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# -*- test-case-name: twisted.test.test_jelly -*-
# Copyright (c) 2001-2010 Twisted Matrix Laboratories.
# See LICENSE for details.
"""
S-expression-based persistence of python objects.
It does something very much like L{Pickle<pickle>}; however, pickle's main goal
seems to be efficiency (both in space and time); jelly's main goals are
security, human readability, and portability to other environments.
This is how Jelly converts various objects to s-expressions.
Boolean::
True --> ['boolean', 'true']
Integer::
1 --> 1
List::
[1, 2] --> ['list', 1, 2]
String::
\"hello\" --> \"hello\"
Float::
2.3 --> 2.3
Dictionary::
{'a': 1, 'b': 'c'} --> ['dictionary', ['b', 'c'], ['a', 1]]
Module::
UserString --> ['module', 'UserString']
Class::
UserString.UserString --> ['class', ['module', 'UserString'], 'UserString']
Function::
string.join --> ['function', 'join', ['module', 'string']]
Instance: s is an instance of UserString.UserString, with a __dict__
{'data': 'hello'}::
[\"UserString.UserString\", ['dictionary', ['data', 'hello']]]
Class Method: UserString.UserString.center::
['method', 'center', ['None'], ['class', ['module', 'UserString'],
'UserString']]
Instance Method: s.center, where s is an instance of UserString.UserString::
['method', 'center', ['instance', ['reference', 1, ['class',
['module', 'UserString'], 'UserString']], ['dictionary', ['data', 'd']]],
['dereference', 1]]
The C{set} builtin and the C{sets.Set} class are serialized to the same
thing, and unserialized to C{set} if available, else to C{sets.Set}. It means
that there's a possibility of type switching in the serialization process. The
solution is to always use C{set} if possible, and only use C{sets.Set} under
Python 2.3; this can be accomplished by using L{twisted.python.compat.set}.
The same rule applies for C{frozenset} and C{sets.ImmutableSet}.
@author: Glyph Lefkowitz
"""
# System Imports
import pickle
import types
import warnings
from types import StringType
from types import UnicodeType
from types import IntType
from types import TupleType
from types import ListType
from types import LongType
from types import FloatType
from types import FunctionType
from types import MethodType
from types import ModuleType
from types import DictionaryType
from types import InstanceType
from types import NoneType
from types import ClassType
import copy
import datetime
from types import BooleanType
try:
import decimal
except ImportError:
decimal = None
try:
_set = set
except NameError:
_set = None
try:
# Filter out deprecation warning for Python >= 2.6
warnings.filterwarnings("ignore", category=DeprecationWarning,
message="the sets module is deprecated", append=True)
import sets as _sets
finally:
warnings.filters.pop()
from new import instance
from new import instancemethod
from zope.interface import implements
# Twisted Imports
from twisted.python.reflect import namedObject, qual
from twisted.persisted.crefutil import NotKnown, _Tuple, _InstanceMethod
from twisted.persisted.crefutil import _DictKeyAndValue, _Dereference
from twisted.persisted.crefutil import _Container
from twisted.python.compat import reduce
from twisted.spread.interfaces import IJellyable, IUnjellyable
DictTypes = (DictionaryType,)
None_atom = "None" # N
# code
class_atom = "class" # c
module_atom = "module" # m
function_atom = "function" # f
# references
dereference_atom = 'dereference' # D
persistent_atom = 'persistent' # p
reference_atom = 'reference' # r
# mutable collections
dictionary_atom = "dictionary" # d
list_atom = 'list' # l
set_atom = 'set'
# immutable collections
# (assignment to __dict__ and __class__ still might go away!)
tuple_atom = "tuple" # t
instance_atom = 'instance' # i
frozenset_atom = 'frozenset'
# errors
unpersistable_atom = "unpersistable"# u
unjellyableRegistry = {}
unjellyableFactoryRegistry = {}
_NO_STATE = object()
def _newInstance(cls, state=_NO_STATE):
"""
Make a new instance of a class without calling its __init__ method.
Supports both new- and old-style classes.
@param state: A C{dict} used to update C{inst.__dict__} or C{_NO_STATE}
to skip this part of initialization.
@return: A new instance of C{cls}.
