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414 lines
14 KiB
414 lines
14 KiB
from sympy.core.expr import Expr
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from sympy.core.symbol import Symbol
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from sympy.core.sympify import sympify
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from sympy.matrices.dense import Matrix
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from sympy.printing.pretty.stringpict import prettyForm
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from sympy.core.containers import Tuple
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from sympy.utilities.iterables import is_sequence
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from sympy.physics.quantum.dagger import Dagger
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from sympy.physics.quantum.matrixutils import (
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numpy_ndarray, scipy_sparse_matrix,
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to_sympy, to_numpy, to_scipy_sparse
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)
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__all__ = [
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'QuantumError',
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'QExpr'
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]
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#-----------------------------------------------------------------------------
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# Error handling
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#-----------------------------------------------------------------------------
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class QuantumError(Exception):
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pass
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def _qsympify_sequence(seq):
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"""Convert elements of a sequence to standard form.
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This is like sympify, but it performs special logic for arguments passed
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to QExpr. The following conversions are done:
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* (list, tuple, Tuple) => _qsympify_sequence each element and convert
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sequence to a Tuple.
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* basestring => Symbol
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* Matrix => Matrix
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* other => sympify
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Strings are passed to Symbol, not sympify to make sure that variables like
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'pi' are kept as Symbols, not the SymPy built-in number subclasses.
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Examples
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========
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>>> from sympy.physics.quantum.qexpr import _qsympify_sequence
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>>> _qsympify_sequence((1,2,[3,4,[1,]]))
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(1, 2, (3, 4, (1,)))
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"""
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return tuple(__qsympify_sequence_helper(seq))
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def __qsympify_sequence_helper(seq):
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"""
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Helper function for _qsympify_sequence
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This function does the actual work.
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"""
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#base case. If not a list, do Sympification
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if not is_sequence(seq):
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if isinstance(seq, Matrix):
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return seq
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elif isinstance(seq, str):
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return Symbol(seq)
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else:
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return sympify(seq)
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# base condition, when seq is QExpr and also
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# is iterable.
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if isinstance(seq, QExpr):
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return seq
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#if list, recurse on each item in the list
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result = [__qsympify_sequence_helper(item) for item in seq]
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return Tuple(*result)
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#-----------------------------------------------------------------------------
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# Basic Quantum Expression from which all objects descend
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#-----------------------------------------------------------------------------
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class QExpr(Expr):
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"""A base class for all quantum object like operators and states."""
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# In sympy, slots are for instance attributes that are computed
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# dynamically by the __new__ method. They are not part of args, but they
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# derive from args.
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# The Hilbert space a quantum Object belongs to.
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__slots__ = ('hilbert_space', )
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is_commutative = False
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# The separator used in printing the label.
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_label_separator = ''
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@property
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def free_symbols(self):
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return {self}
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def __new__(cls, *args, **kwargs):
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"""Construct a new quantum object.
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Parameters
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==========
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args : tuple
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The list of numbers or parameters that uniquely specify the
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quantum object. For a state, this will be its symbol or its
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set of quantum numbers.
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Examples
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========
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>>> from sympy.physics.quantum.qexpr import QExpr
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>>> q = QExpr(0)
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>>> q
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0
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>>> q.label
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(0,)
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>>> q.hilbert_space
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H
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>>> q.args
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(0,)
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>>> q.is_commutative
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False
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"""
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# First compute args and call Expr.__new__ to create the instance
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args = cls._eval_args(args, **kwargs)
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if len(args) == 0:
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args = cls._eval_args(tuple(cls.default_args()), **kwargs)
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inst = Expr.__new__(cls, *args)
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# Now set the slots on the instance
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inst.hilbert_space = cls._eval_hilbert_space(args)
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return inst
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@classmethod
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def _new_rawargs(cls, hilbert_space, *args, **old_assumptions):
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"""Create new instance of this class with hilbert_space and args.
