def _get_flattener(self, obj):
if util.is_primitive(obj):
return lambda obj: obj
list_recurse = lambda obj: [self.flatten(v) for v in obj]
if util.is_list(obj):
if self._mkref(obj):
return list_recurse
else:
self._push()
return self._getref
# We handle tuples and sets by encoding them in a "(tuple|set)dict"
if util.is_tuple(obj):
if not self.unpicklable:
return list_recurse
return lambda obj: {tags.TUPLE: [self.flatten(v) for v in obj]}
if util.is_set(obj):
if not self.unpicklable:
return list_recurse
return lambda obj: {tags.SET: [self.flatten(v) for v in obj]}
if util.is_dictionary(obj):
return self._flatten_dict_obj
if util.is_type(obj):
return _mktyperef
if util.is_object(obj):
return self._ref_obj_instance
# else, what else? (methods, functions, old style classes...)
return None
def _get_flattener(self, obj):
if util.is_primitive(obj):
return lambda obj: obj
list_recurse = lambda obj: [self.flatten(v) for v in obj]
if util.is_list(obj):
if self._mkref(obj):
return list_recurse
else:
self._push()
return self._getref
# We handle tuples and sets by encoding them in a "(tuple|set)dict"
if util.is_tuple(obj):
if not self.unpicklable:
return list_recurse
return lambda obj: {tags.TUPLE: [self.flatten(v) for v in obj]}
if util.is_set(obj):
if not self.unpicklable:
return list_recurse
return lambda obj: {tags.SET: [self.flatten(v) for v in obj]}
if util.is_dictionary(obj):
return self._flatten_dict_obj
if util.is_type(obj):
return _mktyperef
if util.is_object(obj):
return self._ref_obj_instance
# else, what else? (methods, functions, old style classes...)
return None
def restore(self, obj, cls_def = None):
"""Restores a flattened object to its original python state.
Simply returns any of the basic builtin types
>>> u = Unpickler()
>>> u.restore('hello world')
'hello world'
>>> u.restore({'key': 'value'})
{'key': 'value'}
cls_def could be either a type or an instance. In case of instance, it
will be used to define types inside a list or dict. eg. [Test()] means
a list of Test.
"""
self._push()
if has_tag(obj, tags.ID):
return self._pop(self._objs[obj[tags.ID]])
# Backwards compatibility
if has_tag(obj, tags.REF):
return self._pop(self._namedict.get(obj[tags.REF]))
if has_tag(obj, tags.TYPE):
typeref = loadclass(obj[tags.TYPE])
if not typeref:
return self._pop(obj)
return self._pop(typeref)
# Backwards compatibility
if has_tag(obj, tags.REPR):
obj = loadrepr(obj[tags.REPR])
return self._pop(self._mkref(obj))
if util.is_type(cls_def):
if not util.is_dictionary(obj):
# Type mismatch. cls_def is a type but we didn't get a dict
# from JSON. Return None.
return self._pop(None)
# check custom handlers
HandlerClass = handlers.BaseHandler._registry.get(cls_def)
if HandlerClass:
handler = HandlerClass(self)
instance = handler.restore(obj)
return self._pop(self._mkref(instance))
factory = loadfactory(obj)
args = getargs(obj, cls_def)
if args:
args = self.restore(args)
try:
if hasattr(cls_def, '__new__'):
# new style classes
if factory:
instance = cls_def.__new__(cls_def, factory, *args)
instance.default_factory = factory
else:
instance = cls_def.__new__(cls_def, *args)
else:
instance = object.__new__(cls_def)
except TypeError:
# old-style classes
try:
instance = cls_def()
except TypeError:
# fail gracefully if the constructor requires arguments
return self._pop(self._mkref(obj))
# Add to the instance table to allow being referenced by a
# downstream object
self._mkref(instance)
if isinstance(instance, tuple):
return self._pop(instance)
if hasattr(instance, '__setstate__') and has_tag(obj, tags.STATE):
state = self.restore(obj[tags.STATE])
instance.__setstate__(state)
return self._pop(instance)
for k in util.get_public_variables(cls_def):
if k in obj:
v = obj[k]
# ignore the reserved attribute
if k in tags.RESERVED:
continue
self._namestack.append(k)
# step into the namespace
value = self.restore(v, get_attr_cls_def(cls_def, k))
if (util.is_noncomplex(instance) or
util.is_dictionary(instance)):
instance[k] = value
else:
setattr(instance, k, value)
# step out
self._namestack.pop()
else:
# Attribute in cls_def but not given in JSON. Assign it to
# None so that user could tell that it wasn't given know.
setattr(instance, k, None)
# Handle list and set subclasses
if has_tag(obj, tags.SEQ):
if hasattr(instance, 'append'):
for v in obj[tags.SEQ]:
instance.append(self.restore(v))
if hasattr(instance, 'add'):
for v in obj[tags.SEQ]:
instance.add(self.restore(v))
return self._pop(instance)
if util.is_list(obj):
if util.is_collection(cls_def):
parent = type(cls_def)()
else:
parent = []
self._mkref(parent)
item_type = get_collection_item_type(cls_def)
is_set = type(parent) is set
for v in obj:
restored_v = self.restore(v, item_type)
if is_set:
parent.add(restored_v)
else:
parent.append(restored_v)
return self._pop(parent)
if has_tag(obj, tags.TUPLE):
return self._pop(tuple([self.restore(v)
for v in obj[tags.TUPLE]]))
if has_tag(obj, tags.SET):
return self._pop(set([self.restore(v)
for v in obj[tags.SET]]))
if util.is_dictionary(obj):
if util.is_dictionary(cls_def):
data = type(cls_def)()
else:
data = {}
k_type, v_type = get_dictionary_item_type(cls_def)
for k, v in sorted(obj.items(), key=operator.itemgetter(0)):
self._namestack.append(k)
data[self.restore(k, k_type)] = self.restore(v, v_type)
self._namestack.pop()
return self._pop(data)
return self._pop(obj)
