PEP 367 – New Super
- PEP
- 367
- Title
- New Super
- Author
- Calvin Spealman <ironfroggy at gmail.com>, Tim Delaney <timothy.c.delaney at gmail.com>
- Status
- Superseded
- Type
- Standards Track
- Created
- 28-Apr-2007
- Python-Version
- 2.6
- Post-History
- 28-Apr-2007, 29-Apr-2007, 29-Apr-2007, 14-May-2007
Numbering Note
This PEP has been renumbered to PEP 3135. The text below is the last version submitted under the old number.
Abstract
This PEP proposes syntactic sugar for use of the super
type to automatically
construct instances of the super type binding to the class that a method was
defined in, and the instance (or class object for classmethods) that the method
is currently acting upon.
The premise of the new super usage suggested is as follows:
super.foo(1, 2)
to replace the old:
super(Foo, self).foo(1, 2)
and the current __builtin__.super
be aliased to __builtin__.__super__
(with __builtin__.super
to be removed in Python 3.0).
It is further proposed that assignment to super
become a SyntaxError
,
similar to the behaviour of None
.
Rationale
The current usage of super requires an explicit passing of both the class and instance it must operate from, requiring a breaking of the DRY (Don’t Repeat Yourself) rule. This hinders any change in class name, and is often considered a wart by many.
Specification
Within the specification section, some special terminology will be used to distinguish similar and closely related concepts. “super type” will refer to the actual builtin type named “super”. A “super instance” is simply an instance of the super type, which is associated with a class and possibly with an instance of that class.
Because the new super
semantics are not backwards compatible with Python
2.5, the new semantics will require a __future__
import:
from __future__ import new_super
The current __builtin__.super
will be aliased to __builtin__.__super__
.
This will occur regardless of whether the new super
semantics are active.
It is not possible to simply rename __builtin__.super
, as that would affect
modules that do not use the new super
semantics. In Python 3.0 it is
proposed that the name __builtin__.super
will be removed.
Replacing the old usage of super, calls to the next class in the MRO (method
resolution order) can be made without explicitly creating a super
instance (although doing so will still be supported via __super__
). Every
function will have an implicit local named super
. This name behaves
identically to a normal local, including use by inner functions via a cell,
with the following exceptions:
- Assigning to the name
super
will raise aSyntaxError
at compile time; - Calling a static method or normal function that accesses the name
super
will raise aTypeError
at runtime.
Every function that uses the name super
, or has an inner function that
uses the name super
, will include a preamble that performs the equivalent
of:
super = __builtin__.__super__(<class>, <instance>)
where <class>
is the class that the method was defined in, and
<instance>
is the first parameter of the method (normally self
for
instance methods, and cls
for class methods). For static methods and normal
functions, <class>
will be None
, resulting in a TypeError
being
raised during the preamble.
Note: The relationship between super
and __super__
is similar to that
between import
and __import__
.
Much of this was discussed in the thread of the python-dev list, “Fixing super anyone?” [1].
Open Issues
Determining the class object to use
The exact mechanism for associating the method with the defining class is not
specified in this PEP, and should be chosen for maximum performance. For
CPython, it is suggested that the class instance be held in a C-level variable
on the function object which is bound to one of NULL
(not part of a class),
Py_None
(static method) or a class object (instance or class method).
Should super
actually become a keyword?
With this proposal, super
would become a keyword to the same extent that
None
is a keyword. It is possible that further restricting the super
name may simplify implementation, however some are against the actual keyword-
ization of super. The simplest solution is often the correct solution and the
simplest solution may well not be adding additional keywords to the language
when they are not needed. Still, it may solve other open issues.
Closed Issues
super used with __call__ attributes
It was considered that it might be a problem that instantiating super instances the classic way, because calling it would lookup the __call__ attribute and thus try to perform an automatic super lookup to the next class in the MRO. However, this was found to be false, because calling an object only looks up the __call__ method directly on the object’s type. The following example shows this in action.
class A(object):
def __call__(self):
return '__call__'
def __getattribute__(self, attr):
if attr == '__call__':
return lambda: '__getattribute__'
a = A()
assert a() == '__call__'
assert a.__call__() == '__getattribute__'
In any case, with the renaming of __builtin__.super
to
__builtin__.__super__
this issue goes away entirely.
