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      # -*- coding: utf-8 -*-

      """Mimic C structs with lots of extra functionality.

      $Id: ipstruct.py 1950 2006-11-28 19:15:35Z vivainio $"""

      #*****************************************************************************

      #       Copyright (C) 2001-2004 Fernando Perez <fperez@colorado.edu>

      #

      #  Distributed under the terms of the BSD License.  The full license is in

      #  the file COPYING, distributed as part of this software.

      #*****************************************************************************

      from IPython import Release

      __author__  = '%s <%s>' % Release.authors['Fernando']

      __license__ = Release.license

      __all__ = ['Struct']

      import types

      import pprint

      from IPython.genutils import list2dict2

      class Struct:

          """Class to mimic C structs but also provide convenient dictionary-like

          functionality.

          Instances can be initialized with a dictionary, a list of key=value pairs

          or both. If both are present, the dictionary must come first.

          Because Python classes provide direct assignment to their members, it's

          easy to overwrite normal methods (S.copy = 1 would destroy access to

          S.copy()). For this reason, all builtin method names are protected and

          can't be assigned to. An attempt to do s.copy=1 or s['copy']=1 will raise

          a KeyError exception. If you really want to, you can bypass this

          protection by directly assigning to __dict__: s.__dict__['copy']=1 will

          still work. Doing this will break functionality, though. As in most of

          Python, namespace protection is weakly enforced, so feel free to shoot

          yourself if you really want to.

          Note that this class uses more memory and is *much* slower than a regular

          dictionary, so be careful in situations where memory or performance are

          critical. But for day to day use it should behave fine. It is particularly

          convenient for storing configuration data in programs.

          +,+=,- and -= are implemented. +/+= do merges (non-destructive updates),

          -/-= remove keys from the original. See the method descripitions.

          This class allows a quick access syntax: both s.key and s['key'] are

          valid.  This syntax has a limitation: each 'key' has to be explicitly

          accessed by its original name. The normal s.key syntax doesn't provide

          access to the keys via variables whose values evaluate to the desired

          keys. An example should clarify this:

          Define a dictionary and initialize both with dict and k=v pairs:

          >>> d={'a':1,'b':2}

          >>> s=Struct(d,hi=10,ho=20)

          The return of __repr__ can be used to create a new instance:

          >>> s

          Struct({'ho': 20, 'b': 2, 'hi': 10, 'a': 1})

          __str__ (called by print) shows it's not quite a regular dictionary:

          >>> print s

          Struct {a: 1, b: 2, hi: 10, ho: 20}

          Access by explicitly named key with dot notation:

          >>> s.a

          1

          Or like a dictionary:

          >>> s['a']

          1

          If you want a variable to hold the key value, only dictionary access works:

          >>> key='hi'

          >>> s.key

          Traceback (most recent call last):

            File "<stdin>", line 1, in ?

          AttributeError: Struct instance has no attribute 'key'

          >>> s[key]

          10

          Another limitation of the s.key syntax (and Struct(key=val)

          initialization): keys can't be numbers. But numeric keys can be used and

          accessed using the dictionary syntax. Again, an example:

          This doesn't work:

          >>> s=Struct(4='hi')

          SyntaxError: keyword can't be an expression

          But this does:

          >>> s=Struct()

          >>> s[4]='hi'

          >>> s

          Struct({4: 'hi'})

          >>> s[4]

          'hi'

          """

          # Attributes to which __setitem__ and __setattr__ will block access.

          # Note: much of this will be moot in Python 2.2 and will be done in a much

          # cleaner way.

          __protected = ('copy dict dictcopy get has_attr has_key items keys '

                         'merge popitem setdefault update values '

                         '__make_dict __dict_invert ').split()

          def __init__(self,dict=None,**kw):

              """Initialize with a dictionary, another Struct, or by giving

              explicitly the list of attributes.

