834 lines
33 KiB
ReStructuredText
834 lines
33 KiB
ReStructuredText
PEP: 577
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Title: Augmented Assignment Expressions
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Author: Nick Coghlan <ncoghlan@gmail.com>
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Status: Withdrawn
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Type: Standards Track
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Content-Type: text/x-rst
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Created: 14-May-2018
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Python-Version: 3.8
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Post-History: 22-May-2018
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PEP Withdrawal
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==============
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While working on this PEP, I realised that it didn't really address what was
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actually bothering me about :pep:`572`'s proposed scoping rules for previously
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unreferenced assignment targets, and also had some significant undesirable
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consequences (most notably, allowing ``>>=`` and ``<<=`` as inline augmented
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assignment operators that meant something entirely different from the ``>=``
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and ``<=`` comparison operators).
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I also realised that even without dedicated syntax of their own, :pep:`572`
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technically allows inline augmented assignments to be written using the
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``operator`` module::
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from operator import iadd
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if (target := iadd(target, value)) < limit:
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...
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The restriction to simple names as inline assignment targets means that the
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target expression can always be repeated without side effects, and thus avoids
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the ambiguity that would arise from allowing actual embedded augmented
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assignments (it's still a bad idea, since it would almost certainly be hard
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for humans to read, this note is just about the theoretical limits of language
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level expressiveness).
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Accordingly, I withdrew this PEP without submitting it for pronouncement. At
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the time I also started writing a replacement PEP that focused specifically on
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the handling of assignment targets which hadn't already been declared as local
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variables in the current scope (for both regular block scopes, and for scoped
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expressions), but that draft never even reached a stage where *I* liked it
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better than the ultimately accepted proposal in :pep:`572`, so it was never
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posted anywhere, nor assigned a PEP number.
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Abstract
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========
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This is a proposal to allow augmented assignments such as ``x += 1`` to be
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used as expressions, not just statements.
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As part of this, ``NAME := EXPR`` is proposed as an inline assignment expression
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that uses the new augmented assignment scoping rules, rather than implicitly
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defining a new local variable name the way that existing name binding
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statements do. The question of allowing expression level local variable
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declarations at function scope is deliberately separated from the question of
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allowing expression level name bindings, and deferred to a later PEP.
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This PEP is a direct competitor to :pep:`572` (although it borrows heavily from that
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PEP's motivation, and even shares the proposed syntax for inline assignments).
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See `Relationship with PEP 572`_ for more details on the connections between
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the two PEPs.
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To improve the usability of the new expressions, a semantic split is proposed
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between the handling of augmented assignments in regular block scopes (modules,
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classes, and functions), and the handling of augmented assignments in scoped
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expressions (lambda expressions, generator expressions, and comprehensions),
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such that all inline assignments default to targeting the nearest containing
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block scope.
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A new compile time ``TargetNameError`` is added as a subclass of ``SyntaxError``
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to handle cases where it is deemed to be currently unclear which target is
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expected to be rebound by an inline assignment, or else the target scope
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for the inline assignment is considered invalid for another reason.
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Syntax and semantics
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====================
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Augmented assignment expressions
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--------------------------------
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The language grammar would be adjusted to allow augmented assignments to
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appear as expressions, where the result of the augmented assignment
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expression is the same post-calculation reference as is being bound to the
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given target.
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For example::
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>>> n = 0
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>>> n += 5
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5
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>>> n -= 2
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3
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>>> n *= 3
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9
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>>> n
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9
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For mutable targets, this means the result is always just the original object::
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>>> seq = []
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>>> seq_id = id(seq)
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>>> seq += range(3)
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[0, 1, 2]
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>>> seq_id == id(seq)
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True
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Augmented assignments to attributes and container subscripts will be permitted,
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with the result being the post-calculation reference being bound to the target,
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just as it is for simple name targets::
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def increment(self, step=1):
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return self._value += step
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In these cases, ``__getitem__`` and ``__getattribute__`` will *not* be called
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after the assignment has already taken place (they will only be called as
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needed to evaluate the in-place operation).
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Adding an inline assignment operator
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------------------------------------
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Given only the addition of augmented assignment expressions, it would be
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possible to abuse a symbol like ``|=`` as a general purpose assignment
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operator by defining a ``Target`` wrapper type that worked as follows::
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>>> class Target:
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... def __init__(self, value):
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... self.value = value
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... def __or__(self, other):
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... return Target(other)
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...