Reference Implementation
It is impossible to implement the above specification entirely in Python. This reference implementation has the following differences to the specification:
- New
super
semantics are implemented using bytecode hacking. - Assignment to
super
is not aSyntaxError
. Also see point #4. - Classes must either use the metaclass
autosuper_meta
or inherit from the base classautosuper
to acquire the newsuper
semantics. super
is not an implicit local variable. In particular, for inner functions to be able to use the super instance, there must be an assignment of the formsuper = super
in the method.
The reference implementation assumes that it is being run on Python 2.5+.
#!/usr/bin/env python
#
# autosuper.py
from array import array
import dis
import new
import types
import __builtin__
__builtin__.__super__ = __builtin__.super
del __builtin__.super
# We need these for modifying bytecode
from opcode import opmap, HAVE_ARGUMENT, EXTENDED_ARG
LOAD_GLOBAL = opmap['LOAD_GLOBAL']
LOAD_NAME = opmap['LOAD_NAME']
LOAD_CONST = opmap['LOAD_CONST']
LOAD_FAST = opmap['LOAD_FAST']
LOAD_ATTR = opmap['LOAD_ATTR']
STORE_FAST = opmap['STORE_FAST']
LOAD_DEREF = opmap['LOAD_DEREF']
STORE_DEREF = opmap['STORE_DEREF']
CALL_FUNCTION = opmap['CALL_FUNCTION']
STORE_GLOBAL = opmap['STORE_GLOBAL']
DUP_TOP = opmap['DUP_TOP']
POP_TOP = opmap['POP_TOP']
NOP = opmap['NOP']
JUMP_FORWARD = opmap['JUMP_FORWARD']
ABSOLUTE_TARGET = dis.hasjabs
def _oparg(code, opcode_pos):
return code[opcode_pos+1] + (code[opcode_pos+2] << 8)
def _bind_autosuper(func, cls):
co = func.func_code
name = func.func_name
newcode = array('B', co.co_code)
codelen = len(newcode)
newconsts = list(co.co_consts)
newvarnames = list(co.co_varnames)
# Check if the global 'super' keyword is already present
try:
sn_pos = list(co.co_names).index('super')
except ValueError:
sn_pos = None
# Check if the varname 'super' keyword is already present
try:
sv_pos = newvarnames.index('super')
except ValueError:
sv_pos = None
# Check if the cellvar 'super' keyword is already present
try:
sc_pos = list(co.co_cellvars).index('super')
except ValueError:
sc_pos = None
# If 'super' isn't used anywhere in the function, we don't have anything to do
if sn_pos is None and sv_pos is None and sc_pos is None:
return func
c_pos = None
s_pos = None
n_pos = None
# Check if the 'cls_name' and 'super' objects are already in the constants
for pos, o in enumerate(newconsts):
if o is cls:
c_pos = pos
if o is __super__:
s_pos = pos
if o == name:
n_pos = pos
# Add in any missing objects to constants and varnames
if c_pos is None:
c_pos = len(newconsts)
newconsts.append(cls)
if n_pos is None:
n_pos = len(newconsts)
newconsts.append(name)
if s_pos is None:
s_pos = len(newconsts)
newconsts.append(__super__)
if sv_pos is None:
sv_pos = len(newvarnames)
newvarnames.append('super')