              Both can be used, but the dictionary must come first:

              Struct(dict), Struct(k1=v1,k2=v2) or Struct(dict,k1=v1,k2=v2).

              """

              self.__dict__['__allownew'] = True

              if dict is None:

                  dict = {}

              if isinstance(dict,Struct):

                  dict = dict.dict()

              elif dict and  type(dict) is not types.DictType:

                  raise TypeError,\

                        'Initialize with a dictionary or key=val pairs.'

              dict.update(kw)

              # do the updating by hand to guarantee that we go through the

              # safety-checked __setitem__

              for k,v in dict.items():

                  self[k] = v

          def __setitem__(self,key,value):

              """Used when struct[key] = val calls are made."""

              if key in Struct.__protected:

                  raise KeyError,'Key '+`key`+' is a protected key of class Struct.'

              if not self['__allownew'] and key not in self.__dict__:

                  raise KeyError(

                  "Can't create unknown attribute %s - Check for typos, or use allow_new_attr to create new attributes!" %

                  key)

              self.__dict__[key] = value

          def __setattr__(self, key, value):

              """Used when struct.key = val calls are made."""

              self.__setitem__(key,value)

          def __str__(self):

              """Gets called by print."""

              return 'Struct('+ pprint.pformat(self.__dict__)+')'

          def __repr__(self):

              """Gets called by repr.

              A Struct can be recreated with S_new=eval(repr(S_old))."""

              return self.__str__()

          def __getitem__(self,key):

              """Allows struct[key] access."""

              return self.__dict__[key]

          def __contains__(self,key):

              """Allows use of the 'in' operator."""

              return self.__dict__.has_key(key)

          def __iadd__(self,other):

              """S += S2 is a shorthand for S.merge(S2)."""

              self.merge(other)

              return self

          def __add__(self,other):

              """S + S2 -> New Struct made form S and S.merge(S2)"""

              Sout = self.copy()

              Sout.merge(other)

              return Sout

          def __sub__(self,other):

              """Return S1-S2, where all keys in S2 have been deleted (if present)

              from S1."""

              Sout = self.copy()

              Sout -= other

              return Sout

          def __isub__(self,other):

              """Do in place S = S - S2, meaning all keys in S2 have been deleted

              (if present) from S1."""

              for k in other.keys():

                  if self.has_key(k):

                      del self.__dict__[k]

          def __make_dict(self,__loc_data__,**kw):

              "Helper function for update and merge. Return a dict from data."

              if __loc_data__ == None:

                  dict = {}

              elif type(__loc_data__) is types.DictType:

                  dict = __loc_data__

              elif isinstance(__loc_data__,Struct):

                  dict = __loc_data__.__dict__

              else:

                  raise TypeError, 'Update with a dict, a Struct or key=val pairs.'

              if kw:

                  dict.update(kw)

              return dict

          def __dict_invert(self,dict):

              """Helper function for merge. Takes a dictionary whose values are

              lists and returns a dict. with the elements of each list as keys and

              the original keys as values."""

              outdict = {}

              for k,lst in dict.items():

                  if type(lst) is types.StringType:

                      lst = lst.split()

                  for entry in lst:

                      outdict[entry] = k

              return outdict

          def clear(self):

              """Clear all attributes."""

              self.__dict__.clear()

          def copy(self):

              """Return a (shallow) copy of a Struct."""

              return Struct(self.__dict__.copy())

          def dict(self):

              """Return the Struct's dictionary."""

              return self.__dict__

          def dictcopy(self):

              """Return a (shallow) copy of the Struct's dictionary."""

              return self.__dict__.copy()

          def popitem(self):

              """S.popitem() -> (k, v), remove and return some (key, value) pair as

              a 2-tuple; but raise KeyError if S is empty."""

              return self.__dict__.popitem()

          def update(self,__loc_data__=None,**kw):

              """Update (merge) with data from another Struct or from a dictionary.