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This is used to bypass the more complex logic in the ``__new__``
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method in cases where you already have the exact ``hilbert_space``
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and ``args``. This should be used when you are positive these
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arguments are valid, in their final, proper form and want to optimize
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the creation of the object.
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"""
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obj = Expr.__new__(cls, *args, **old_assumptions)
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obj.hilbert_space = hilbert_space
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return obj
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#-------------------------------------------------------------------------
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# Properties
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#-------------------------------------------------------------------------
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@property
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def label(self):
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"""The label is the unique set of identifiers for the object.
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Usually, this will include all of the information about the state
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*except* the time (in the case of time-dependent objects).
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This must be a tuple, rather than a Tuple.
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"""
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if len(self.args) == 0: # If there is no label specified, return the default
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return self._eval_args(list(self.default_args()))
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else:
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return self.args
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@property
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def is_symbolic(self):
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return True
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@classmethod
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def default_args(self):
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"""If no arguments are specified, then this will return a default set
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of arguments to be run through the constructor.
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NOTE: Any classes that override this MUST return a tuple of arguments.
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Should be overridden by subclasses to specify the default arguments for kets and operators
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"""
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raise NotImplementedError("No default arguments for this class!")
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#-------------------------------------------------------------------------
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# _eval_* methods
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#-------------------------------------------------------------------------
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def _eval_adjoint(self):
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obj = Expr._eval_adjoint(self)
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if obj is None:
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obj = Expr.__new__(Dagger, self)
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if isinstance(obj, QExpr):
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obj.hilbert_space = self.hilbert_space
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return obj
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@classmethod
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def _eval_args(cls, args):
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"""Process the args passed to the __new__ method.
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This simply runs args through _qsympify_sequence.
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"""
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return _qsympify_sequence(args)
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@classmethod
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def _eval_hilbert_space(cls, args):
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"""Compute the Hilbert space instance from the args.
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"""
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from sympy.physics.quantum.hilbert import HilbertSpace
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return HilbertSpace()
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#-------------------------------------------------------------------------
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# Printing
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#-------------------------------------------------------------------------
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# Utilities for printing: these operate on raw SymPy objects
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def _print_sequence(self, seq, sep, printer, *args):
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result = []
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for item in seq:
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result.append(printer._print(item, *args))
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return sep.join(result)
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def _print_sequence_pretty(self, seq, sep, printer, *args):
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pform = printer._print(seq[0], *args)
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for item in seq[1:]:
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pform = prettyForm(*pform.right(sep))
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pform = prettyForm(*pform.right(printer._print(item, *args)))
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return pform
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# Utilities for printing: these operate prettyForm objects
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def _print_subscript_pretty(self, a, b):
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top = prettyForm(*b.left(' '*a.width()))
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bot = prettyForm(*a.right(' '*b.width()))
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return prettyForm(binding=prettyForm.POW, *bot.below(top))
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def _print_superscript_pretty(self, a, b):
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return a**b
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def _print_parens_pretty(self, pform, left='(', right=')'):
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return prettyForm(*pform.parens(left=left, right=right))
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# Printing of labels (i.e. args)
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def _print_label(self, printer, *args):
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"""Prints the label of the QExpr
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This method prints self.label, using self._label_separator to separate
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the elements. This method should not be overridden, instead, override
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_print_contents to change printing behavior.
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"""
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return self._print_sequence(
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self.label, self._label_separator, printer, *args
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)
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def _print_label_repr(self, printer, *args):
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return self._print_sequence(
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self.label, ',', printer, *args
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)
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def _print_label_pretty(self, printer, *args):
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return self._print_sequence_pretty(
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self.label, self._label_separator, printer, *args
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)
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def _print_label_latex(self, printer, *args):
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return self._print_sequence(
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self.label, self._label_separator, printer, *args
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)
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# Printing of contents (default to label)
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def _print_contents(self, printer, *args):
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"""Printer for contents of QExpr
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Handles the printing of any unique identifying contents of a QExpr to
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print as its contents, such as any variables or quantum numbers. The
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default is to print the label, which is almost always the args. This
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should not include printing of any brackets or parentheses.