"""
if not isinstance(cls, types.ClassType):
# new-style
inst = cls.__new__(cls)
if state is not _NO_STATE:
inst.__dict__.update(state) # Copy 'instance' behaviour
else:
if state is not _NO_STATE:
inst = instance(cls, state)
else:
inst = instance(cls)
return inst
def _maybeClass(classnamep):
try:
object
except NameError:
isObject = 0
else:
isObject = isinstance(classnamep, type)
if isinstance(classnamep, ClassType) or isObject:
return qual(classnamep)
return classnamep
def setUnjellyableForClass(classname, unjellyable):
"""
Set which local class will represent a remote type.
If you have written a Copyable class that you expect your client to be
receiving, write a local "copy" class to represent it, then call::
jellier.setUnjellyableForClass('module.package.Class', MyCopier).
Call this at the module level immediately after its class
definition. MyCopier should be a subclass of RemoteCopy.
The classname may be a special tag returned by
'Copyable.getTypeToCopyFor' rather than an actual classname.
This call is also for cached classes, since there will be no
overlap. The rules are the same.
"""
global unjellyableRegistry
classname = _maybeClass(classname)
unjellyableRegistry[classname] = unjellyable
globalSecurity.allowTypes(classname)
def setUnjellyableFactoryForClass(classname, copyFactory):
"""
Set the factory to construct a remote instance of a type::
jellier.setUnjellyableFactoryForClass('module.package.Class', MyFactory)
Call this at the module level immediately after its class definition.
C{copyFactory} should return an instance or subclass of
L{RemoteCopy<pb.RemoteCopy>}.
Similar to L{setUnjellyableForClass} except it uses a factory instead
of creating an instance.
"""
global unjellyableFactoryRegistry
classname = _maybeClass(classname)
unjellyableFactoryRegistry[classname] = copyFactory
globalSecurity.allowTypes(classname)
def setUnjellyableForClassTree(module, baseClass, prefix=None):
"""
Set all classes in a module derived from C{baseClass} as copiers for
a corresponding remote class.
When you have a heirarchy of Copyable (or Cacheable) classes on one
side, and a mirror structure of Copied (or RemoteCache) classes on the
other, use this to setUnjellyableForClass all your Copieds for the
Copyables.
Each copyTag (the \"classname\" argument to getTypeToCopyFor, and
what the Copyable's getTypeToCopyFor returns) is formed from
adding a prefix to the Copied's class name. The prefix defaults
to module.__name__. If you wish the copy tag to consist of solely
the classname, pass the empty string \'\'.
@param module: a module object from which to pull the Copied classes.
(passing sys.modules[__name__] might be useful)
@param baseClass: the base class from which all your Copied classes derive.
@param prefix: the string prefixed to classnames to form the
unjellyableRegistry.
"""
if prefix is None:
prefix = module.__name__
if prefix:
prefix = "%s." % prefix
for i in dir(module):
i_ = getattr(module, i)
if type(i_) == types.ClassType:
if issubclass(i_, baseClass):
setUnjellyableForClass('%s%s' % (prefix, i), i_)
def getInstanceState(inst, jellier):
"""
Utility method to default to 'normal' state rules in serialization.
"""
if hasattr(inst, "__getstate__"):
state = inst.__getstate__()
else:
state = inst.__dict__
sxp = jellier.prepare(inst)
sxp.extend([qual(inst.__class__), jellier.jelly(state)])
return jellier.preserve(inst, sxp)
def setInstanceState(inst, unjellier, jellyList):
"""
Utility method to default to 'normal' state rules in unserialization.
"""
state = unjellier.unjelly(jellyList[1])
if hasattr(inst, "__setstate__"):
inst.__setstate__(state)
else:
inst.__dict__ = state
return inst
class Unpersistable:
"""
This is an instance of a class that comes back when something couldn't be
unpersisted.
"""
def __init__(self, reason):
"""
Initialize an unpersistable object with a descriptive C{reason} string.
"""
self.reason = reason
def __repr__(self):
return "Unpersistable(%s)" % repr(self.reason)
class Jellyable:
"""
Inherit from me to Jelly yourself directly with the `getStateFor'
convenience method.
"""
implements(IJellyable)
def getStateFor(self, jellier):
return self.__dict__
def jellyFor(self, jellier):
"""
@see: L{twisted.spread.interfaces.IJellyable.jellyFor}
"""
sxp = jellier.prepare(self)
sxp.extend([
qual(self.__class__),
jellier.jelly(self.getStateFor(jellier))])
return jellier.preserve(self, sxp)
class Unjellyable:
"""
Inherit from me to Unjelly yourself directly with the
C{setStateFor} convenience method.
