Lib/copy.py - platform/external/python/cpython2 - Gitiles

 """Generic (shallow and deep) copying operations.

 Interface summary:

         import copy

         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
 class instances).

 - A shallow copy constructs a new compound object and then (to the
   extent possible) inserts *the same objects* into it that the
   original contains.

 - 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
     copies

 Python's deep copy operation avoids these problems by:

  a) keeping a table of objects already copied during the current
     copying pass

  b) letting user-defined classes override the copying operation or the
     set of components copied

 This version does not copy types like module, class, function, method,
 nor stack trace, stack frame, nor file, socket, window, nor array, nor
 any similar types.

 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.
 """

 import types
 from copy_reg import dispatch_table

 class Error(Exception):
     pass
 error = Error   # backward compatibility

 try:
     from org.python.core import PyStringMap
 except ImportError:
     PyStringMap = None

 __all__ = ["Error", "copy", "deepcopy"]

 def copy(x):
     """Shallow copy operation on arbitrary Python objects.

     See the module's __doc__ string for more info.
     """

     cls = type(x)

     copier = _copy_dispatch.get(cls)
     if copier:
         return copier(x)

     copier = getattr(cls, "__copy__", None)
     if copier:
         return copier(x)

     reductor = dispatch_table.get(cls)
     if reductor:
         rv = reductor(x)
     else:
         reductor = getattr(x, "__reduce_ex__", None)
         if reductor:
             rv = reductor(2)
         else:
             reductor = getattr(x, "__reduce__", None)
             if reductor:
                 rv = reductor()
             else:
                 raise Error("un(shallow)copyable object of type %s" % cls)

     return _reconstruct(x, rv, 0)


 _copy_dispatch = d = {}

 def _copy_immutable(x):
     return x
 for t in (type(None), int, long, float, bool, str, tuple,
           frozenset, type, xrange, types.ClassType,
           types.BuiltinFunctionType, type(Ellipsis),
           types.FunctionType):
     d[t] = _copy_immutable
 for name in ("ComplexType", "UnicodeType", "CodeType"):
     t = getattr(types, name, None)
     if t is not None:
         d[t] = _copy_immutable

 def _copy_with_constructor(x):
     return type(x)(x)
 for t in (list, dict, set):
     d[t] = _copy_with_constructor

 def _copy_with_copy_method(x):
     return x.copy()
 if PyStringMap is not None:
     d[PyStringMap] = _copy_with_copy_method

 def _copy_inst(x):
     if hasattr(x, '__copy__'):
         return x.__copy__()
     if hasattr(x, '__getinitargs__'):
         args = x.__getinitargs__()
         y = x.__class__(*args)
     else:
         y = _EmptyClass()
         y.__class__ = x.__class__
     if hasattr(x, '__getstate__'):
         state = x.__getstate__()
     else:
         state = x.__dict__
     if hasattr(y, '__setstate__'):
         y.__setstate__(state)
     else:
         y.__dict__.update(state)
     return y
 d[types.InstanceType] = _copy_inst

 del d

 def deepcopy(x, memo=None, _nil=[]):
     """Deep copy operation on arbitrary Python objects.

     See the module's __doc__ string for more info.
     """

     if memo is None:
         memo = {}

     d = id(x)
     y = memo.get(d, _nil)
     if y is not _nil:
         return y

     cls = type(x)

     copier = _deepcopy_dispatch.get(cls)
     if copier:
         y = copier(x, memo)
     else:
         try:
             issc = issubclass(cls, type)
         except TypeError: # cls is not a class (old Boost; see SF #502085)
             issc = 0
         if issc:
             y = _deepcopy_atomic(x, memo)
         else:
             copier = getattr(x, "__deepcopy__", None)
             if copier:
                 y = copier(memo)
             else:
                 reductor = dispatch_table.get(cls)
                 if reductor:
                     rv = reductor(x)
                 else:
                     reductor = getattr(x, "__reduce_ex__", None)
                     if reductor:
                         rv = reductor(2)
                     else:
                         reductor = getattr(x, "__reduce__", None)
                         if reductor:
                             rv = reductor()
                         else:
                             raise Error(
                                 "un(deep)copyable object of type %s" % cls)
                 y = _reconstruct(x, rv, 1, memo)

     memo[d] = y
     _keep_alive(x, memo) # Make sure x lives at least as long as d
     return y

