# This code is part of Qiskit. # # (C) Copyright IBM 2020, 2023. # # 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. """DictStateFn Class""" import itertools from typing import Dict, List, Optional, Set, Union, cast import numpy as np from scipy import sparse 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 from qiskit.opflow.state_fns.state_fn import StateFn from qiskit.opflow.state_fns.vector_state_fn import VectorStateFn from qiskit.quantum_info import Statevector from qiskit.result import Result from qiskit.utils import algorithm_globals from qiskit.utils.deprecation import deprecate_func class DictStateFn(StateFn): """Deprecated: A class for state functions and measurements which are defined by a lookup table, stored in a dict. """ primitive: Dict[str, complex] # TODO allow normalization somehow? @deprecate_func( since="0.24.0", additional_msg="For code migration guidelines, visit https://qisk.it/opflow_migration.", ) def __init__( self, primitive: Union[str, dict, Result] = None, coeff: Union[complex, ParameterExpression] = 1.0, is_measurement: bool = False, from_operator: bool = False, ) -> None: """ Args: primitive: The dict, single bitstring (if defining a basis sate), or Qiskit Result, which defines the behavior of the underlying function. coeff: A coefficient by which to multiply the state function. is_measurement: Whether the StateFn is a measurement operator. from_operator: if True the StateFn is derived from OperatorStateFn. (Default: False) Raises: TypeError: invalid parameters. """ # If the initial density is a string, treat this as a density dict # with only a single basis state. if isinstance(primitive, str): primitive = {primitive: 1} # NOTE: # 1) This is not the same as passing in the counts dict directly, as this will # convert the shot numbers to # probabilities, whereas passing in the counts dict will not. # 2) This will extract counts for both shot and statevector simulations. # To use the statevector, # simply pass in the statevector. # 3) This will only extract the first result. if isinstance(primitive, Result): counts = primitive.get_counts() # NOTE: Need to square root to take correct Pauli measurements! primitive = { bstr: (shots / sum(counts.values())) ** 0.5 for (bstr, shots) in counts.items() } if not isinstance(primitive, dict): raise TypeError( "DictStateFn can only be instantiated with dict, " "string, or Qiskit Result, not {}".format(type(primitive)) ) super().__init__(primitive, coeff=coeff, is_measurement=is_measurement) self.from_operator = from_operator def primitive_strings(self) -> Set[str]: return {"Dict"} @property def num_qubits(self) -> int: return len(next(iter(self.primitive))) @property def settings(self) -> Dict: """Return settings.""" data = super().settings data["from_operator"] = self.from_operator return data def add(self, other: OperatorBase) -> OperatorBase: if not self.num_qubits == other.num_qubits: raise ValueError( "Sum over statefns with different numbers of qubits, {} and {}, is not well " "defined".format(self.num_qubits, other.num_qubits) ) # Right now doesn't make sense to add a StateFn to a Measurement if isinstance(other, DictStateFn) and self.is_measurement == other.is_measurement: # TODO add compatibility with vector and Operator? if self.primitive == other.primitive: return DictStateFn( self.primitive, coeff=self.coeff + other.coeff, is_measurement=self.is_measurement, ) else: new_dict = { b: (v * self.coeff) + (other.primitive.get(b, 0) * other.coeff) for (b, v) in self.primitive.items() } new_dict.update( { b: v * other.coeff for (b, v) in other.primitive.items() if b not in self.primitive } ) return DictStateFn(new_dict, is_measurement=self._is_measurement) # pylint: disable=cyclic-import from ..list_ops.summed_op import SummedOp return SummedOp([self, other]) def adjoint(self) -> "DictStateFn": return DictStateFn( {b: np.conj(v) for (b, v) in self.primitive.items()}, coeff=self.coeff.conjugate(), is_measurement=(not self.is_measurement), ) def permute(self, permutation: List[int]) -> "DictStateFn": new_num_qubits = max(permutation) + 1 if self.num_qubits != len(permutation): raise OpflowError("New index must be defined for each qubit of the operator.") # helper function to permute the key def perm(key): list_key = ["0"] * new_num_qubits for i, k in enumerate(permutation): list_key[k] = key[i] return "".join(list_key) new_dict = {perm(key): value for key, value in self.primitive.items()} return DictStateFn(new_dict, coeff=self.coeff, is_measurement=self.is_measurement) def _expand_dim(self, num_qubits: int) -> "DictStateFn": pad = "0" * num_qubits new_dict = {key + pad: value for key, value in self.primitive.items()} return DictStateFn(new_dict, coeff=self.coeff, is_measurement=self.is_measurement) def tensor(self, other: OperatorBase) -> OperatorBase: # Both dicts if isinstance(other, DictStateFn): new_dict = { k1 + k2: v1 * v2 for ( ( k1, v1, ), (k2, v2), ) in itertools.product(self.primitive.items(), other.primitive.items()) } return StateFn( new_dict, coeff=self.coeff * other.coeff, is_measurement=self.is_measurement ) # pylint: disable=cyclic-import from ..list_ops.tensored_op import TensoredOp return TensoredOp([self, other]) def to_density_matrix(self, massive: bool = False) -> np.ndarray: OperatorBase._check_massive("to_density_matrix", True, self.num_qubits, massive) states = int(2**self.num_qubits) return self.to_matrix(massive=massive) * np.eye(states) * self.coeff def to_matrix(self, massive: bool = False) -> np.ndarray: OperatorBase._check_massive("to_matrix", False, self.num_qubits, massive) states = int(2**self.num_qubits) probs = np.zeros(states) + 0.0j for k, v in self.primitive.items(): probs[int(k, 2)] = v vec = probs * self.coeff # Reshape for measurements so np.dot still works for composition. return vec if not self.is_measurement else vec.reshape(1, -1) def to_spmatrix(self) -> sparse.spmatrix: """Same as to_matrix, but returns csr sparse matrix. Returns: CSR sparse matrix representation of the State function. Raises: ValueError: invalid parameters. """ indices = [int(v, 2) for v in self.primitive.keys()] vals = np.array(list(self.primitive.values())) * self.coeff spvec = sparse.csr_matrix( (vals, (np.zeros(len(indices), dtype=int), indices)), shape=(1, 2**self.num_qubits) ) return spvec if not self.is_measurement else spvec.transpose() def to_spmatrix_op(self) -> OperatorBase: """Convert this state function to a ``SparseVectorStateFn``.""" from .sparse_vector_state_fn import SparseVectorStateFn return SparseVectorStateFn(self.to_spmatrix(), self.coeff, self.is_measurement) def to_circuit_op(self) -> OperatorBase: """Convert this state function to a ``CircuitStateFn``.""" from .circuit_state_fn import CircuitStateFn csfn = CircuitStateFn.from_dict(self.primitive) * self.coeff return csfn.adjoint() if self.is_measurement else csfn def __str__(self) -> str: prim_str = str(self.primitive) if self.coeff == 1.0: return "{}({})".format( "DictStateFn" if not self.is_measurement else "DictMeasurement", prim_str ) else: return "{}({}) * {}".format( "DictStateFn" if not self.is_measurement else "DictMeasurement", prim_str, self.coeff, ) # pylint: disable=too-many-return-statements def eval( self, front: Optional[ Union[str, Dict[str, complex], np.ndarray, OperatorBase, Statevector] ] = None, ) -> Union[OperatorBase, complex]: if front is None: sparse_vector_state_fn = self.to_spmatrix_op().eval() return sparse_vector_state_fn if not self.is_measurement and isinstance(front, OperatorBase): raise ValueError( "Cannot compute overlap with StateFn or Operator if not Measurement. Try taking " "sf.adjoint() first to convert to measurement." ) if isinstance(front, ListOp) and front.distributive: return front.combo_fn( [self.eval(front.coeff * front_elem) for front_elem in front.oplist] ) # For now, always do this. If it's not performant, we can be more granular. if not isinstance(front, OperatorBase): front = StateFn(front) # pylint: disable=cyclic-import from ..operator_globals import EVAL_SIG_DIGITS # If the primitive is a lookup of bitstrings, # we define all missing strings to have a function value of # zero. if isinstance(front, DictStateFn): # If self is come from operator, it should be expanded as # = . front_coeff = ( front.coeff * front.coeff.conjugate() if self.from_operator else front.coeff ) return np.round( cast( float, sum(v * front.primitive.get(b, 0) for (b, v) in self.primitive.items()) * self.coeff * front_coeff, ), decimals=EVAL_SIG_DIGITS, ) # All remaining possibilities only apply when self.is_measurement is True if isinstance(front, VectorStateFn): # TODO does it need to be this way for measurement? # return sum([v * front.primitive.data[int(b, 2)] * # np.conj(front.primitive.data[int(b, 2)]) return np.round( cast( float, sum(v * front.primitive.data[int(b, 2)] for (b, v) in self.primitive.items()) * self.coeff, ), decimals=EVAL_SIG_DIGITS, ) from .circuit_state_fn import CircuitStateFn if isinstance(front, CircuitStateFn): # Don't reimplement logic from CircuitStateFn self_adjoint = cast(DictStateFn, self.adjoint()) return np.conj(front.adjoint().eval(self_adjoint.primitive)) * self.coeff from .operator_state_fn import OperatorStateFn if isinstance(front, OperatorStateFn): return cast(Union[OperatorBase, complex], front.adjoint().eval(self.adjoint())) # All other OperatorBases go here self_adjoint = cast(DictStateFn, self.adjoint()) adjointed_eval = cast(OperatorBase, front.adjoint().eval(self_adjoint.primitive)) return adjointed_eval.adjoint() * self.coeff def sample( self, shots: int = 1024, massive: bool = False, reverse_endianness: bool = False ) -> Dict[str, float]: probs = np.square(np.abs(np.array(list(self.primitive.values())))) unique, counts = np.unique( algorithm_globals.random.choice( list(self.primitive.keys()), size=shots, p=(probs / sum(probs)) ), return_counts=True, ) counts = dict(zip(unique, counts)) if reverse_endianness: scaled_dict = {bstr[::-1]: (prob / shots) for (bstr, prob) in counts.items()} else: scaled_dict = {bstr: (prob / shots) for (bstr, prob) in counts.items()} return dict(sorted(scaled_dict.items(), key=lambda x: x[1], reverse=True))