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346 lines
10 KiB
346 lines
10 KiB
5 months ago
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"""Grover's algorithm and helper functions.
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Todo:
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* W gate construction (or perhaps -W gate based on Mermin's book)
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* Generalize the algorithm for an unknown function that returns 1 on multiple
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qubit states, not just one.
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* Implement _represent_ZGate in OracleGate
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"""
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from sympy.core.numbers import pi
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from sympy.core.sympify import sympify
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from sympy.core.basic import Atom
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from sympy.functions.elementary.integers import floor
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from sympy.functions.elementary.miscellaneous import sqrt
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from sympy.matrices.dense import eye
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from sympy.core.numbers import NegativeOne
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from sympy.physics.quantum.qapply import qapply
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from sympy.physics.quantum.qexpr import QuantumError
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from sympy.physics.quantum.hilbert import ComplexSpace
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from sympy.physics.quantum.operator import UnitaryOperator
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from sympy.physics.quantum.gate import Gate
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from sympy.physics.quantum.qubit import IntQubit
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__all__ = [
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'OracleGate',
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'WGate',
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'superposition_basis',
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'grover_iteration',
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'apply_grover'
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]
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def superposition_basis(nqubits):
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"""Creates an equal superposition of the computational basis.
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Parameters
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==========
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nqubits : int
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The number of qubits.
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Returns
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=======
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state : Qubit
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An equal superposition of the computational basis with nqubits.
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Examples
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========
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Create an equal superposition of 2 qubits::
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>>> from sympy.physics.quantum.grover import superposition_basis
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>>> superposition_basis(2)
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|0>/2 + |1>/2 + |2>/2 + |3>/2
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"""
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amp = 1/sqrt(2**nqubits)
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return sum([amp*IntQubit(n, nqubits=nqubits) for n in range(2**nqubits)])
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class OracleGateFunction(Atom):
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"""Wrapper for python functions used in `OracleGate`s"""
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def __new__(cls, function):
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if not callable(function):
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raise TypeError('Callable expected, got: %r' % function)
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obj = Atom.__new__(cls)
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obj.function = function
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return obj
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def _hashable_content(self):
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return type(self), self.function
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def __call__(self, *args):
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return self.function(*args)
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class OracleGate(Gate):
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"""A black box gate.
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The gate marks the desired qubits of an unknown function by flipping
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the sign of the qubits. The unknown function returns true when it
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finds its desired qubits and false otherwise.
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Parameters
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==========
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qubits : int
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Number of qubits.
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oracle : callable
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A callable function that returns a boolean on a computational basis.
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Examples
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========
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Apply an Oracle gate that flips the sign of ``|2>`` on different qubits::
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>>> from sympy.physics.quantum.qubit import IntQubit
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>>> from sympy.physics.quantum.qapply import qapply
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>>> from sympy.physics.quantum.grover import OracleGate
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>>> f = lambda qubits: qubits == IntQubit(2)
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>>> v = OracleGate(2, f)
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>>> qapply(v*IntQubit(2))
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-|2>
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>>> qapply(v*IntQubit(3))
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|3>
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"""
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gate_name = 'V'
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gate_name_latex = 'V'
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#-------------------------------------------------------------------------
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# Initialization/creation
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#-------------------------------------------------------------------------
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@classmethod
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def _eval_args(cls, args):
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if len(args) != 2:
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raise QuantumError(
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'Insufficient/excessive arguments to Oracle. Please ' +
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'supply the number of qubits and an unknown function.'
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)
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sub_args = (args[0],)
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sub_args = UnitaryOperator._eval_args(sub_args)
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if not sub_args[0].is_Integer:
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raise TypeError('Integer expected, got: %r' % sub_args[0])
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function = args[1]
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if not isinstance(function, OracleGateFunction):
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function = OracleGateFunction(function)
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return (sub_args[0], function)
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@classmethod
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def _eval_hilbert_space(cls, args):
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"""This returns the smallest possible Hilbert space."""
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return ComplexSpace(2)**args[0]
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#-------------------------------------------------------------------------
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# Properties
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#-------------------------------------------------------------------------
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@property
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def search_function(self):
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"""The unknown function that helps find the sought after qubits."""
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return self.label[1]
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@property
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def targets(self):
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"""A tuple of target qubits."""
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return sympify(tuple(range(self.args[0])))
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#-------------------------------------------------------------------------
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# Apply
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#-------------------------------------------------------------------------
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def _apply_operator_Qubit(self, qubits, **options):
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"""Apply this operator to a Qubit subclass.
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Parameters
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==========
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qubits : Qubit
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The qubit subclass to apply this operator to.
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Returns
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=======
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state : Expr
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The resulting quantum state.