 _deepcopy_dispatch = d = {}

 def _deepcopy_atomic(x, memo):
     return x
 d[type(None)] = _deepcopy_atomic
 d[type(Ellipsis)] = _deepcopy_atomic
 d[int] = _deepcopy_atomic
 d[long] = _deepcopy_atomic
 d[float] = _deepcopy_atomic
 d[bool] = _deepcopy_atomic
 try:
     d[complex] = _deepcopy_atomic
 except NameError:
     pass
 d[str] = _deepcopy_atomic
 try:
     d[unicode] = _deepcopy_atomic
 except NameError:
     pass
 try:
     d[types.CodeType] = _deepcopy_atomic
 except AttributeError:
     pass
 d[type] = _deepcopy_atomic
 d[xrange] = _deepcopy_atomic
 d[types.ClassType] = _deepcopy_atomic
 d[types.BuiltinFunctionType] = _deepcopy_atomic
 d[types.FunctionType] = _deepcopy_atomic

 def _deepcopy_list(x, memo):
     y = []
     memo[id(x)] = y
     for a in x:
         y.append(deepcopy(a, memo))
     return y
 d[list] = _deepcopy_list

 def _deepcopy_tuple(x, memo):
     y = []
     for a in x:
         y.append(deepcopy(a, memo))
     d = id(x)
     try:
         return memo[d]
     except KeyError:
         pass
     for i in range(len(x)):
         if x[i] is not y[i]:
             y = tuple(y)
             break
     else:
         y = x
     memo[d] = y
     return y
 d[tuple] = _deepcopy_tuple

 def _deepcopy_dict(x, memo):
     y = {}
     memo[id(x)] = y
     for key, value in x.iteritems():
         y[deepcopy(key, memo)] = deepcopy(value, memo)
     return y
 d[dict] = _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
     the memo itself...
     """
     try:
         memo[id(memo)].append(x)
     except KeyError:
         # aha, this is the first one :-)
         memo[id(memo)]=[x]

 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 = x.__class__(*args)
     else:
         y = _EmptyClass()
         y.__class__ = x.__class__
     memo[id(x)] = y
     if hasattr(x, '__getstate__'):
         state = x.__getstate__()
     else:
         state = x.__dict__
     state = deepcopy(state, memo)
     if hasattr(y, '__setstate__'):
         y.__setstate__(state)
     else:
         y.__dict__.update(state)
     return y
 d[types.InstanceType] = _deepcopy_inst

 def _reconstruct(x, info, deep, memo=None):
     if isinstance(info, str):
         return x
     assert isinstance(info, tuple)
     if memo is None:
         memo = {}
     n = len(info)
     assert n in (2, 3, 4, 5)
     callable, args = info[:2]
     if n > 2:
         state = info[2]
     else:
         state = {}
     if n > 3:
         listiter = info[3]
     else:
         listiter = None
     if n > 4:
         dictiter = info[4]
     else:
         dictiter = None
     if deep:
         args = deepcopy(args, memo)
     y = callable(*args)
     memo[id(x)] = y
     if listiter is not None:
         for item in listiter:
             if deep:
                 item = deepcopy(item, memo)
             y.append(item)
     if dictiter is not None:
         for key, value in dictiter:
             if deep:
                 key = deepcopy(key, memo)
                 value = deepcopy(value, memo)
             y[key] = value
     if state:
         if deep:
             state = deepcopy(state, memo)
         if hasattr(y, '__setstate__'):
             y.__setstate__(state)
         else:
             if isinstance(state, tuple) and len(state) == 2:
                 state, slotstate = state
             else:
                 slotstate = None
             if state is not None:
                 y.__dict__.update(state)
             if slotstate is not None:
                 for key, value in slotstate.iteritems():
                     setattr(y, key, value)
     return y

 del d

 del types

 # Helper for instance creation without calling __init__
 class _EmptyClass:
     pass

 def _test():
     l = [None, 1, 2L, 3.14, 'xyzzy', (1, 2L), [3.14, 'abc'],
          {'abc': 'ABC'}, (), [], {}]
     l1 = copy(l)
     print l1==l
     l1 = map(copy, l)
     print l1==l
     l1 = deepcopy(l)
     print l1==l
     class C:
         def __init__(self, arg=None):
             self.a = 1
             self.arg = arg
             if __name__ == '__main__':
                 import sys
                 file = sys.argv[0]
             else:
                 file = __file__
             self.fp = open(file)
             self.fp.close()
         def __getstate__(self):
             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))
             new.a = self.a
             return new
     c = C('argument sketch')
     l.append(c)
     l2 = copy(l)
     print l == l2
     print l
     print l2
     l2 = deepcopy(l)
     print l == l2
     print l
     print l2
     l.append({l[1]: l, 'xyz': l[2]})
     l3 = copy(l)
     import repr
     print map(repr.repr, l)
     print map(repr.repr, l1)
     print map(repr.repr, l2)
     print map(repr.repr, l3)
     l3 = deepcopy(l)
     import repr
     print map(repr.repr, l)
     print map(repr.repr, l1)
     print map(repr.repr, l2)
     print map(repr.repr, l3)

 if __name__ == '__main__':
     _test()
	"""Generic (shallow and deep) copying operations.