              Optionally, one or more key=value pairs can be given at the end for

              direct update."""

              # The funny name __loc_data__ is to prevent a common variable name which

              # could be a fieled of a Struct to collide with this parameter. The problem

              # would arise if the function is called with a keyword with this same name

              # that a user means to add as a Struct field.

              newdict = Struct.__make_dict(self,__loc_data__,**kw)

              for k,v in newdict.items():

                  self[k] = v

          def merge(self,__loc_data__=None,__conflict_solve=None,**kw):

              """S.merge(data,conflict,k=v1,k=v2,...) -> merge data and k=v into S.

              This is similar to update(), but much more flexible.  First, a dict is

              made from data+key=value pairs. When merging this dict with the Struct

              S, the optional dictionary 'conflict' is used to decide what to do.

              If conflict is not given, the default behavior is to preserve any keys

              with their current value (the opposite of the update method's

              behavior).

              conflict is a dictionary of binary functions which will be used to

              solve key conflicts. It must have the following structure:

                conflict == { fn1 : [Skey1,Skey2,...], fn2 : [Skey3], etc }

              Values must be lists or whitespace separated strings which are

              automatically converted to lists of strings by calling string.split().

              Each key of conflict is a function which defines a policy for

              resolving conflicts when merging with the input data. Each fn must be

              a binary function which returns the desired outcome for a key

              conflict. These functions will be called as fn(old,new).

              An example is probably in order. Suppose you are merging the struct S

              with a dict D and the following conflict policy dict:

                  S.merge(D,{fn1:['a','b',4], fn2:'key_c key_d'})

              If the key 'a' is found in both S and D, the merge method will call:

                  S['a'] = fn1(S['a'],D['a'])

              As a convenience, merge() provides five (the most commonly needed)

              pre-defined policies: preserve, update, add, add_flip and add_s. The

              easiest explanation is their implementation:

                preserve = lambda old,new: old

                update   = lambda old,new: new

                add      = lambda old,new: old + new

                add_flip = lambda old,new: new + old  # note change of order!

                add_s    = lambda old,new: old + ' ' + new  # only works for strings!

              You can use those four words (as strings) as keys in conflict instead

              of defining them as functions, and the merge method will substitute

              the appropriate functions for you. That is, the call

                S.merge(D,{'preserve':'a b c','add':[4,5,'d'],my_function:[6]})

              will automatically substitute the functions preserve and add for the

              names 'preserve' and 'add' before making any function calls.

              For more complicated conflict resolution policies, you still need to

              construct your own functions. """

              data_dict = Struct.__make_dict(self,__loc_data__,**kw)

              # policies for conflict resolution: two argument functions which return

              # the value that will go in the new struct

              preserve = lambda old,new: old

              update   = lambda old,new: new

              add      = lambda old,new: old + new

              add_flip = lambda old,new: new + old  # note change of order!

              add_s    = lambda old,new: old + ' ' + new

              # default policy is to keep current keys when there's a conflict

              conflict_solve = list2dict2(self.keys(),default = preserve)

              # the conflict_solve dictionary is given by the user 'inverted': we

              # need a name-function mapping, it comes as a function -> names

              # dict. Make a local copy (b/c we'll make changes), replace user

              # strings for the three builtin policies and invert it.

              if __conflict_solve:

                  inv_conflict_solve_user = __conflict_solve.copy()

                  for name, func in [('preserve',preserve), ('update',update),

                                     ('add',add), ('add_flip',add_flip), ('add_s',add_s)]:

                      if name in inv_conflict_solve_user.keys():

                          inv_conflict_solve_user[func] = inv_conflict_solve_user[name]

                          del inv_conflict_solve_user[name]

                  conflict_solve.update(Struct.__dict_invert(self,inv_conflict_solve_user))

              #print 'merge. conflict_solve: '; pprint(conflict_solve) # dbg

              #print '*'*50,'in merger. conflict_solver:';  pprint(conflict_solve)

              for key in data_dict:

                  if key not in self:

                      self[key] = data_dict[key]

                  else:

                      self[key] = conflict_solve[key](self[key],data_dict[key])

          def has_key(self,key):

              """Like has_key() dictionary method."""

              return self.__dict__.has_key(key)

          def hasattr(self,key):

              """hasattr function available as a method.