# This goes at the start of the function. It is:
#
# super = __super__(cls, self)
#
# If 'super' is a cell variable, we store to both the
# local and cell variables (i.e. STORE_FAST and STORE_DEREF).
#
preamble = [
LOAD_CONST, s_pos & 0xFF, s_pos >> 8,
LOAD_CONST, c_pos & 0xFF, c_pos >> 8,
LOAD_FAST, 0, 0,
CALL_FUNCTION, 2, 0,
]
if sc_pos is None:
# 'super' is not a cell variable - we can just use the local variable
preamble += [
STORE_FAST, sv_pos & 0xFF, sv_pos >> 8,
]
else:
# If 'super' is a cell variable, we need to handle LOAD_DEREF.
preamble += [
DUP_TOP,
STORE_FAST, sv_pos & 0xFF, sv_pos >> 8,
STORE_DEREF, sc_pos & 0xFF, sc_pos >> 8,
]
preamble = array('B', preamble)
# Bytecode for loading the local 'super' variable.
load_super = array('B', [
LOAD_FAST, sv_pos & 0xFF, sv_pos >> 8,
])
preamble_len = len(preamble)
need_preamble = False
i = 0
while i < codelen:
opcode = newcode[i]
need_load = False
remove_store = False
if opcode == EXTENDED_ARG:
raise TypeError("Cannot use 'super' in function with EXTENDED_ARG opcode")
# If the opcode is an absolute target it needs to be adjusted
# to take into account the preamble.
elif opcode in ABSOLUTE_TARGET:
oparg = _oparg(newcode, i) + preamble_len
newcode[i+1] = oparg & 0xFF
newcode[i+2] = oparg >> 8
# If LOAD_GLOBAL(super) or LOAD_NAME(super) then we want to change it into
# LOAD_FAST(super)
elif (opcode == LOAD_GLOBAL or opcode == LOAD_NAME) and _oparg(newcode, i) == sn_pos:
need_preamble = need_load = True
# If LOAD_FAST(super) then we just need to add the preamble
elif opcode == LOAD_FAST and _oparg(newcode, i) == sv_pos:
need_preamble = need_load = True
# If LOAD_DEREF(super) then we change it into LOAD_FAST(super) because
# it's slightly faster.
elif opcode == LOAD_DEREF and _oparg(newcode, i) == sc_pos:
need_preamble = need_load = True
if need_load:
newcode[i:i+3] = load_super
i += 1
if opcode >= HAVE_ARGUMENT:
i += 2
# No changes needed - get out.
if not need_preamble:
return func
# Our preamble will have 3 things on the stack
co_stacksize = max(3, co.co_stacksize)
# Conceptually, our preamble is on the `def` line.
co_lnotab = array('B', co.co_lnotab)
if co_lnotab:
co_lnotab[0] += preamble_len
co_lnotab = co_lnotab.tostring()
# Our code consists of the preamble and the modified code.
codestr = (preamble + newcode).tostring()
codeobj = new.code(co.co_argcount, len(newvarnames), co_stacksize,
co.co_flags, codestr, tuple(newconsts), co.co_names,
tuple(newvarnames), co.co_filename, co.co_name,
co.co_firstlineno, co_lnotab, co.co_freevars,
co.co_cellvars)
func.func_code = codeobj
func.func_class = cls
return func
class autosuper_meta(type):
def __init__(cls, name, bases, clsdict):
UnboundMethodType = types.UnboundMethodType
for v in vars(cls):
o = getattr(cls, v)
if isinstance(o, UnboundMethodType):
_bind_autosuper(o.im_func, cls)
class autosuper(object):
__metaclass__ = autosuper_meta
if __name__ == '__main__':
class A(autosuper):
def f(self):
return 'A'
class B(A):
def f(self):
return 'B' + super.f()
class C(A):
def f(self):
def inner():
return 'C' + super.f()
# Needed to put 'super' into a cell
super = super
return inner()
class D(B, C):
def f(self, arg=None):
var = None
return 'D' + super.f()
assert D().f() == 'DBCA'
Disassembly of B.f and C.f reveals the different preambles used when super
is simply a local variable compared to when it is used by an inner function.
