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staticstdop.py
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staticstdop.py
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"""
The StaticStandardOp class and supporting functionality.
"""
#***************************************************************************************************
# Copyright 2015, 2019 National Technology & Engineering Solutions of Sandia, LLC (NTESS).
# Under the terms of Contract DE-NA0003525 with NTESS, the U.S. Government retains certain rights
# in this software.
# Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
# in compliance with the License. You may obtain a copy of the License at
# http://www.apache.org/licenses/LICENSE-2.0 or in the LICENSE file in the root pyGSTi directory.
#***************************************************************************************************
import numpy as _np
from pygsti.modelmembers.operations.linearop import LinearOperator as _LinearOperator
from pygsti.modelmembers.errorgencontainer import NoErrorGeneratorInterface as _NoErrorGeneratorInterface
from pygsti.modelmembers import term as _term
from pygsti.evotypes import Evotype as _Evotype
from pygsti.baseobjs import statespace as _statespace
from pygsti.baseobjs.basis import Basis as _Basis
from pygsti.baseobjs.polynomial import Polynomial as _Polynomial
from pygsti.tools import internalgates as _itgs
class StaticStandardOp(_LinearOperator, _NoErrorGeneratorInterface):
"""
An operation that is completely fixed, or "static" (i.e. that posesses no parameters)
that can be constructed from "standard" gate names (as defined in pygsti.tools.internalgates).
Parameters
----------
name : str
Standard gate name
basis : Basis or {'pp','gm','std'}, optional
The basis used to construct the Hilbert-Schmidt space representation
of this state as a super-operator.
evotype : Evotype or str, optional
The evolution type. The special value `"default"` is equivalent
to specifying the value of `pygsti.evotypes.Evotype.default_evotype`.
state_space : StateSpace, optional
The state space for this operation. If `None` a default state space
with the appropriate number of qubits is used.
"""
def __init__(self, name, basis='pp', evotype="default", state_space=None):
self.name = name
#Create default state space if needed
std_unitaries = _itgs.standard_gatename_unitaries()
if name not in std_unitaries:
raise ValueError("'%s' does not name a standard operation" % self.name)
state_space = _statespace.default_space_for_udim(std_unitaries[name].shape[0]) if (state_space is None) \
else _statespace.StateSpace.cast(state_space)
basis = _Basis.cast(basis, state_space.dim) # basis for Hilbert-Schmidt (superop) space
evotype = _Evotype.cast(evotype)
rep = evotype.create_standard_rep(name, basis, state_space)
_LinearOperator.__init__(self, rep, evotype)
def to_dense(self, on_space='minimal'):
"""
Return the dense array used to represent this operation within its evolution type.
Note: for efficiency, this doesn't copy the underlying data, so
the caller should copy this data before modifying it.
Parameters
----------
on_space : {'minimal', 'Hilbert', 'HilbertSchmidt'}
The space that the returned dense operation acts upon. For unitary matrices and bra/ket vectors,
use `'Hilbert'`. For superoperator matrices and super-bra/super-ket vectors use `'HilbertSchmidt'`.
`'minimal'` means that `'Hilbert'` is used if possible given this operator's evolution type, and
otherwise `'HilbertSchmidt'` is used.
Returns
-------
numpy.ndarray
"""
return self._rep.to_dense(on_space) # standard rep needs to implement this
def taylor_order_terms(self, order, max_polynomial_vars=100, return_coeff_polys=False):
"""
Get the `order`-th order Taylor-expansion terms of this operation.
This function either constructs or returns a cached list of the terms at
the given order. Each term is "rank-1", meaning that its action on a
density matrix `rho` can be written:
`rho -> A rho B`
The coefficients of these terms are typically polynomials of the operation's
parameters, where the polynomial's variable indices index the *global*
parameters of the operation's parent (usually a :class:`Model`), not the
operation's local parameter array (i.e. that returned from `to_vector`).