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"""
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return self._print_label(printer, *args)
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def _print_contents_pretty(self, printer, *args):
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return self._print_label_pretty(printer, *args)
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def _print_contents_latex(self, printer, *args):
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return self._print_label_latex(printer, *args)
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# Main printing methods
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def _sympystr(self, printer, *args):
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"""Default printing behavior of QExpr objects
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Handles the default printing of a QExpr. To add other things to the
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printing of the object, such as an operator name to operators or
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brackets to states, the class should override the _print/_pretty/_latex
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functions directly and make calls to _print_contents where appropriate.
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This allows things like InnerProduct to easily control its printing the
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printing of contents.
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"""
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return self._print_contents(printer, *args)
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def _sympyrepr(self, printer, *args):
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classname = self.__class__.__name__
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label = self._print_label_repr(printer, *args)
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return '%s(%s)' % (classname, label)
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def _pretty(self, printer, *args):
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pform = self._print_contents_pretty(printer, *args)
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return pform
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def _latex(self, printer, *args):
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return self._print_contents_latex(printer, *args)
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#-------------------------------------------------------------------------
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# Represent
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#-------------------------------------------------------------------------
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def _represent_default_basis(self, **options):
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raise NotImplementedError('This object does not have a default basis')
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def _represent(self, *, basis=None, **options):
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"""Represent this object in a given basis.
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This method dispatches to the actual methods that perform the
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representation. Subclases of QExpr should define various methods to
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determine how the object will be represented in various bases. The
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format of these methods is::
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def _represent_BasisName(self, basis, **options):
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Thus to define how a quantum object is represented in the basis of
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the operator Position, you would define::
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def _represent_Position(self, basis, **options):
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Usually, basis object will be instances of Operator subclasses, but
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there is a chance we will relax this in the future to accommodate other
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types of basis sets that are not associated with an operator.
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If the ``format`` option is given it can be ("sympy", "numpy",
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"scipy.sparse"). This will ensure that any matrices that result from
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representing the object are returned in the appropriate matrix format.
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Parameters
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==========
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basis : Operator
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The Operator whose basis functions will be used as the basis for
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representation.
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options : dict
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A dictionary of key/value pairs that give options and hints for
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the representation, such as the number of basis functions to
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be used.
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"""
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if basis is None:
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result = self._represent_default_basis(**options)
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else:
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result = dispatch_method(self, '_represent', basis, **options)
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# If we get a matrix representation, convert it to the right format.
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format = options.get('format', 'sympy')
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result = self._format_represent(result, format)
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return result
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def _format_represent(self, result, format):
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if format == 'sympy' and not isinstance(result, Matrix):
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return to_sympy(result)
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elif format == 'numpy' and not isinstance(result, numpy_ndarray):
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return to_numpy(result)
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elif format == 'scipy.sparse' and \
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not isinstance(result, scipy_sparse_matrix):
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return to_scipy_sparse(result)
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return result
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def split_commutative_parts(e):
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"""Split into commutative and non-commutative parts."""
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c_part, nc_part = e.args_cnc()
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c_part = list(c_part)
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return c_part, nc_part
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def split_qexpr_parts(e):
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"""Split an expression into Expr and noncommutative QExpr parts."""
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expr_part = []
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qexpr_part = []
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for arg in e.args:
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if not isinstance(arg, QExpr):
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expr_part.append(arg)
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else:
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qexpr_part.append(arg)
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return expr_part, qexpr_part
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def dispatch_method(self, basename, arg, **options):
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"""Dispatch a method to the proper handlers."""
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method_name = '%s_%s' % (basename, arg.__class__.__name__)
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if hasattr(self, method_name):
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f = getattr(self, method_name)
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# This can raise and we will allow it to propagate.
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result = f(arg, **options)
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if result is not None:
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return result
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raise NotImplementedError(
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"%s.%s cannot handle: %r" %
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(self.__class__.__name__, basename, arg)
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)
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