"""Generic (shallow and deep) copying operations.
x = copy.copy(y) # make a shallow copy of y
x = copy.deepcopy(y) # make a deep copy of y
For module specific errors, copy.Error is raised.
The difference between shallow and deep copying is only relevant for
compound objects (objects that contain other objects, like lists or
- A shallow copy constructs a new compound object and then (to the
extent possible) inserts *the same objects* into it that the
- A deep copy constructs a new compound object and then, recursively,
inserts *copies* into it of the objects found in the original.
Two problems often exist with deep copy operations that don't exist
with shallow copy operations:
a) recursive objects (compound objects that, directly or indirectly,
contain a reference to themselves) may cause a recursive loop
b) because deep copy copies *everything* it may copy too much, e.g.
administrative data structures that should be shared even between
Python's deep copy operation avoids these problems by:
a) keeping a table of objects already copied during the current
b) letting user-defined classes override the copying operation or the
This version does not copy types like module, class, function, method,
nor stack trace, stack frame, nor file, socket, window, nor array, nor
Classes can use the same interfaces to control copying that they use
to control pickling: they can define methods called __getinitargs__(),
__getstate__() and __setstate__(). See the documentation for module
"pickle" for information on these methods.
from copy_reg
import dispatch_table
error
= Error
# backward compatibility
from org
.python
.core
import PyStringMap
__all__
= ["Error", "copy", "deepcopy"]
def _getspecial(cls
, name
):
for basecls
in inspect
.getmro(cls
):
return basecls
.__dict
__[name
]
"""Shallow copy operation on arbitrary Python objects.
See the module's __doc__ string for more info.
copier
= _copy_dispatch
.get(cls
)
copier
= _getspecial(cls
, "__copy__")
reductor
= dispatch_table
.get(cls
)
reductor
= getattr(x
, "__reduce_ex__", None)
reductor
= getattr(x
, "__reduce__", None)
copier
= getattr(x
, "__copy__", None)
raise Error("un(shallow)copyable object of type %s" % cls
)
return _reconstruct(x
, rv
, 0)
for t
in (types
.NoneType
, int, long, float, bool, str, tuple,
frozenset, type, xrange, types
.ClassType
,
types
.BuiltinFunctionType
):
for name
in ("ComplexType", "UnicodeType", "CodeType"):
t
= getattr(types
, name
, None)
def _copy_with_constructor(x
):
for t
in (list, dict, set):
d
[t
] = _copy_with_constructor
def _copy_with_copy_method(x
):
if PyStringMap
is not None:
d
[PyStringMap
] = _copy_with_copy_method
if hasattr(x
, '__copy__'):
if hasattr(x
, '__getinitargs__'):
args
= x
.__getinitargs
__()
y
.__class
__ = x
.__class
__
if hasattr(x
, '__getstate__'):
if hasattr(y
, '__setstate__'):
d
[types
.InstanceType
] = _copy_inst
def deepcopy(x
, memo
=None, _nil
=[]):
"""Deep copy operation on arbitrary Python objects.
See the module's __doc__ string for more info.
copier
= _deepcopy_dispatch
.get(cls
)
issc
= issubclass(cls
, type)
except TypeError: # cls is not a class (old Boost; see SF #502085)
y
= _deepcopy_atomic(x
, memo
)
copier
= _getspecial(cls
, "__deepcopy__")
reductor
= dispatch_table
.get(cls
)
reductor
= getattr(x
, "__reduce_ex__", None)
reductor
= getattr(x
, "__reduce__", None)
copier
= getattr(x
, "__deepcopy__", None)
"un(deep)copyable object of type %s" % cls
)
y
= _reconstruct(x
, rv
, 1, memo
)
_keep_alive(x
, memo
) # Make sure x lives at least as long as d
_deepcopy_dispatch
= d
= {}
def _deepcopy_atomic(x
, memo
):
d
[types
.NoneType
] = _deepcopy_atomic
d
[types
.IntType
] = _deepcopy_atomic
d
[types
.LongType
] = _deepcopy_atomic
d
[types
.FloatType
] = _deepcopy_atomic
d
[types
.BooleanType
] = _deepcopy_atomic
d
[types
.ComplexType
] = _deepcopy_atomic
d
[types
.StringType
] = _deepcopy_atomic
d
[types
.UnicodeType
] = _deepcopy_atomic
d
[types
.CodeType
] = _deepcopy_atomic
d
[types
.TypeType
] = _deepcopy_atomic
d
[types
.XRangeType
] = _deepcopy_atomic
d
[types
.ClassType
] = _deepcopy_atomic
d
[types
.BuiltinFunctionType
] = _deepcopy_atomic
def _deepcopy_list(x
, memo
):
y
.append(deepcopy(a
, memo
))
d
[types
.ListType
] = _deepcopy_list
def _deepcopy_tuple(x
, memo
):
y
.append(deepcopy(a
, memo
))
d
[types
.TupleType
] = _deepcopy_tuple
def _deepcopy_dict(x
, memo
):
for key
, value
in x
.iteritems():
y
[deepcopy(key
, memo
)] = deepcopy(value
, memo
)
d
[types
.DictionaryType
] = _deepcopy_dict
if PyStringMap
is not None:
d
[PyStringMap
] = _deepcopy_dict
def _keep_alive(x
, memo
):
"""Keeps a reference to the object x in the memo.
Because we remember objects by their id, we have
to assure that possibly temporary objects are kept
alive by referencing them.
We store a reference at the id of the memo, which should
normally not be used unless someone tries to deepcopy
# aha, this is the first one :-)
def _deepcopy_inst(x
, memo
):
if hasattr(x
, '__deepcopy__'):
return x
.__deepcopy
__(memo
)
if hasattr(x
, '__getinitargs__'):
args
= x
.__getinitargs
__()
args
= deepcopy(args
, memo
)
y
.__class
__ = x
.__class
__
if hasattr(x
, '__getstate__'):
state
= deepcopy(state
, memo
)
if hasattr(y
, '__setstate__'):
d
[types
.InstanceType
] = _deepcopy_inst
def _reconstruct(x
, info
, deep
, memo
=None):
if isinstance(info
, str):
assert isinstance(info
, tuple)
callable, args
= info
[:2]
args
= deepcopy(args
, memo
)
item
= deepcopy(item
, memo
)
for key
, value
in dictiter
:
key
= deepcopy(key
, memo
)
value
= deepcopy(value
, memo
)
state
= deepcopy(state
, memo
)
if hasattr(y
, '__setstate__'):
if isinstance(state
, tuple) and len(state
) == 2:
if slotstate
is not None:
for key
, value
in slotstate
.iteritems():
# Helper for instance creation without calling __init__
l
= [None, 1, 2L, 3.14, 'xyzzy', (1, 2L), [3.14, 'abc'],
{'abc': 'ABC'}, (), [], {}]
def __init__(self
, arg
=None):
if __name__
== '__main__':
return {'a': self
.a
, 'arg': self
.arg
}
def __setstate__(self
, state
):
for key
, value
in state
.iteritems():
setattr(self
, key
, value
)
def __deepcopy__(self
, memo
=None):
new
= self
.__class
__(deepcopy(self
.arg
, memo
))
l
.append({l
[1]: l
, 'xyz': l
[2]})
if __name__
== '__main__':