	Interface summary:

	import copy

	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
	class instances).

	- A shallow copy constructs a new compound object and then (to the
	extent possible) inserts the same objects into it that the
	original contains.

	- 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
	copies

	Python's deep copy operation avoids these problems by:

	a) keeping a table of objects already copied during the current
	copying pass

	b) letting user-defined classes override the copying operation or the
	set of components copied

	This version does not copy types like module, class, function, method,
	nor stack trace, stack frame, nor file, socket, window, nor array, nor
	any similar types.

	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.
	"""

	import types
	from copy_reg import dispatch_table

	class Error(Exception):
	pass
	error = Error # backward compatibility

	try:
	from org.python.core import PyStringMap
	except ImportError:
	PyStringMap = None

	__all__ = ["Error", "copy", "deepcopy"]

	def copy(x):
	"""Shallow copy operation on arbitrary Python objects.

	See the module's __doc__ string for more info.
	"""

	cls = type(x)

	copier = _copy_dispatch.get(cls)
	if copier:
	return copier(x)

	copier = getattr(cls, "__copy__", None)
	if copier:
	return copier(x)

	reductor = dispatch_table.get(cls)
	if reductor:
	rv = reductor(x)
	else:
	reductor = getattr(x, "__reduce_ex__", None)
	if reductor:
	rv = reductor(2)
	else:
	reductor = getattr(x, "__reduce__", None)
	if reductor:
	rv = reductor()
	else:
	raise Error("un(shallow)copyable object of type %s" % cls)

	return _reconstruct(x, rv, 0)


	_copy_dispatch = d = {}

	def _copy_immutable(x):
	return x
	for t in (type(None), int, long, float, bool, str, tuple,
	frozenset, type, xrange, types.ClassType,
	types.BuiltinFunctionType, type(Ellipsis),
	types.FunctionType):
	d[t] = _copy_immutable
	for name in ("ComplexType", "UnicodeType", "CodeType"):
	t = getattr(types, name, None)
	if t is not None:
	d[t] = _copy_immutable

	def _copy_with_constructor(x):
	return type(x)(x)
	for t in (list, dict, set):
	d[t] = _copy_with_constructor

	def _copy_with_copy_method(x):
	return x.copy()
	if PyStringMap is not None:
	d[PyStringMap] = _copy_with_copy_method

	def _copy_inst(x):
	if hasattr(x, '__copy__'):
	return x.__copy__()
	if hasattr(x, '__getinitargs__'):
	args = x.__getinitargs__()
	y = x.__class__(*args)
	else:
	y = _EmptyClass()
	y.__class__ = x.__class__
	if hasattr(x, '__getstate__'):
	state = x.__getstate__()
	else:
	state = x.__dict__
	if hasattr(y, '__setstate__'):
	y.__setstate__(state)
	else:
	y.__dict__.update(state)
	return y
	d[types.InstanceType] = _copy_inst

	del d

	def deepcopy(x, memo=None, _nil=[]):
	"""Deep copy operation on arbitrary Python objects.

	See the module's __doc__ string for more info.
	"""

	if memo is None:
	memo = {}

	d = id(x)
	y = memo.get(d, _nil)
	if y is not _nil:
	return y

	cls = type(x)

	copier = _deepcopy_dispatch.get(cls)
	if copier:
	y = copier(x, memo)
	else:
	try:
	issc = issubclass(cls, type)
	except TypeError: # cls is not a class (old Boost; see SF #502085)
	issc = 0
	if issc:
	y = _deepcopy_atomic(x, memo)
	else:
	copier = getattr(x, "__deepcopy__", None)
	if copier:
	y = copier(memo)
	else:
	reductor = dispatch_table.get(cls)
	if reductor:
	rv = reductor(x)
	else:
	reductor = getattr(x, "__reduce_ex__", None)
	if reductor:
	rv = reductor(2)
	else:
	reductor = getattr(x, "__reduce__", None)
	if reductor:
	rv = reductor()
	else:
	raise Error(
	"un(deep)copyable object of type %s" % cls)
	y = _reconstruct(x, rv, 1, memo)

	memo[d] = y
	_keep_alive(x, memo) # Make sure x lives at least as long as d
	return y