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>>> x = Target(10)
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>>> x.value
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10
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>>> x |= 42
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<__main__.Target object at 0x7f608caa8048>
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>>> x.value
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42
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This is similar to the way that storing a single reference in a list was long
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used as a workaround for the lack of a ``nonlocal`` keyword, and can still be
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used today (in combination with ``operator.itemsetter``) to work around the
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lack of expression level assignments.
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Rather than requiring such workarounds, this PEP instead proposes that
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:pep:`572`'s "NAME := EXPR" syntax be adopted as a new inline assignment
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expression that uses the augmented assignment scoping rules described below.
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This cleanly handles cases where only the new value is of interest, and the
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previously bound value (if any) can just be discarded completely.
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Note that for both simple names and complex assignment targets, the inline
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assignment operator does *not* read the previous reference before assigning
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the new one. However, when used at function scope (either directly or inside
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a scoped expression), it does *not* implicitly define a new local variable,
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and will instead raise ``TargetNameError`` (as described for augmented
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assignments below).
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Assignment operator precedence
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------------------------------
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To preserve the existing semantics of augmented assignment statements,
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inline assignment operators will be defined as being of lower precedence
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than all other operators, include the comma pseudo-operator. This ensures
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that when used as a top level expression the entire right hand side of the
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expression is still interpreted as the value to be processed (even when that
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value is a tuple without parentheses).
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The difference this introduces relative to :pep:`572` is that where
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``(n := first, second)`` sets ``n = first`` in :pep:`572`, in this PEP it would set
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``n = (first, second)``, and getting the first meaning would require an extra
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set of parentheses (``((n := first), second)``).
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:pep:`572` quite reasonably notes that this results in ambiguity when assignment
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expressions are used as function call arguments. This PEP resolves that concern
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a different way by requiring that assignment expressions be parenthesised
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when used as arguments to a function call (unless they're the sole argument).
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This is a more relaxed version of the restriction placed on generator
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expressions (which always require parentheses, except when they're the sole
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argument to a function call).
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Augmented assignment to names in block scopes
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---------------------------------------------
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No target name binding changes are proposed for augmented assignments at module
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or class scope (this also includes code executed using "exec" or "eval"). These
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will continue to implicitly declare a new local variable as the binding target
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as they do today, and (if necessary) will be able to resolve the name from an
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outer scope before binding it locally.
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At function scope, augmented assignments will be changed to require that there
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be either a preceding name binding or variable declaration to explicitly
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establish the target name as being local to the function, or else an explicit
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``global`` or ``nonlocal`` declaration. ``TargetNameError``, a new
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``SyntaxError`` subclass, will be raised at compile time if no such binding or
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declaration is present.
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For example, the following code would compile and run as it does today::
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x = 0
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x += 1 # Sets global "x" to 1
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class C:
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x += 1 # Sets local "x" to 2, leaves global "x" alone
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def local_target():
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x = 0
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x += 1 # Sets local "x" to 1, leaves global "x" alone
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def global_target():
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global x
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x += 1 # Increments global "x" each time this runs
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def nonlocal_target():
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x = 0
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def g():
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nonlocal x
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x += 1 # Increments "x" in outer scope each time this runs
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return x
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return g
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The follow examples would all still compile and then raise an error at runtime
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as they do today::
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n += 1 # Raises NameError at runtime
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class C:
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n += 1 # Raises NameError at runtime
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def missing_global():
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global n
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n += 1 # Raises NameError at runtime
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def delayed_nonlocal_initialisation():
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def f():
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nonlocal n
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n += 1
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f() # Raises NameError at runtime
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n = 0
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def skipped_conditional_initialisation():
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if False:
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n = 0
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n += 1 # Raises UnboundLocalError at runtime
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def local_declaration_without_initial_assignment():
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n: typing.Any
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n += 1 # Raises UnboundLocalError at runtime
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Whereas the following would raise a compile time ``DeprecationWarning``
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initially, and eventually change to report a compile time ``TargetNameError``::
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def missing_target():
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x += 1 # Compile time TargetNameError due to ambiguous target scope
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# Is there a missing initialisation of "x" here? Or a missing
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# global or nonlocal declaration?