"""
implements(IUnjellyable)
def setStateFor(self, unjellier, state):
self.__dict__ = state
def unjellyFor(self, unjellier, jellyList):
"""
Perform the inverse operation of L{Jellyable.jellyFor}.
@see: L{twisted.spread.interfaces.IUnjellyable.unjellyFor}
"""
state = unjellier.unjelly(jellyList[1])
self.setStateFor(unjellier, state)
return self
class _Jellier:
"""
(Internal) This class manages state for a call to jelly()
"""
def __init__(self, taster, persistentStore, invoker):
"""
Initialize.
"""
self.taster = taster
# `preserved' is a dict of previously seen instances.
self.preserved = {}
# `cooked' is a dict of previously backreferenced instances to their
# `ref' lists.
self.cooked = {}
self.cooker = {}
self._ref_id = 1
self.persistentStore = persistentStore
self.invoker = invoker
def _cook(self, object):
"""
(internal) Backreference an object.
Notes on this method for the hapless future maintainer: If I've already
gone through the prepare/preserve cycle on the specified object (it is
being referenced after the serializer is \"done with\" it, e.g. this
reference is NOT circular), the copy-in-place of aList is relevant,
since the list being modified is the actual, pre-existing jelly
expression that was returned for that object. If not, it's technically
superfluous, since the value in self.preserved didn't need to be set,
but the invariant that self.preserved[id(object)] is a list is
convenient because that means we don't have to test and create it or
not create it here, creating fewer code-paths. that's why
self.preserved is always set to a list.
Sorry that this code is so hard to follow, but Python objects are
tricky to persist correctly. -glyph
"""
aList = self.preserved[id(object)]
newList = copy.copy(aList)
# make a new reference ID
refid = self._ref_id
self._ref_id = self._ref_id + 1
# replace the old list in-place, so that we don't have to track the
# previous reference to it.
aList[:] = [reference_atom, refid, newList]
self.cooked[id(object)] = [dereference_atom, refid]
return aList
def prepare(self, object):
"""
(internal) Create a list for persisting an object to. This will allow
backreferences to be made internal to the object. (circular
references).
The reason this needs to happen is that we don't generate an ID for
every object, so we won't necessarily know which ID the object will
have in the future. When it is 'cooked' ( see _cook ), it will be
assigned an ID, and the temporary placeholder list created here will be
modified in-place to create an expression that gives this object an ID:
[reference id# [object-jelly]].
"""
# create a placeholder list to be preserved
self.preserved[id(object)] = []
# keep a reference to this object around, so it doesn't disappear!
# (This isn't always necessary, but for cases where the objects are
# dynamically generated by __getstate__ or getStateToCopyFor calls, it
# is; id() will return the same value for a different object if it gets
# garbage collected. This may be optimized later.)
self.cooker[id(object)] = object
return []
def preserve(self, object, sexp):
"""
(internal) Mark an object's persistent list for later referral.
"""
# if I've been cooked in the meanwhile,
if id(object) in self.cooked:
