nested, [0, 1])
    expected = Circuit(
        [Instruction(Gate.H(), j) for i in range(2) for j in range(2)])
    assert circ == expected
Esempio n. 15
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 def _foo(target):
     """this docstring will be added to the registered attribute"""
     return Instruction(Gate.H(), target)
Esempio n. 16
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def h_instr():
    return Instruction(Gate.H(), 0)
def test_operator_setter(instr):
    instr.operator = Gate.H()
Esempio n. 18
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def test_basis_rotation_instructions_target():
    circ = Circuit().h(0).cnot(0, 1).expectation(observable=Observable.X(),
                                                 target=0)
    expected = [Instruction(Gate.H(), 0)]
    assert circ.basis_rotation_instructions == expected
# distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF
# ANY KIND, either express or implied. See the License for the specific
# language governing permissions and limitations under the License.

import math

import numpy as np
import pytest

from braket.circuits import Gate, Observable
from braket.circuits.observables import observable_from_ir
from braket.circuits.quantum_operator_helpers import get_pauli_eigenvalues

testdata = [
    (Observable.I(), Gate.I(), ["i"], (), np.array([1, 1])),
    (Observable.X(), Gate.X(), ["x"], tuple([Gate.H()]), get_pauli_eigenvalues(1)),
    (
        Observable.Y(),
        Gate.Y(),
        ["y"],
        tuple([Gate.Z(), Gate.S(), Gate.H()]),
        get_pauli_eigenvalues(1),
    ),
    (Observable.Z(), Gate.Z(), ["z"], (), get_pauli_eigenvalues(1)),
    (Observable.H(), Gate.H(), ["h"], tuple([Gate.Ry(-math.pi / 4)]), get_pauli_eigenvalues(1)),
]

invalid_hermitian_matrices = [
    (np.array([[1]])),
    (np.array([1])),
    (np.array([0, 1, 2])),
Esempio n. 20
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def h():
    return Circuit().add_instruction(Instruction(Gate.H(), 0))
Esempio n. 21
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 def h(target):
     for qubit in target:
         yield Instruction(Gate.H(), qubit)
# distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF
# ANY KIND, either express or implied. See the License for the specific
# language governing permissions and limitations under the License.

import math

import numpy as np
import pytest

from braket.circuits import Gate, Observable
from braket.circuits.observables import observable_from_ir
from braket.circuits.quantum_operator_helpers import get_pauli_eigenvalues

testdata = [
    (Observable.I(), Gate.I(), ["i"], (), np.array([1, 1])),
    (Observable.X(), Gate.X(), ["x"], tuple([Gate.H()]),
     get_pauli_eigenvalues(1)),
    (
        Observable.Y(),
        Gate.Y(),
        ["y"],
        tuple([Gate.Z(), Gate.S(), Gate.H()]),
        get_pauli_eigenvalues(1),
    ),
    (Observable.Z(), Gate.Z(), ["z"], (), get_pauli_eigenvalues(1)),
    (Observable.H(), Gate.H(), ["h"], tuple([Gate.Ry(-math.pi / 4)]),
     get_pauli_eigenvalues(1)),
]

invalid_hermitian_matrices = [
    (np.array([[1]])),
Esempio n. 23
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 def foo(target):
     for qubit in range(1):
         yield Instruction(Gate.H(), qubit)
Esempio n. 24
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 def foo(target):
     return Instruction(Gate.H(), 0)
Esempio n. 25
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def h(q):
    return Instruction(Gate.H(), q)
Esempio n. 26
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def test_matrix_equivalence():
    gate1 = Gate.H()
    gate2 = Gate.H()
    gate3 = Gate.CNot()
    assert gate1.matrix_equivalence(gate2)
    assert not gate2.matrix_equivalence(gate3)
Esempio n. 27
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def test_matrix_equivalence_non_gate():
    gate1 = Gate.H()
    assert not gate1.matrix_equivalence(1)
Esempio n. 28
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 (
     Gate.Y(),
     [4],
     OpenQASMSerializationProperties(
         qubit_reference_type=QubitReferenceType.VIRTUAL),
     "y q[4];",
 ),
 (
     Gate.Y(),
     [4],
     OpenQASMSerializationProperties(
         qubit_reference_type=QubitReferenceType.PHYSICAL),
     "y $4;",
 ),
 (
     Gate.H(),
     [4],
     OpenQASMSerializationProperties(
         qubit_reference_type=QubitReferenceType.VIRTUAL),
     "h q[4];",
 ),
 (
     Gate.H(),
     [4],
     OpenQASMSerializationProperties(
         qubit_reference_type=QubitReferenceType.PHYSICAL),
     "h $4;",
 ),
 (
     Gate.Ry(angle=0.17),
     [4],
Esempio n. 29
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def bell_pair(prob):
    return (Circuit().add_instruction(Instruction(
        Gate.H(),
        0)).add_instruction(Instruction(Gate.CNot(),
                                        [0, 1])).add_result_type(prob))
Esempio n. 30
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 def foo(target):
     return Circuit().add(Instruction(Gate.H(), 0))