              Implemented like has_key, to make sure that all available keys in the

              internal dictionary of the Struct appear also as attributes (even

              numeric keys)."""

              return self.__dict__.has_key(key)

          def items(self):

              """Return the items in the Struct's dictionary, in the same format

              as a call to {}.items()."""

              return self.__dict__.items()

          def keys(self):

              """Return the keys in the Struct's dictionary, in the same format

              as a call to {}.keys()."""

              return self.__dict__.keys()

          def values(self,keys=None):

              """Return the values in the Struct's dictionary, in the same format

              as a call to {}.values().

              Can be called with an optional argument keys, which must be a list or

              tuple of keys. In this case it returns only the values corresponding

              to those keys (allowing a form of 'slicing' for Structs)."""

              if not keys:

                  return self.__dict__.values()

              else:

                  ret=[]

                  for k in keys:

                      ret.append(self[k])

                  return ret

          def get(self,attr,val=None):

              """S.get(k[,d]) -> S[k] if S.has_key(k), else d.  d defaults to None."""

              try:

                  return self[attr]

              except KeyError:

                  return val

          def setdefault(self,attr,val=None):

              """S.setdefault(k[,d]) -> S.get(k,d), also set S[k]=d if not S.has_key(k)"""

              if not self.has_key(attr):

                  self[attr] = val

              return self.get(attr,val)

          def allow_new_attr(self, allow = True):

              """ Set whether new attributes can be created inside struct

              This can be used to catch typos by verifying that the attribute user tries to 

              change already exists in this Struct.

              """

              self['__allownew'] = allow

      # end class Struct

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				# -- coding: utf-8 --
				"""Mimic C structs with lots of extra functionality.

				$Id: ipstruct.py 1950 2006-11-28 19:15:35Z vivainio $"""

				#*****************************************************************************
				# Copyright (C) 2001-2004 Fernando Perez <fperez@colorado.edu>
				#
				# Distributed under the terms of the BSD License. The full license is in
				# the file COPYING, distributed as part of this software.
				#*****************************************************************************

				from IPython import Release
				__author__ = '%s <%s>' % Release.authors['Fernando']
				__license__ = Release.license

				__all__ = ['Struct']

				import types
				import pprint

				from IPython.genutils import list2dict2

				class Struct:
				"""Class to mimic C structs but also provide convenient dictionary-like
				functionality.

				Instances can be initialized with a dictionary, a list of key=value pairs
				or both. If both are present, the dictionary must come first.

				Because Python classes provide direct assignment to their members, it's
				easy to overwrite normal methods (S.copy = 1 would destroy access to
				S.copy()). For this reason, all builtin method names are protected and
				can't be assigned to. An attempt to do s.copy=1 or s['copy']=1 will raise
				a KeyError exception. If you really want to, you can bypass this
				protection by directly assigning to __dict__: s.__dict__['copy']=1 will
				still work. Doing this will break functionality, though. As in most of
				Python, namespace protection is weakly enforced, so feel free to shoot
				yourself if you really want to.

				Note that this class uses more memory and is much slower than a regular
				dictionary, so be careful in situations where memory or performance are
				critical. But for day to day use it should behave fine. It is particularly
				convenient for storing configuration data in programs.

				+,+=,- and -= are implemented. +/+= do merges (non-destructive updates),
				-/-= remove keys from the original. See the method descripitions.