# replace the placeholder empty list with the real one
self.preserved[id(object)][2] = sexp
# but give this one back.
sexp = self.preserved[id(object)]
else:
self.preserved[id(object)] = sexp
return sexp
constantTypes = {types.StringType : 1, types.IntType : 1,
types.FloatType : 1, types.LongType : 1}
def _checkMutable(self,obj):
objId = id(obj)
if objId in self.cooked:
return self.cooked[objId]
if objId in self.preserved:
self._cook(obj)
return self.cooked[objId]
def jelly(self, obj):
if isinstance(obj, Jellyable):
preRef = self._checkMutable(obj)
if preRef:
return preRef
return obj.jellyFor(self)
objType = type(obj)
if self.taster.isTypeAllowed(qual(objType)):
# "Immutable" Types
if ((objType is StringType) or
(objType is IntType) or
(objType is LongType) or
(objType is FloatType)):
return obj
elif objType is MethodType:
return ["method",
obj.im_func.__name__,
self.jelly(obj.im_self),
self.jelly(obj.im_class)]
elif UnicodeType and objType is UnicodeType:
return ['unicode', obj.encode('UTF-8')]
elif objType is NoneType:
return ['None']
elif objType is FunctionType:
name = obj.__name__
return ['function', str(pickle.whichmodule(obj, obj.__name__))
+ '.' +
name]
elif objType is ModuleType:
return ['module', obj.__name__]
elif objType is BooleanType:
return ['boolean', obj and 'true' or 'false']
elif objType is datetime.datetime:
if obj.tzinfo:
raise NotImplementedError(
"Currently can't jelly datetime objects with tzinfo")
return ['datetime', '%s %s %s %s %s %s %s' % (
obj.year, obj.month, obj.day, obj.hour,
obj.minute, obj.second, obj.microsecond)]
elif objType is datetime.time:
if obj.tzinfo:
raise NotImplementedError(
"Currently can't jelly datetime objects with tzinfo")
return ['time', '%s %s %s %s' % (obj.hour, obj.minute,
obj.second, obj.microsecond)]
elif objType is datetime.date:
return ['date', '%s %s %s' % (obj.year, obj.month, obj.day)]
elif objType is datetime.timedelta:
return ['timedelta', '%s %s %s' % (obj.days, obj.seconds,
obj.microseconds)]
elif objType is ClassType or issubclass(objType, type):
return ['class', qual(obj)]
elif decimal is not None and objType is decimal.Decimal:
return self.jelly_decimal(obj)
else:
preRef = self._checkMutable(obj)
if preRef:
return preRef
# "Mutable" Types
sxp = self.prepare(obj)
if objType is ListType:
sxp.extend(self._jellyIterable(list_atom, obj))
elif objType is TupleType:
sxp.extend(self._jellyIterable(tuple_atom, obj))
elif objType in DictTypes:
sxp.append(dictionary_atom)
for key, val in obj.items():
sxp.append([self.jelly(key), self.jelly(val)])
elif (_set is not None and objType is set or
objType is _sets.Set):
sxp.extend(self._jellyIterable(set_atom, obj))
elif (_set is not None and objType is frozenset or
objType is _sets.ImmutableSet):
sxp.extend(self._jellyIterable(frozenset_atom, obj))
else:
className = qual(obj.__class__)
persistent = None
if self.persistentStore:
persistent = self.persistentStore(obj, self)
if persistent is not None:
sxp.append(persistent_atom)
sxp.append(persistent)
elif self.taster.isClassAllowed(obj.__class__):
sxp.append(className)
if hasattr(obj, "__getstate__"):
state = obj.__getstate__()
else:
state = obj.__dict__
sxp.append(self.jelly(state))
else:
self.unpersistable(
"instance of class %s deemed insecure" %
qual(obj.__class__), sxp)
return self.preserve(obj, sxp)
else:
if objType is InstanceType:
raise InsecureJelly("Class not allowed for instance: %s %s" %
(obj.__class__, obj))
raise InsecureJelly("Type not allowed for object: %s %s" %
(objType, obj))
def _jellyIterable(self, atom, obj):
"""
Jelly an iterable object.
@param atom: the identifier atom of the object.
@type atom: C{str}
@param obj: any iterable object.
@type obj: C{iterable}
@return: a generator of jellied data.
@rtype: C{generator}
"""
yield atom
for item in obj:
yield self.jelly(item)
def jelly_decimal(self, d):
"""
Jelly a decimal object.
@param d: a decimal object to serialize.
@type d: C{decimal.Decimal}
@return: jelly for the decimal object.
@rtype: C{list}
"""
sign, guts, exponent = d.as_tuple()
value = reduce(lambda left, right: left * 10 + right, guts)
if sign:
value = -value
return ['decimal', value, exponent]
def unpersistable(self, reason, sxp=None):
"""
(internal) Returns an sexp: (unpersistable "reason"). Utility method
for making note that a particular object could not be serialized.