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As a conservative implementation approach, the compile time function name
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resolution change would be introduced as a ``DeprecationWarning`` in Python
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3.8, and then converted to ``TargetNameError`` in Python 3.9. This avoids
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potential problems in cases where an unused function would currently raise
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``UnboundLocalError`` if it was ever actually called, but the code is actually
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unused - converting that latent runtime defect to a compile time error qualifies
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as a backwards incompatible change that requires a deprecation period.
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When augmented assignments are used as expressions in function scope (rather
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than as standalone statements), there aren't any backwards compatibility
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concerns, so the compile time name binding checks would be enforced immediately
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in Python 3.8.
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Similarly, the new inline assignment expressions would always require explicit
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predeclaration of their target scope when used as part of a function, at least
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for Python 3.8. (See the design discussion section for notes on potentially
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revisiting that restriction in the future).
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Augmented assignment to names in scoped expressions
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---------------------------------------------------
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Scoped expressions is a new collective term being proposed for expressions that
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introduce a new nested scope of execution, either as an intrinsic part of their
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operation (lambda expressions, generator expressions), or else as a way of
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hiding name binding operations from the containing scope (container
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comprehensions).
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Unlike regular functions, these scoped expressions can't include explicit
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``global`` or ``nonlocal`` declarations to rebind names directly in an outer
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scope.
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Instead, their name binding semantics for augmented assignment expressions would
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be defined as follows:
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* augmented assignment targets used in scoped expressions are expected to either
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be already bound in the containing block scope, or else have their scope
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explicitly declared in the containing block scope. If no suitable name
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binding or declaration can be found in that scope, then ``TargetNameError``
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will be raised at compile time (rather than creating a new binding within
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the scoped expression).
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* if the containing block scope is a function scope, and the target name is
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explicitly declared as ``global`` or ``nonlocal``, then it will be use the
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same scope declaration in the body of the scoped expression
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* if the containing block scope is a function scope, and the target name is
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a local variable in that function, then it will be implicitly declared as
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``nonlocal`` in the body of the scoped expression
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* if the containing block scope is a class scope, than ``TargetNameError`` will
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always be raised, with a dedicated message indicating that combining class
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scopes with augmented assignments in scoped expressions is not currently
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permitted.
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* if a name is declared as a formal parameter (lambda expressions), or as an
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iteration variable (generator expressions, comprehensions), then that name
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is considered local to that scoped expression, and attempting to use it as
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the target of an augmented assignment operation in that scope, or any nested
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scoped expression, will raise ``TargetNameError`` (this is a restriction that
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could potentially be lifted later, but is being proposed for now to simplify
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the initial set of compile time and runtime semantics that needs to be
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covered in the language reference and handled by the compiler and interpreter)
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For example, the following code would work as shown::
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>>> global_target = 0
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>>> incr_global_target = lambda: global_target += 1
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>>> incr_global_target()
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1
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>>> incr_global_target()
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2
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>>> global_target
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2
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>>> def cumulative_sums(data, start=0)
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... total = start
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... yield from (total += value for value in data)
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... return total
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...
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>>> print(list(cumulative_sums(range(5))))
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[0, 1, 3, 6, 10]
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While the following examples would all raise ``TargetNameError``::
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class C:
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cls_target = 0
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incr_cls_target = lambda: cls_target += 1 # Error due to class scope
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def missing_target():
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incr_x = lambda: x += 1 # Error due to missing target "x"
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def late_target():
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incr_x = lambda: x += 1 # Error due to "x" being declared after use
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x = 1
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lambda arg: arg += 1 # Error due to attempt to target formal parameter
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[x += 1 for x in data] # Error due to attempt to target iteration variable
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As augmented assignments currently can't appear inside scoped expressions, the
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above compile time name resolution exceptions would be included as part of the
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initial implementation rather than needing to be phased in as a potentially
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backwards incompatible change.
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Design discussion
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=================
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Allowing complex assignment targets
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-----------------------------------
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The initial drafts of this PEP kept :pep:`572`'s restriction to single name targets
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when augmented assignments were used as expressions, allowing attribute and
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subscript targets solely for the statement form.
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However, enforcing that required varying the permitted targets based on whether
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or not the augmented assignment was a top level expression or not, as well as
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explaining why ``n += 1``, ``(n += 1)``, and ``self.n += 1`` were all legal,
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but ``(self.n += 1)`` was prohibited, so the proposal was simplified to allow
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all existing augmented assignment targets for the expression form as well.