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"""
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if qubits.nqubits != self.nqubits:
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raise QuantumError(
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'OracleGate operates on %r qubits, got: %r'
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% (self.nqubits, qubits.nqubits)
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)
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# If function returns 1 on qubits
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# return the negative of the qubits (flip the sign)
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if self.search_function(qubits):
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return -qubits
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else:
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return qubits
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#-------------------------------------------------------------------------
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# Represent
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#-------------------------------------------------------------------------
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def _represent_ZGate(self, basis, **options):
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"""
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Represent the OracleGate in the computational basis.
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"""
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nbasis = 2**self.nqubits # compute it only once
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matrixOracle = eye(nbasis)
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# Flip the sign given the output of the oracle function
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for i in range(nbasis):
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if self.search_function(IntQubit(i, nqubits=self.nqubits)):
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matrixOracle[i, i] = NegativeOne()
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return matrixOracle
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class WGate(Gate):
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"""General n qubit W Gate in Grover's algorithm.
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The gate performs the operation ``2|phi><phi| - 1`` on some qubits.
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``|phi> = (tensor product of n Hadamards)*(|0> with n qubits)``
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Parameters
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==========
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nqubits : int
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The number of qubits to operate on
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"""
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gate_name = 'W'
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gate_name_latex = 'W'
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@classmethod
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def _eval_args(cls, args):
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if len(args) != 1:
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raise QuantumError(
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'Insufficient/excessive arguments to W gate. Please ' +
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'supply the number of qubits to operate on.'
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)
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args = UnitaryOperator._eval_args(args)
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if not args[0].is_Integer:
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raise TypeError('Integer expected, got: %r' % args[0])
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return args
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#-------------------------------------------------------------------------
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# Properties
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#-------------------------------------------------------------------------
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@property
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def targets(self):
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return sympify(tuple(reversed(range(self.args[0]))))
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#-------------------------------------------------------------------------
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# Apply
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#-------------------------------------------------------------------------
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def _apply_operator_Qubit(self, qubits, **options):
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"""
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qubits: a set of qubits (Qubit)
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Returns: quantum object (quantum expression - QExpr)
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"""
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if qubits.nqubits != self.nqubits:
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raise QuantumError(
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'WGate operates on %r qubits, got: %r'
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% (self.nqubits, qubits.nqubits)
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)
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# See 'Quantum Computer Science' by David Mermin p.92 -> W|a> result
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# Return (2/(sqrt(2^n)))|phi> - |a> where |a> is the current basis
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# state and phi is the superposition of basis states (see function
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# create_computational_basis above)
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basis_states = superposition_basis(self.nqubits)
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change_to_basis = (2/sqrt(2**self.nqubits))*basis_states
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return change_to_basis - qubits
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def grover_iteration(qstate, oracle):
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"""Applies one application of the Oracle and W Gate, WV.
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Parameters
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==========
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qstate : Qubit
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A superposition of qubits.
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oracle : OracleGate
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The black box operator that flips the sign of the desired basis qubits.
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Returns
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=======
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Qubit : The qubits after applying the Oracle and W gate.
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Examples
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========
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Perform one iteration of grover's algorithm to see a phase change::
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>>> from sympy.physics.quantum.qapply import qapply
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>>> from sympy.physics.quantum.qubit import IntQubit
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>>> from sympy.physics.quantum.grover import OracleGate
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>>> from sympy.physics.quantum.grover import superposition_basis
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>>> from sympy.physics.quantum.grover import grover_iteration
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>>> numqubits = 2
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>>> basis_states = superposition_basis(numqubits)
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>>> f = lambda qubits: qubits == IntQubit(2)
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>>> v = OracleGate(numqubits, f)
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>>> qapply(grover_iteration(basis_states, v))
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|2>
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"""
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wgate = WGate(oracle.nqubits)
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return wgate*oracle*qstate
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def apply_grover(oracle, nqubits, iterations=None):
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"""Applies grover's algorithm.
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Parameters
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==========
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oracle : callable
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The unknown callable function that returns true when applied to the
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desired qubits and false otherwise.
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Returns
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=======
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state : Expr
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The resulting state after Grover's algorithm has been iterated.
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Examples
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========
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Apply grover's algorithm to an even superposition of 2 qubits::
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>>> from sympy.physics.quantum.qapply import qapply
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>>> from sympy.physics.quantum.qubit import IntQubit
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>>> from sympy.physics.quantum.grover import apply_grover
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>>> f = lambda qubits: qubits == IntQubit(2)
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>>> qapply(apply_grover(f, 2))
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|2>
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"""
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if nqubits <= 0:
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raise QuantumError(
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'Grover\'s algorithm needs nqubits > 0, received %r qubits'
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% nqubits
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)
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if iterations is None:
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iterations = floor(sqrt(2**nqubits)*(pi/4))
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v = OracleGate(nqubits, oracle)
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iterated = superposition_basis(nqubits)
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for iter in range(iterations):
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iterated = grover_iteration(iterated, v)
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iterated = qapply(iterated)
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return iterated
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