"""
if sxp is None:
sxp = []
sxp.append(unpersistable_atom)
sxp.append(reason)
return sxp
class _Unjellier:
def __init__(self, taster, persistentLoad, invoker):
self.taster = taster
self.persistentLoad = persistentLoad
self.references = {}
self.postCallbacks = []
self.invoker = invoker
def unjellyFull(self, obj):
o = self.unjelly(obj)
for m in self.postCallbacks:
m()
return o
def unjelly(self, obj):
if type(obj) is not types.ListType:
return obj
jelType = obj[0]
if not self.taster.isTypeAllowed(jelType):
raise InsecureJelly(jelType)
regClass = unjellyableRegistry.get(jelType)
if regClass is not None:
if isinstance(regClass, ClassType):
inst = _Dummy() # XXX chomp, chomp
inst.__class__ = regClass
method = inst.unjellyFor
elif isinstance(regClass, type):
# regClass.__new__ does not call regClass.__init__
inst = regClass.__new__(regClass)
method = inst.unjellyFor
else:
method = regClass # this is how it ought to be done
val = method(self, obj)
if hasattr(val, 'postUnjelly'):
self.postCallbacks.append(inst.postUnjelly)
return val
regFactory = unjellyableFactoryRegistry.get(jelType)
if regFactory is not None:
state = self.unjelly(obj[1])
inst = regFactory(state)
if hasattr(inst, 'postUnjelly'):
self.postCallbacks.append(inst.postUnjelly)
return inst
thunk = getattr(self, '_unjelly_%s'%jelType, None)
if thunk is not None:
ret = thunk(obj[1:])
else:
nameSplit = jelType.split('.')
modName = '.'.join(nameSplit[:-1])
if not self.taster.isModuleAllowed(modName):
raise InsecureJelly(
"Module %s not allowed (in type %s)." % (modName, jelType))
clz = namedObject(jelType)
if not self.taster.isClassAllowed(clz):
raise InsecureJelly("Class %s not allowed." % jelType)
if hasattr(clz, "__setstate__"):
ret = _newInstance(clz)
state = self.unjelly(obj[1])
ret.__setstate__(state)
else:
state = self.unjelly(obj[1])
ret = _newInstance(clz, state)
if hasattr(clz, 'postUnjelly'):
self.postCallbacks.append(ret.postUnjelly)
return ret
def _unjelly_None(self, exp):
return None
def _unjelly_unicode(self, exp):
if UnicodeType:
return unicode(exp[0], "UTF-8")
else:
return Unpersistable("Could not unpersist unicode: %s" % (exp[0],))
def _unjelly_decimal(self, exp):
"""
Unjelly decimal objects, if decimal is available. If not, return a
L{Unpersistable} object instead.
"""
if decimal is None:
return Unpersistable(
"Could not unpersist decimal: %s" % (exp[0] * (10**exp[1]),))
value = exp[0]
exponent = exp[1]
if value < 0:
sign = 1
else:
sign = 0
guts = decimal.Decimal(value).as_tuple()[1]
return decimal.Decimal((sign, guts, exponent))
def _unjelly_boolean(self, exp):
if BooleanType:
assert exp[0] in ('true', 'false')
return exp[0] == 'true'
else:
return Unpersistable("Could not unpersist boolean: %s" % (exp[0],))
def _unjelly_datetime(self, exp):
return datetime.datetime(*map(int, exp[0].split()))
def _unjelly_date(self, exp):
return datetime.date(*map(int, exp[0].split()))
def _unjelly_time(self, exp):
return datetime.time(*map(int, exp[0].split()))
def _unjelly_timedelta(self, exp):
days, seconds, microseconds = map(int, exp[0].split())
return datetime.timedelta(
days=days, seconds=seconds, microseconds=microseconds)
def unjellyInto(self, obj, loc, jel):
o = self.unjelly(jel)
if isinstance(o, NotKnown):
o.addDependant(obj, loc)
obj[loc] = o
return o
def _unjelly_dereference(self, lst):
refid = lst[0]
x = self.references.get(refid)
if x is not None:
return x
der = _Dereference(refid)
self.references[refid] = der
return der
def _unjelly_reference(self, lst):
refid = lst[0]
exp = lst[1]
o = self.unjelly(exp)
ref = self.references.get(refid)
if (ref is None):
self.references[refid] = o
elif isinstance(ref, NotKnown):
ref.resolveDependants(o)
self.references[refid] = o
else:
assert 0, "Multiple references with same ID!"
return o
def _unjelly_tuple(self, lst):
l = range(len(lst))
finished = 1
for elem in l:
if isinstance(self.unjellyInto(l, elem, lst[elem]), NotKnown):
finished = 0
if finished:
return tuple(l)
else:
return _Tuple(l)
def _unjelly_list(self, lst):
l = range(len(lst))
for elem in l:
self.unjellyInto(l, elem, lst[elem])
return l
def _unjellySetOrFrozenset(self, lst, containerType):
"""
Helper method to unjelly set or frozenset.
@param lst: the content of the set.
@type lst: C{list}
@param containerType: the type of C{set} to use.