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Since this PEP defines ``TARGET := EXPR`` as a variant on augmented assignment,
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that also gained support for assignment and subscript targets.
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Augmented assignment or name binding only?
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------------------------------------------
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:pep:`572` makes a reasonable case that the potential use cases for inline
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augmented assignment are notably weaker than those for inline assignment in
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general, so it's acceptable to require that they be spelled as ``x := x + 1``,
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bypassing any in-place augmented assignment methods.
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While this is at least arguably true for the builtin types (where potential
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counterexamples would probably need to focus on set manipulation use cases
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that the PEP author doesn't personally have), it would also rule out more
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memory intensive use cases like manipulation of NumPy arrays, where the data
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copying involved in out-of-place operations can make them impractical as
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alternatives to their in-place counterparts.
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That said, this PEP mainly exists because the PEP author found the inline
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assignment proposal much easier to grasp as "It's like ``+=``, only skipping
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the addition step", and also liked the way that that framing provides an
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actual semantic difference between ``NAME = EXPR`` and ``NAME := EXPR`` at
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function scope.
|
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That difference in target scoping behaviour means that the ``NAME := EXPR``
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syntax would be expected to have two primary use cases:
|
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* as a way of allowing assignments to be embedded as an expression in an ``if``
|
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or ``while`` statement, or as part of a scoped expression
|
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* as a way of requesting a compile time check that the target name be previously
|
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declared or bound in the current function scope
|
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|
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At module or class scope, ``NAME = EXPR`` and ``NAME := EXPR`` would be
|
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semantically equivalent due to the compiler's lack of visibility into the set
|
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of names that will be resolvable at runtime, but code linters and static
|
||
type checkers would be encouraged to enforce the same "declaration or assignment
|
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required before use" behaviour for ``NAME := EXPR`` as the compiler would
|
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enforce at function scope.
|
||
|
||
|
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Postponing a decision on expression level target declarations
|
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-------------------------------------------------------------
|
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|
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At least for Python 3.8, usage of inline assignments (whether augmented or not)
|
||
at function scope would always require a preceding name binding or scope
|
||
declaration to avoid getting ``TargetNameError``, even when used outside a
|
||
scoped expression.
|
||
|
||
The intent behind this requirement is to clearly separate the following two
|
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language design questions:
|
||
|
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1. Can an expression rebind a name in the current scope?
|
||
2. Can an expression declare a new name in the current scope?
|
||
|
||
For module global scopes, the answer to both of those questions is unequivocally
|
||
"Yes", because it's a language level guarantee that mutating the ``globals()``
|
||
dict will immediately impact the runtime module scope, and ``global NAME``
|
||
declarations inside a function can have the same effect (as can importing the
|
||
currently executing module and modifying its attributes).
|
||
|
||
For class scopes, the answer to both questions is also "Yes" in practice,
|
||
although less unequivocally so, since the semantics of ``locals()`` are
|
||
currently formally unspecified. However, if the current behaviour of ``locals()``
|
||
at class scope is taken as normative (as :pep:`558` proposes), then this is
|
||
essentially the same scenario as manipulating the module globals, just using
|
||
``locals()`` instead.
|
||
|
||
For function scopes, however, the current answers to these two questions are
|
||
respectively "Yes" and "No". Expression level rebinding of function locals is
|
||
already possible thanks to lexically nested scopes and explicit ``nonlocal NAME``
|
||
expressions. While this PEP will likely make expression level rebinding more
|
||
common than it is today, it isn't a fundamentally new concept for the language.
|
||
|
||
By contrast, declaring a *new* function local variable is currently a statement
|
||
level action, involving one of:
|
||
|
||
* an assignment statement (``NAME = EXPR``, ``OTHER_TARGET = NAME = EXPR``, etc)
|
||
* a variable declaration (``NAME : EXPR``)
|
||
* a nested function definition
|
||
* a nested class definition
|
||
* a ``for`` loop
|
||
* a ``with`` statement
|
||
* an ``except`` clause (with limited scope of access)
|
||
|
||
The historical trend for the language has actually been to *remove* support for
|
||
expression level declarations of function local names, first with the
|
||
introduction of "fast locals" semantics (which made the introduction of names
|
||
via ``locals()`` unsupported for function scopes), and again with the hiding
|
||
of comprehension iteration variables in Python 3.0.