	_deepcopy_dispatch = d = {}

	def _deepcopy_atomic(x, memo):
	return x
	d[type(None)] = _deepcopy_atomic
	d[type(Ellipsis)] = _deepcopy_atomic
	d[int] = _deepcopy_atomic
	d[long] = _deepcopy_atomic
	d[float] = _deepcopy_atomic
	d[bool] = _deepcopy_atomic
	try:
	d[complex] = _deepcopy_atomic
	except NameError:
	pass
	d[str] = _deepcopy_atomic
	try:
	d[unicode] = _deepcopy_atomic
	except NameError:
	pass
	try:
	d[types.CodeType] = _deepcopy_atomic
	except AttributeError:
	pass
	d[type] = _deepcopy_atomic
	d[xrange] = _deepcopy_atomic
	d[types.ClassType] = _deepcopy_atomic
	d[types.BuiltinFunctionType] = _deepcopy_atomic
	d[types.FunctionType] = _deepcopy_atomic

	def _deepcopy_list(x, memo):
	y = []
	memo[id(x)] = y
	for a in x:
	y.append(deepcopy(a, memo))
	return y
	d[list] = _deepcopy_list

	def _deepcopy_tuple(x, memo):
	y = []
	for a in x:
	y.append(deepcopy(a, memo))
	d = id(x)
	try:
	return memo[d]
	except KeyError:
	pass
	for i in range(len(x)):
	if x[i] is not y[i]:
	y = tuple(y)
	break
	else:
	y = x
	memo[d] = y
	return y
	d[tuple] = _deepcopy_tuple

	def _deepcopy_dict(x, memo):
	y = {}
	memo[id(x)] = y
	for key, value in x.iteritems():
	y[deepcopy(key, memo)] = deepcopy(value, memo)
	return y
	d[dict] = _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
	the memo itself...
	"""
	try:
	memo[id(memo)].append(x)
	except KeyError:
	# aha, this is the first one :-)
	memo[id(memo)]=[x]

	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 = x.__class__(*args)
	else:
	y = _EmptyClass()
	y.__class__ = x.__class__
	memo[id(x)] = y
	if hasattr(x, '__getstate__'):
	state = x.__getstate__()
	else:
	state = x.__dict__
	state = deepcopy(state, memo)
	if hasattr(y, '__setstate__'):
	y.__setstate__(state)
	else:
	y.__dict__.update(state)
	return y
	d[types.InstanceType] = _deepcopy_inst

	def _reconstruct(x, info, deep, memo=None):
	if isinstance(info, str):
	return x
	assert isinstance(info, tuple)
	if memo is None:
	memo = {}
	n = len(info)
	assert n in (2, 3, 4, 5)
	callable, args = info[:2]
	if n > 2:
	state = info[2]
	else:
	state = {}
	if n > 3:
	listiter = info[3]
	else:
	listiter = None
	if n > 4:
	dictiter = info[4]
	else:
	dictiter = None
	if deep:
	args = deepcopy(args, memo)
	y = callable(*args)
	memo[id(x)] = y
	if listiter is not None:
	for item in listiter:
	if deep:
	item = deepcopy(item, memo)
	y.append(item)
	if dictiter is not None:
	for key, value in dictiter:
	if deep:
	key = deepcopy(key, memo)
	value = deepcopy(value, memo)
	y[key] = value
	if state:
	if deep:
	state = deepcopy(state, memo)
	if hasattr(y, '__setstate__'):
	y.__setstate__(state)
	else:
	if isinstance(state, tuple) and len(state) == 2:
	state, slotstate = state
	else:
	slotstate = None
	if state is not None:
	y.__dict__.update(state)
	if slotstate is not None:
	for key, value in slotstate.iteritems():
	setattr(y, key, value)
	return y

	del d

	del types

	# Helper for instance creation without calling __init__
	class _EmptyClass:
	pass

	def _test():
	l = [None, 1, 2L, 3.14, 'xyzzy', (1, 2L), [3.14, 'abc'],
	{'abc': 'ABC'}, (), [], {}]
	l1 = copy(l)
	print l1==l
	l1 = map(copy, l)
	print l1==l
	l1 = deepcopy(l)
	print l1==l
	class C:
	def __init__(self, arg=None):
	self.a = 1
	self.arg = arg
	if __name__ == '__main__':
	import sys
	file = sys.argv[0]
	else:
	file = __file__
	self.fp = open(file)
	self.fp.close()
	def __getstate__(self):
	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))
	new.a = self.a
	return new
	c = C('argument sketch')
	l.append(c)
	l2 = copy(l)
	print l == l2
	print l
	print l2
	l2 = deepcopy(l)
	print l == l2
	print l
	print l2
	l.append({l[1]: l, 'xyz': l[2]})
	l3 = copy(l)
	import repr
	print map(repr.repr, l)
	print map(repr.repr, l1)
	print map(repr.repr, l2)
	print map(repr.repr, l3)
	l3 = deepcopy(l)
	import repr
	print map(repr.repr, l)
	print map(repr.repr, l1)
	print map(repr.repr, l2)
	print map(repr.repr, l3)

	if __name__ == '__main__':
	_test()