"""
l = range(len(lst))
finished = True
for elem in l:
data = self.unjellyInto(l, elem, lst[elem])
if isinstance(data, NotKnown):
finished = False
if not finished:
return _Container(l, containerType)
else:
return containerType(l)
def _unjelly_set(self, lst):
"""
Unjelly set using either the C{set} builtin if available, or
C{sets.Set} as fallback.
"""
if _set is not None:
containerType = set
else:
containerType = _sets.Set
return self._unjellySetOrFrozenset(lst, containerType)
def _unjelly_frozenset(self, lst):
"""
Unjelly frozenset using either the C{frozenset} builtin if available,
or C{sets.ImmutableSet} as fallback.
"""
if _set is not None:
containerType = frozenset
else:
containerType = _sets.ImmutableSet
return self._unjellySetOrFrozenset(lst, containerType)
def _unjelly_dictionary(self, lst):
d = {}
for k, v in lst:
kvd = _DictKeyAndValue(d)
self.unjellyInto(kvd, 0, k)
self.unjellyInto(kvd, 1, v)
return d
def _unjelly_module(self, rest):
moduleName = rest[0]
if type(moduleName) != types.StringType:
raise InsecureJelly(
"Attempted to unjelly a module with a non-string name.")
if not self.taster.isModuleAllowed(moduleName):
raise InsecureJelly(
"Attempted to unjelly module named %r" % (moduleName,))
mod = __import__(moduleName, {}, {},"x")
return mod
def _unjelly_class(self, rest):
clist = rest[0].split('.')
modName = '.'.join(clist[:-1])
if not self.taster.isModuleAllowed(modName):
raise InsecureJelly("module %s not allowed" % modName)
klaus = namedObject(rest[0])
objType = type(klaus)
if objType not in (types.ClassType, types.TypeType):
raise InsecureJelly(
"class %r unjellied to something that isn't a class: %r" % (
rest[0], klaus))
if not self.taster.isClassAllowed(klaus):
raise InsecureJelly("class not allowed: %s" % qual(klaus))
return klaus
def _unjelly_function(self, rest):
modSplit = rest[0].split('.')
modName = '.'.join(modSplit[:-1])
if not self.taster.isModuleAllowed(modName):
raise InsecureJelly("Module not allowed: %s"% modName)
# XXX do I need an isFunctionAllowed?
function = namedObject(rest[0])
return function
def _unjelly_persistent(self, rest):
if self.persistentLoad:
pload = self.persistentLoad(rest[0], self)
return pload
else:
return Unpersistable("Persistent callback not found")
def _unjelly_instance(self, rest):
clz = self.unjelly(rest[0])
if type(clz) is not types.ClassType:
raise InsecureJelly("Instance found with non-class class.")
if hasattr(clz, "__setstate__"):
inst = _newInstance(clz, {})
state = self.unjelly(rest[1])
inst.__setstate__(state)
else:
state = self.unjelly(rest[1])
inst = _newInstance(clz, state)
if hasattr(clz, 'postUnjelly'):
self.postCallbacks.append(inst.postUnjelly)
return inst
def _unjelly_unpersistable(self, rest):
return Unpersistable("Unpersistable data: %s" % (rest[0],))
def _unjelly_method(self, rest):
"""
(internal) Unjelly a method.
"""
im_name = rest[0]
im_self = self.unjelly(rest[1])
im_class = self.unjelly(rest[2])
if type(im_class) is not types.ClassType:
raise InsecureJelly("Method found with non-class class.")
if im_name in im_class.__dict__:
if im_self is None:
im = getattr(im_class, im_name)
elif isinstance(im_self, NotKnown):
im = _InstanceMethod(im_name, im_self, im_class)
else:
im = instancemethod(im_class.__dict__[im_name],
im_self,
im_class)
else:
raise TypeError('instance method changed')
return im
class _Dummy:
"""
(Internal) Dummy class, used for unserializing instances.
"""
class _DummyNewStyle(object):
"""
(Internal) Dummy class, used for unserializing instances of new-style
classes.
"""
#### Published Interface.
class InsecureJelly(Exception):
"""
This exception will be raised when a jelly is deemed `insecure'; e.g. it
contains a type, class, or module disallowed by the specified `taster'
"""
class DummySecurityOptions:
"""
DummySecurityOptions() -> insecure security options
Dummy security options -- this class will allow anything.