|
||
|
||
Now, it may be that in Python 3.9, we decide to revisit this question based on
|
||
our experience with expression level name binding in Python 3.8, and decide that
|
||
we really do want expression level function local variable declarations as well,
|
||
and that we want ``NAME := EXPR`` to be the way we spell that (rather than,
|
||
for example, spelling inline declarations more explicitly as
|
||
``NAME := EXPR given NAME``, which would permit them to carry type annotations,
|
||
and also permit them to declare new local variables in scoped expressions,
|
||
rather than having to pollute the namespace in their containing scope).
|
||
|
||
But the proposal in this PEP is that we explicitly give ourselves a full
|
||
release to decide how much we want that feature, and exactly where we find
|
||
its absence irritating. Python has survived happily without expression level
|
||
name bindings *or* declarations for decades, so we can afford to give ourselves
|
||
a couple of years to decide if we really want *both* of those, or if expression
|
||
level bindings are sufficient.
|
||
|
||
|
||
Ignoring scoped expressions when determining augmented assignment targets
|
||
-------------------------------------------------------------------------
|
||
|
||
When discussing possible binding semantics for :pep:`572`'s assignment expressions,
|
||
Tim Peters made a plausible case [1_,2_,3_] for assignment expressions targeting
|
||
the containing block scope, essentially ignoring any intervening scoped
|
||
expressions.
|
||
|
||
This approach allows use cases like cumulative sums, or extracting the final
|
||
value from a generator expression to be written in a relatively straightforward
|
||
way::
|
||
|
||
total = 0
|
||
partial_sums = [total := total + value for value in data]
|
||
|
||
factor = 1
|
||
while any(n % (factor := p) == 0 for p in small_primes):
|
||
n //= factor
|
||
|
||
Guido also expressed his approval for this general approach [4_].
|
||
|
||
The proposal in this PEP differs from Tim's original proposal in three main
|
||
areas:
|
||
|
||
- it applies the proposal to all augmented assignment operators, not just a
|
||
single new name binding operator
|
||
- as far as is practical, it extends the augmented assignment requirement that
|
||
the name already be defined to the new name binding operator (raising
|
||
``TargetNameError`` rather than implicitly declaring new local variables at
|
||
function scope)
|
||
- it includes lambda expressions in the set of scopes that get ignored for
|
||
target name binding purposes, making this transparency to assignments common
|
||
to all of the scoped expressions rather than being specific to comprehensions
|
||
and generator expressions
|
||
|
||
With scoped expressions being ignored when calculating binding targets, it's
|
||
once again difficult to detect the scoping difference between the outermost
|
||
iterable expressions in generator expressions and comprehensions (you have to
|
||
mess about with either class scopes or attempting to rebind iteration Variables
|
||
to detect it), so there's also no need to tinker with that.
|
||
|
||
|
||
Treating inline assignment as an augmented assignment variant
|
||
-------------------------------------------------------------
|
||
|
||
One of the challenges with :pep:`572` is the fact that ``NAME = EXPR`` and
|
||
``NAME := EXPR`` are entirely semantically equivalent at every scope. This
|
||
makes the two forms hard to teach, since there's no inherent nudge towards
|
||
choosing one over the other at the statement level, so you end up having to
|
||
resort to "``NAME = EXPR`` is preferred because it's been around longer"
|
||
(and :pep:`572` proposes to enfore that historical idiosyncrasy at the compiler
|
||
level).
|
||
|
||
That semantic equivalence is difficult to avoid at module and class scope while
|
||
still having ``if NAME := EXPR:`` and ``while NAME := EXPR:`` work sensibly, but
|
||
at function scope the compiler's comprehensive view of all local names makes
|
||
it possible to require that the name be assigned or declared before use,
|
||
providing a reasonable incentive to continue to default to using the
|
||
``NAME = EXPR`` form when possible, while also enabling the use of the
|
||
``NAME := EXPR`` as a kind of simple compile time assertion (i.e. explicitly
|
||
indicating that the targeted name has already been bound or declared and hence
|
||
should already be known to the compiler).