				This class allows a quick access syntax: both s.key and s['key'] are
				valid. This syntax has a limitation: each 'key' has to be explicitly
				accessed by its original name. The normal s.key syntax doesn't provide
				access to the keys via variables whose values evaluate to the desired
				keys. An example should clarify this:

				Define a dictionary and initialize both with dict and k=v pairs:
				>>> d={'a':1,'b':2}
				>>> s=Struct(d,hi=10,ho=20)
				The return of __repr__ can be used to create a new instance:
				>>> s
				Struct({'ho': 20, 'b': 2, 'hi': 10, 'a': 1})
				__str__ (called by print) shows it's not quite a regular dictionary:
				>>> print s
				Struct {a: 1, b: 2, hi: 10, ho: 20}
				Access by explicitly named key with dot notation:
				>>> s.a
				1
				Or like a dictionary:
				>>> s['a']
				1
				If you want a variable to hold the key value, only dictionary access works:
				>>> key='hi'
				>>> s.key
				Traceback (most recent call last):
				File "<stdin>", line 1, in ?
				AttributeError: Struct instance has no attribute 'key'
				>>> s[key]
				10

				Another limitation of the s.key syntax (and Struct(key=val)
				initialization): keys can't be numbers. But numeric keys can be used and
				accessed using the dictionary syntax. Again, an example:

				This doesn't work:
				>>> s=Struct(4='hi')
				SyntaxError: keyword can't be an expression
				But this does:
				>>> s=Struct()
				>>> s[4]='hi'
				>>> s
				Struct({4: 'hi'})
				>>> s[4]
				'hi'
				"""

				# Attributes to which __setitem__ and __setattr__ will block access.
				# Note: much of this will be moot in Python 2.2 and will be done in a much
				# cleaner way.
				__protected = ('copy dict dictcopy get has_attr has_key items keys '
				'merge popitem setdefault update values '
				'__make_dict __dict_invert ').split()

				def __init__(self,dict=None,**kw):
				"""Initialize with a dictionary, another Struct, or by giving
				explicitly the list of attributes.

				Both can be used, but the dictionary must come first:
				Struct(dict), Struct(k1=v1,k2=v2) or Struct(dict,k1=v1,k2=v2).
				"""
				self.__dict__['__allownew'] = True
				if dict is None:
				dict = {}
				if isinstance(dict,Struct):
				dict = dict.dict()
				elif dict and type(dict) is not types.DictType:
				raise TypeError,\
				'Initialize with a dictionary or key=val pairs.'
				dict.update(kw)
				# do the updating by hand to guarantee that we go through the
				# safety-checked __setitem__
				for k,v in dict.items():
				self[k] = v


				def __setitem__(self,key,value):
				"""Used when struct[key] = val calls are made."""
				if key in Struct.__protected:
				raise KeyError,'Key '+`key`+' is a protected key of class Struct.'
				if not self['__allownew'] and key not in self.__dict__:
				raise KeyError(
				"Can't create unknown attribute %s - Check for typos, or use allow_new_attr to create new attributes!" %
				key)

				self.__dict__[key] = value

				def __setattr__(self, key, value):
				"""Used when struct.key = val calls are made."""
				self.__setitem__(key,value)

				def __str__(self):
				"""Gets called by print."""

				return 'Struct('+ pprint.pformat(self.__dict__)+')'

				def __repr__(self):
				"""Gets called by repr.

				A Struct can be recreated with S_new=eval(repr(S_old))."""
				return self.__str__()

				def __getitem__(self,key):
				"""Allows struct[key] access."""
				return self.__dict__[key]

				def __contains__(self,key):
				"""Allows use of the 'in' operator."""
				return self.__dict__.has_key(key)

				def __iadd__(self,other):
				"""S += S2 is a shorthand for S.merge(S2)."""
				self.merge(other)
				return self

				def __add__(self,other):
				"""S + S2 -> New Struct made form S and S.merge(S2)"""
				Sout = self.copy()
				Sout.merge(other)
				return Sout

				def __sub__(self,other):
				"""Return S1-S2, where all keys in S2 have been deleted (if present)
				from S1."""
				Sout = self.copy()
				Sout -= other
				return Sout

				def __isub__(self,other):
				"""Do in place S = S - S2, meaning all keys in S2 have been deleted
				(if present) from S1."""