Parameters
----------
order : int
Which order terms (in a Taylor expansion of this :class:`LindbladOp`)
to retrieve.
max_polynomial_vars : int, optional
maximum number of variables the created polynomials can have.
return_coeff_polys : bool
Whether a parallel list of locally-indexed (using variable indices
corresponding to *this* object's parameters rather than its parent's)
polynomial coefficients should be returned as well.
Returns
-------
terms : list
A list of :class:`RankOneTerm` objects.
coefficients : list
Only present when `return_coeff_polys == True`.
A list of *compact* polynomial objects, meaning that each element
is a `(vtape,ctape)` 2-tuple formed by concatenating together the
output of :method:`Polynomial.compact`.
"""
#Same as unitary op -- assume this op acts as a single unitary term -- consolidate in FUTURE?
if order == 0: # only 0-th order term exists
coeff = _Polynomial({(): 1.0}, max_polynomial_vars)
terms = [_term.RankOnePolynomialOpTerm.create_from(coeff, self, self,
self._evotype, self.state_space)]
if return_coeff_polys:
coeffs_as_compact_polys = coeff.compact(complex_coeff_tape=True)
return terms, coeffs_as_compact_polys
else:
return terms
else:
if return_coeff_polys:
vtape = _np.empty(0, _np.int64)
ctape = _np.empty(0, complex)
return [], (vtape, ctape)
else:
return []
@property
def total_term_magnitude(self):
"""
Get the total (sum) of the magnitudes of all this operator's terms.
The magnitude of a term is the absolute value of its coefficient, so
this function returns the number you'd get from summing up the
absolute-coefficients of all the Taylor terms (at all orders!) you
get from expanding this operator in a Taylor series.
Returns
-------
float
"""
return 1.0
@property
def total_term_magnitude_deriv(self):
"""
The derivative of the sum of *all* this operator's terms.
Computes the derivative of the total (sum) of the magnitudes of all this
operator's terms with respect to the operators (local) parameters.
Returns
-------
numpy array
An array of length self.num_params
"""
return _np.empty((0,), 'd')
def to_memoized_dict(self, mmg_memo):
"""Create a serializable dict with references to other objects in the memo.
Parameters
----------
mmg_memo: dict
Memo dict from a ModelMemberGraph, i.e. keys are object ids and values
are ModelMemberGraphNodes (which contain the serialize_id). This is NOT
the same as other memos in ModelMember (e.g. copy, allocate_gpindices, etc.).
Returns
-------
mm_dict: dict
A dict representation of this ModelMember ready for serialization
This must have at least the following fields:
module, class, submembers, params, state_space, evotype
Additional fields may be added by derived classes.
"""
mm_dict = super().to_memoized_dict(mmg_memo)
mm_dict['name'] = self.name
mm_dict['basis'] = self._rep.basis.to_nice_serialization()
return mm_dict
@classmethod
def _from_memoized_dict(cls, mm_dict, serial_memo):
basis = _Basis.from_nice_serialization(mm_dict['basis'])
state_space = _statespace.StateSpace.from_nice_serialization(mm_dict['state_space'])
return cls(mm_dict['name'], basis, mm_dict['evotype'], state_space)
def _is_similar(self, other, rtol, atol):
""" Returns True if `other` model member (which it guaranteed to be the same type as self) has
the same local structure, i.e., not considering parameter values or submembers """
return self.name == other.name # also compare self._rep.basis (?)
def __str__(self):
s = "%s with name %s and evotype %s\n" % (self.__class__.__name__, self.name, self._evotype)
#TODO: move this to __str__ methods of reps??
#if self._evotype in ['statevec', 'densitymx', 'svterm', 'cterm']:
# s += _mt.mx_to_string(self.base, width=4, prec=2)
#elif self._evotype == 'chp':
# s += 'CHP operations: ' + ','.join(self._rep.chp_ops) + '\n'
return s
def _oneline_contents(self):
""" Summarizes the contents of this object in a single line. Does not summarize submembers. """
return "%s gate" % self.name