>>> dis.dis(B.f)
214 0 LOAD_CONST 4 (<type 'super'>)
3 LOAD_CONST 2 (<class '__main__.B'>)
6 LOAD_FAST 0 (self)
9 CALL_FUNCTION 2
12 STORE_FAST 1 (super)
215 15 LOAD_CONST 1 ('B')
18 LOAD_FAST 1 (super)
21 LOAD_ATTR 1 (f)
24 CALL_FUNCTION 0
27 BINARY_ADD
28 RETURN_VALUE
>>> dis.dis(C.f)
218 0 LOAD_CONST 4 (<type 'super'>)
3 LOAD_CONST 2 (<class '__main__.C'>)
6 LOAD_FAST 0 (self)
9 CALL_FUNCTION 2
12 DUP_TOP
13 STORE_FAST 1 (super)
16 STORE_DEREF 0 (super)
219 19 LOAD_CLOSURE 0 (super)
22 LOAD_CONST 1 (<code object inner at 00C160A0, file "autosuper.py", line 219>)
25 MAKE_CLOSURE 0
28 STORE_FAST 2 (inner)
223 31 LOAD_FAST 1 (super)
34 STORE_DEREF 0 (super)
224 37 LOAD_FAST 2 (inner)
40 CALL_FUNCTION 0
43 RETURN_VALUE
Note that in the final implementation, the preamble would not be part of the bytecode of the method, but would occur immediately following unpacking of parameters.
Alternative Proposals
No Changes
Although its always attractive to just keep things how they are, people have sought a change in the usage of super calling for some time, and for good reason, all mentioned previously.
- Decoupling from the class name (which might not even be bound to the right class anymore!)
- Simpler looking, cleaner super calls would be better
Dynamic attribute on super type
The proposal adds a dynamic attribute lookup to the super type, which will automatically determine the proper class and instance parameters. Each super attribute lookup identifies these parameters and performs the super lookup on the instance, as the current super implementation does with the explicit invocation of a super instance upon a class and instance.
This proposal relies on sys._getframe(), which is not appropriate for anything except a prototype implementation.
super(__this_class__, self)
This is nearly an anti-proposal, as it basically relies on the acceptance of the __this_class__ PEP, which proposes a special name that would always be bound to the class within which it is used. If that is accepted, __this_class__ could simply be used instead of the class’ name explicitly, solving the name binding issues [2].
self.__super__.foo(*args)
The __super__ attribute is mentioned in this PEP in several places, and could be a candidate for the complete solution, actually using it explicitly instead of any super usage directly. However, double-underscore names are usually an internal detail, and attempted to be kept out of everyday code.
super(self, *args) or __super__(self, *args)
This solution only solves the problem of the type indication, does not handle differently named super methods, and is explicit about the name of the instance. It is less flexible without being able to enacted on other method names, in cases where that is needed. One use case this fails is where a base- class has a factory classmethod and a subclass has two factory classmethods, both of which needing to properly make super calls to the one in the base- class.
super.foo(self, *args)
This variation actually eliminates the problems with locating the proper instance, and if any of the alternatives were pushed into the spotlight, I would want it to be this one.
super or super()
This proposal leaves no room for different names, signatures, or application to other classes, or instances. A way to allow some similar use alongside the normal proposal would be favorable, encouraging good design of multiple inheritance trees and compatible methods.
super(*p, **kw)
There has been the proposal that directly calling super(*p, **kw)
would
be equivalent to calling the method on the super
object with the same name
as the method currently being executed i.e. the following two methods would be
equivalent:
def f(self, *p, **kw):
super.f(*p, **kw)
def f(self, *p, **kw):
super(*p, **kw)
There is strong sentiment for and against this, but implementation and style concerns are obvious. Guido has suggested that this should be excluded from this PEP on the principle of KISS (Keep It Simple Stupid).
History
- 29-Apr-2007 - Changed title from “Super As A Keyword” to “New Super”
- Updated much of the language and added a terminology section for clarification in confusing places.
- Added reference implementation and history sections.
- 06-May-2007 - Updated by Tim Delaney to reflect discussions on the python-3000
- and python-dev mailing lists.
References
- [1]
- Fixing super anyone? (https://mail.python.org/pipermail/python-3000/2007-April/006667.html)
- [2]
- PEP 3130: Access to Module/Class/Function Currently Being Defined (this) (https://mail.python.org/pipermail/python-ideas/2007-April/000542.html)
Copyright
This document has been placed in the public domain.
Source: https://github.com/python-discord/peps/blob/main/pep-0367.txt
Last modified: 2022-03-09 16:04:44 GMT