# Quellcode für qiskit.opflow.list_ops.summed_op

```
# This code is part of Qiskit.
#
# (C) Copyright IBM 2020.
#
# This code is licensed under the Apache License, Version 2.0. You may
# obtain a copy of this license in the LICENSE.txt file in the root directory
# of this source tree or at http://www.apache.org/licenses/LICENSE-2.0.
#
# Any modifications or derivative works of this code must retain this
# copyright notice, and modified files need to carry a notice indicating
# that they have been altered from the originals.
""" SummedOp Class """
from typing import List, Union, cast, Dict
import numpy as np
from qiskit import QuantumCircuit
from qiskit.circuit import ParameterExpression
from qiskit.opflow.exceptions import OpflowError
from qiskit.opflow.list_ops.list_op import ListOp
from qiskit.opflow.operator_base import OperatorBase
[Doku]class SummedOp(ListOp):
"""A class for lazily representing sums of Operators. Often Operators cannot be
efficiently added to one another, but may be manipulated further so that they can be
later. This class holds logic to indicate that the Operators in ``oplist`` are meant to
be added together, and therefore if they reach a point in which they can be, such as after
evaluation or conversion to matrices, they can be reduced by addition."""
def __init__(
self,
oplist: List[OperatorBase],
coeff: Union[complex, ParameterExpression] = 1.0,
abelian: bool = False,
) -> None:
"""
Args:
oplist: The Operators being summed.
coeff: A coefficient multiplying the operator
abelian: Indicates whether the Operators in ``oplist`` are known to mutually commute.
"""
super().__init__(oplist, combo_fn=lambda x: np.sum(x, axis=0), coeff=coeff, abelian=abelian)
@property
def num_qubits(self) -> int:
return self.oplist[0].num_qubits
@property
def distributive(self) -> bool:
return True
@property
def settings(self) -> Dict:
"""Return settings."""
return {"oplist": self._oplist, "coeff": self._coeff, "abelian": self._abelian}
[Doku] def add(self, other: OperatorBase) -> "SummedOp":
"""Return Operator addition of ``self`` and ``other``, overloaded by ``+``.
Note:
This appends ``other`` to ``self.oplist`` without checking ``other`` is already
included or not. If you want to simplify them, please use :meth:`simplify`.
Args:
other: An ``OperatorBase`` with the same number of qubits as self, and in the same
'Operator', 'State function', or 'Measurement' category as self (i.e. the same type
of underlying function).
Returns:
A ``SummedOp`` equivalent to the sum of self and other.
"""
self_new_ops = (
self.oplist if self.coeff == 1 else [op.mul(self.coeff) for op in self.oplist]
)
if isinstance(other, SummedOp):
other_new_ops = (
other.oplist if other.coeff == 1 else [op.mul(other.coeff) for op in other.oplist]
)
else:
other_new_ops = [other]
return SummedOp(self_new_ops + other_new_ops)
[Doku] def collapse_summands(self) -> "SummedOp":
"""Return Operator by simplifying duplicate operators.
E.g., ``SummedOp([2 * X ^ Y, X ^ Y]).collapse_summands() -> SummedOp([3 * X ^ Y])``.
Returns:
A simplified ``SummedOp`` equivalent to self.
"""
# pylint: disable=cyclic-import
from ..primitive_ops.primitive_op import PrimitiveOp
oplist = [] # type: List[OperatorBase]
coeffs = [] # type: List[Union[int, float, complex, ParameterExpression]]
for op in self.oplist:
if isinstance(op, PrimitiveOp):
new_op = PrimitiveOp(op.primitive)
new_coeff = op.coeff * self.coeff
if new_op in oplist:
index = oplist.index(new_op)
coeffs[index] += new_coeff
else:
oplist.append(new_op)
coeffs.append(new_coeff)
else:
if op in oplist:
index = oplist.index(op)
coeffs[index] += self.coeff
else:
oplist.append(op)
coeffs.append(self.coeff)
return SummedOp([op * coeff for op, coeff in zip(oplist, coeffs)])
# TODO be smarter about the fact that any two ops in oplist could be evaluated for sum.
[Doku] def reduce(self) -> OperatorBase:
"""Try collapsing list or trees of sums.
Tries to sum up duplicate operators and reduces the operators
in the sum.