				for k in other.keys():
				if self.has_key(k):
				del self.__dict__[k]

				def __make_dict(self,__loc_data__,**kw):
				"Helper function for update and merge. Return a dict from data."

				if __loc_data__ == None:
				dict = {}
				elif type(__loc_data__) is types.DictType:
				dict = __loc_data__
				elif isinstance(__loc_data__,Struct):
				dict = __loc_data__.__dict__
				else:
				raise TypeError, 'Update with a dict, a Struct or key=val pairs.'
				if kw:
				dict.update(kw)
				return dict

				def __dict_invert(self,dict):
				"""Helper function for merge. Takes a dictionary whose values are
				lists and returns a dict. with the elements of each list as keys and
				the original keys as values."""

				outdict = {}
				for k,lst in dict.items():
				if type(lst) is types.StringType:
				lst = lst.split()
				for entry in lst:
				outdict[entry] = k
				return outdict

				def clear(self):
				"""Clear all attributes."""
				self.__dict__.clear()

				def copy(self):
				"""Return a (shallow) copy of a Struct."""
				return Struct(self.__dict__.copy())

				def dict(self):
				"""Return the Struct's dictionary."""
				return self.__dict__

				def dictcopy(self):
				"""Return a (shallow) copy of the Struct's dictionary."""
				return self.__dict__.copy()

				def popitem(self):
				"""S.popitem() -> (k, v), remove and return some (key, value) pair as
				a 2-tuple; but raise KeyError if S is empty."""
				return self.__dict__.popitem()

				def update(self,__loc_data__=None,**kw):
				"""Update (merge) with data from another Struct or from a dictionary.
				Optionally, one or more key=value pairs can be given at the end for
				direct update."""

				# The funny name __loc_data__ is to prevent a common variable name which
				# could be a fieled of a Struct to collide with this parameter. The problem
				# would arise if the function is called with a keyword with this same name
				# that a user means to add as a Struct field.
				newdict = Struct.__make_dict(self,__loc_data__,**kw)
				for k,v in newdict.items():
				self[k] = v

				def merge(self,__loc_data__=None,__conflict_solve=None,**kw):
				"""S.merge(data,conflict,k=v1,k=v2,...) -> merge data and k=v into S.

				This is similar to update(), but much more flexible. First, a dict is
				made from data+key=value pairs. When merging this dict with the Struct
				S, the optional dictionary 'conflict' is used to decide what to do.

				If conflict is not given, the default behavior is to preserve any keys
				with their current value (the opposite of the update method's
				behavior).

				conflict is a dictionary of binary functions which will be used to
				solve key conflicts. It must have the following structure:

				conflict == { fn1 : [Skey1,Skey2,...], fn2 : [Skey3], etc }

				Values must be lists or whitespace separated strings which are
				automatically converted to lists of strings by calling string.split().

				Each key of conflict is a function which defines a policy for
				resolving conflicts when merging with the input data. Each fn must be
				a binary function which returns the desired outcome for a key
				conflict. These functions will be called as fn(old,new).

				An example is probably in order. Suppose you are merging the struct S
				with a dict D and the following conflict policy dict:

				S.merge(D,{fn1:['a','b',4], fn2:'key_c key_d'})

				If the key 'a' is found in both S and D, the merge method will call:

				S['a'] = fn1(S['a'],D['a'])

				As a convenience, merge() provides five (the most commonly needed)
				pre-defined policies: preserve, update, add, add_flip and add_s. The
				easiest explanation is their implementation:

				preserve = lambda old,new: old
				update = lambda old,new: new
				add = lambda old,new: old + new
				add_flip = lambda old,new: new + old # note change of order!
				add_s = lambda old,new: old + ' ' + new # only works for strings!