"""
def isModuleAllowed(self, moduleName):
"""
DummySecurityOptions.isModuleAllowed(moduleName) -> boolean
returns 1 if a module by that name is allowed, 0 otherwise
"""
return 1
def isClassAllowed(self, klass):
"""
DummySecurityOptions.isClassAllowed(class) -> boolean
Assumes the module has already been allowed. Returns 1 if the given
class is allowed, 0 otherwise.
"""
return 1
def isTypeAllowed(self, typeName):
"""
DummySecurityOptions.isTypeAllowed(typeName) -> boolean
Returns 1 if the given type is allowed, 0 otherwise.
"""
return 1
class SecurityOptions:
"""
This will by default disallow everything, except for 'none'.
"""
basicTypes = ["dictionary", "list", "tuple",
"reference", "dereference", "unpersistable",
"persistent", "long_int", "long", "dict"]
def __init__(self):
"""
SecurityOptions() initialize.
"""
# I don't believe any of these types can ever pose a security hazard,
# except perhaps "reference"...
self.allowedTypes = {"None": 1,
"bool": 1,
"boolean": 1,
"string": 1,
"str": 1,
"int": 1,
"float": 1,
"datetime": 1,
"time": 1,
"date": 1,
"timedelta": 1,
"NoneType": 1}
if hasattr(types, 'UnicodeType'):
self.allowedTypes['unicode'] = 1
if decimal is not None:
self.allowedTypes['decimal'] = 1
self.allowedTypes['set'] = 1
self.allowedTypes['frozenset'] = 1
self.allowedModules = {}
self.allowedClasses = {}
def allowBasicTypes(self):
"""
Allow all `basic' types. (Dictionary and list. Int, string, and float
are implicitly allowed.)
"""
self.allowTypes(*self.basicTypes)
def allowTypes(self, *types):
"""
SecurityOptions.allowTypes(typeString): Allow a particular type, by its
name.
"""
for typ in types:
if not isinstance(typ, str):
typ = qual(typ)
self.allowedTypes[typ] = 1
def allowInstancesOf(self, *classes):
"""
SecurityOptions.allowInstances(klass, klass, ...): allow instances
of the specified classes
This will also allow the 'instance', 'class' (renamed 'classobj' in
Python 2.3), and 'module' types, as well as basic types.
"""
self.allowBasicTypes()
self.allowTypes("instance", "class", "classobj", "module")
for klass in classes:
self.allowTypes(qual(klass))
self.allowModules(klass.__module__)
self.allowedClasses[klass] = 1
def allowModules(self, *modules):
"""
SecurityOptions.allowModules(module, module, ...): allow modules by
name. This will also allow the 'module' type.
"""
for module in modules:
if type(module) == types.ModuleType:
module = module.__name__
self.allowedModules[module] = 1
def isModuleAllowed(self, moduleName):
"""
SecurityOptions.isModuleAllowed(moduleName) -> boolean
returns 1 if a module by that name is allowed, 0 otherwise
"""
return moduleName in self.allowedModules
def isClassAllowed(self, klass):
"""
SecurityOptions.isClassAllowed(class) -> boolean
Assumes the module has already been allowed. Returns 1 if the given
class is allowed, 0 otherwise.
"""
return klass in self.allowedClasses
def isTypeAllowed(self, typeName):
"""
SecurityOptions.isTypeAllowed(typeName) -> boolean
Returns 1 if the given type is allowed, 0 otherwise.
"""
return (typeName in self.allowedTypes or '.' in typeName)
globalSecurity = SecurityOptions()
globalSecurity.allowBasicTypes()
def jelly(object, taster=DummySecurityOptions(), persistentStore=None,
invoker=None):
"""
Serialize to s-expression.
Returns a list which is the serialized representation of an object. An
optional 'taster' argument takes a SecurityOptions and will mark any
insecure objects as unpersistable rather than serializing them.
"""
return _Jellier(taster, persistentStore, invoker).jelly(object)
def unjelly(sexp, taster=DummySecurityOptions(), persistentLoad=None,
invoker=None):
"""
Unserialize from s-expression.
Takes an list that was the result from a call to jelly() and unserializes
an arbitrary object from it. The optional 'taster' argument, an instance
of SecurityOptions, will cause an InsecureJelly exception to be raised if a
disallowed type, module, or class attempted to unserialize.
"""
return _Unjellier(taster, persistentLoad, invoker).unjellyFull(sexp)
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