Returns:
A collapsed version of self, if possible.
"""
if len(self.oplist) == 0:
return SummedOp([], coeff=self.coeff, abelian=self.abelian)
# reduce constituents
reduced_ops = sum(op.reduce() for op in self.oplist) * self.coeff
# group duplicate operators
if isinstance(reduced_ops, SummedOp):
reduced_ops = reduced_ops.collapse_summands()
# pylint: disable=cyclic-import
from ..primitive_ops.pauli_sum_op import PauliSumOp
if isinstance(reduced_ops, PauliSumOp):
reduced_ops = reduced_ops.reduce()
if isinstance(reduced_ops, SummedOp) and len(reduced_ops.oplist) == 1:
return reduced_ops.oplist[0]
else:
return cast(OperatorBase, reduced_ops)
[Doku] def to_circuit(self) -> QuantumCircuit:
"""Returns the quantum circuit, representing the SummedOp. In the first step,
the SummedOp is converted to MatrixOp. This is straightforward for most operators,
but it is not supported for operators containing parameterized PrimitiveOps (in that case,
OpflowError is raised). In the next step, the MatrixOp representation of SummedOp is
converted to circuit. In most cases, if the summands themselves are unitary operators,
the SummedOp itself is non-unitary and can not be converted to circuit. In that case,
ExtensionError is raised in the underlying modules.
Returns:
The circuit representation of the summed operator.
Raises:
OpflowError: if SummedOp can not be converted to MatrixOp (e.g. SummedOp is composed of
parameterized PrimitiveOps).
"""
# pylint: disable=cyclic-import
from ..primitive_ops.matrix_op import MatrixOp
matrix_op = self.to_matrix_op()
if isinstance(matrix_op, MatrixOp):
return matrix_op.to_circuit()
raise OpflowError(
"The SummedOp can not be converted to circuit, because to_matrix_op did "
"not return a MatrixOp."
)
[Doku] def to_matrix_op(self, massive: bool = False) -> "SummedOp":
"""Returns an equivalent Operator composed of only NumPy-based primitives, such as
``MatrixOp`` and ``VectorStateFn``."""
accum = self.oplist[0].to_matrix_op(massive=massive)
for i in range(1, len(self.oplist)):
accum += self.oplist[i].to_matrix_op(massive=massive)
return cast(SummedOp, accum * self.coeff)
[Doku] def to_pauli_op(self, massive: bool = False) -> "SummedOp":
# pylint: disable=cyclic-import
from ..state_fns.state_fn import StateFn
pauli_sum = SummedOp(
[
op.to_pauli_op(massive=massive) # type: ignore
if not isinstance(op, StateFn)
else op
for op in self.oplist
],
coeff=self.coeff,
abelian=self.abelian,
).reduce()
if isinstance(pauli_sum, SummedOp):
return pauli_sum
return pauli_sum.to_pauli_op() # type: ignore
[Doku] def equals(self, other: OperatorBase) -> bool:
"""Check if other is equal to self.
Note:
This is not a mathematical check for equality.
If ``self`` and ``other`` implement the same operation but differ
in the representation (e.g. different type of summands)
``equals`` will evaluate to ``False``.
Args:
other: The other operator to check for equality.
Returns:
True, if other and self are equal, otherwise False.
Examples:
>>> from qiskit.opflow import X, Z
>>> 2 * X == X + X
True
>>> X + Z == Z + X
True
"""
self_reduced, other_reduced = self.reduce(), other.reduce()
if not isinstance(other_reduced, type(self_reduced)):
return False
# check if reduced op is still a SummedOp
if not isinstance(self_reduced, SummedOp):
return self_reduced == other_reduced
self_reduced = cast(SummedOp, self_reduced)
other_reduced = cast(SummedOp, other_reduced)
if len(self_reduced.oplist) != len(other_reduced.oplist):
return False
# absorb coeffs into the operators
if self_reduced.coeff != 1:
self_reduced = SummedOp([op * self_reduced.coeff for op in self_reduced.oplist])
if other_reduced.coeff != 1:
other_reduced = SummedOp([op * other_reduced.coeff for op in other_reduced.oplist])
# compare independent of order
return all(any(i == j for j in other_reduced) for i in self_reduced)
```