				You can use those four words (as strings) as keys in conflict instead
				of defining them as functions, and the merge method will substitute
				the appropriate functions for you. That is, the call

				S.merge(D,{'preserve':'a b c','add':[4,5,'d'],my_function:[6]})

				will automatically substitute the functions preserve and add for the
				names 'preserve' and 'add' before making any function calls.

				For more complicated conflict resolution policies, you still need to
				construct your own functions. """

				data_dict = Struct.__make_dict(self,__loc_data__,**kw)

				# policies for conflict resolution: two argument functions which return
				# the value that will go in the new struct
				preserve = lambda old,new: old
				update = lambda old,new: new
				add = lambda old,new: old + new
				add_flip = lambda old,new: new + old # note change of order!
				add_s = lambda old,new: old + ' ' + new

				# default policy is to keep current keys when there's a conflict
				conflict_solve = list2dict2(self.keys(),default = preserve)

				# the conflict_solve dictionary is given by the user 'inverted': we
				# need a name-function mapping, it comes as a function -> names
				# dict. Make a local copy (b/c we'll make changes), replace user
				# strings for the three builtin policies and invert it.
				if __conflict_solve:
				inv_conflict_solve_user = __conflict_solve.copy()
				for name, func in [('preserve',preserve), ('update',update),
				('add',add), ('add_flip',add_flip), ('add_s',add_s)]:
				if name in inv_conflict_solve_user.keys():
				inv_conflict_solve_user[func] = inv_conflict_solve_user[name]
				del inv_conflict_solve_user[name]
				conflict_solve.update(Struct.__dict_invert(self,inv_conflict_solve_user))
				#print 'merge. conflict_solve: '; pprint(conflict_solve) # dbg
				#print ''50,'in merger. conflict_solver:'; pprint(conflict_solve)
				for key in data_dict:
				if key not in self:
				self[key] = data_dict[key]
				else:
				self[key] = conflict_solve[key](self[key],data_dict[key])

				def has_key(self,key):
				"""Like has_key() dictionary method."""
				return self.__dict__.has_key(key)

				def hasattr(self,key):
				"""hasattr function available as a method.

				Implemented like has_key, to make sure that all available keys in the
				internal dictionary of the Struct appear also as attributes (even
				numeric keys)."""
				return self.__dict__.has_key(key)

				def items(self):
				"""Return the items in the Struct's dictionary, in the same format
				as a call to {}.items()."""
				return self.__dict__.items()

				def keys(self):
				"""Return the keys in the Struct's dictionary, in the same format
				as a call to {}.keys()."""
				return self.__dict__.keys()

				def values(self,keys=None):
				"""Return the values in the Struct's dictionary, in the same format
				as a call to {}.values().

				Can be called with an optional argument keys, which must be a list or
				tuple of keys. In this case it returns only the values corresponding
				to those keys (allowing a form of 'slicing' for Structs)."""
				if not keys:
				return self.__dict__.values()
				else:
				ret=[]
				for k in keys:
				ret.append(self[k])
				return ret

				def get(self,attr,val=None):
				"""S.get(k[,d]) -> S[k] if S.has_key(k), else d. d defaults to None."""
				try:
				return self[attr]
				except KeyError:
				return val

				def setdefault(self,attr,val=None):
				"""S.setdefault(k[,d]) -> S.get(k,d), also set S[k]=d if not S.has_key(k)"""
				if not self.has_key(attr):
				self[attr] = val
				return self.get(attr,val)

				def allow_new_attr(self, allow = True):
				""" Set whether new attributes can be created inside struct

				This can be used to catch typos by verifying that the attribute user tries to
				change already exists in this Struct.
				"""
				self['__allownew'] = allow


				# end class Struct