|
||
|
||
If Guido were to declare that support for inline declarations was a hard
|
||
design requirement, then this PEP would be updated to propose that
|
||
``EXPR given NAME`` also be introduced as a way to support inline name declarations
|
||
after arbitrary expressions (this would allow the inline name declarations to be
|
||
deferred until the end of a complex expression rather than needing to be
|
||
embedded in the middle of it, and :pep:`8` would gain a recommendation encouraging
|
||
that style).
|
||
|
||
|
||
Disallowing augmented assignments in class level scoped expressions
|
||
-------------------------------------------------------------------
|
||
|
||
While modern classes do define an implicit closure that's visible to method
|
||
implementations (in order to make ``__class__`` available for use in zero-arg
|
||
``super()`` calls), there's no way for user level code to explicitly add
|
||
additional names to that scope.
|
||
|
||
Meanwhile, attributes defined in a class body are ignored for the purpose of
|
||
defining a method's lexical closure, which means adding them there wouldn't
|
||
work at an implementation level.
|
||
|
||
Rather than trying to resolve that inherent ambiguity, this PEP simply
|
||
prohibits such usage, and requires that any affected logic be written somewhere
|
||
other than directly inline in the class body (e.g. in a separate helper
|
||
function).
|
||
|
||
|
||
Comparison operators vs assignment operators
|
||
--------------------------------------------
|
||
|
||
The ``OP=`` construct as an expression currently indicates a comparison
|
||
operation::
|
||
|
||
x == y # Equals
|
||
x >= y # Greater-than-or-equal-to
|
||
x <= y # Less-than-or-equal-to
|
||
|
||
Both this PEP and :pep:`572` propose adding at least one operator that's somewhat
|
||
similar in appearance, but defines an assignment instead::
|
||
|
||
x := y # Becomes
|
||
|
||
This PEP then goes much further and allows all *13* augmented assignment symbols
|
||
to be uses as binary operators::
|
||
|
||
x += y # In-place add
|
||
x -= y # In-place minus
|
||
x *= y # In-place multiply
|
||
x @= y # In-place matrix multiply
|
||
x /= y # In-place division
|
||
x //= y # In-place int division
|
||
x %= y # In-place mod
|
||
x &= y # In-place bitwise and
|
||
x |= y # In-place bitwise or
|
||
x ^= y # In-place bitwise xor
|
||
x <<= y # In-place left shift
|
||
x >>= y # In-place right shift
|
||
x **= y # In-place power
|
||
|
||
Of those additional binary operators, the most questionable would be the
|
||
bitshift assignment operators, since they're each only one doubled character
|
||
away from one of the inclusive ordered comparison operators.
|
||
|
||
|
||
Examples
|
||
========
|
||
|
||
Simplifying retry loops
|
||
-----------------------
|
||
|
||
There are currently a few different options for writing retry loops, including::
|
||
|
||
# Post-decrementing a counter
|
||
remaining_attempts = MAX_ATTEMPTS
|
||
while remaining_attempts:
|
||
remaining_attempts -= 1
|
||
try:
|
||
result = attempt_operation()
|
||
except Exception as exc:
|
||
continue # Failed, so try again
|
||
log.debug(f"Succeeded after {attempts} attempts")
|
||
break # Success!
|
||
else:
|
||
raise OperationFailed(f"Failed after {MAX_ATTEMPTS} attempts") from exc
|
||
|
||
# Loop-and-a-half with a pre-incremented counter
|
||
attempt = 0
|
||
while True:
|
||
attempts += 1
|
||
if attempts > MAX_ATTEMPTS:
|
||
raise OperationFailed(f"Failed after {MAX_ATTEMPTS} attempts") from exc
|
||
try:
|
||
result = attempt_operation()
|
||
except Exception as exc:
|
||
continue # Failed, so try again
|
||
log.debug(f"Succeeded after {attempts} attempts")
|
||
break # Success!
|
||
|
||
Each of the available options hides some aspect of the intended loop structure
|
||
inside the loop body, whether that's the state modification, the exit condition,
|
||
or both.
|
||
|
||
The proposal in this PEP allows both the state modification and the exit
|
||
condition to be included directly in the loop header::
|
||
|
||
attempt = 0
|
||
while (attempt += 1) <= MAX_ATTEMPTS:
|
||
try:
|
||
result = attempt_operation()
|
||
except Exception as exc:
|
||
continue # Failed, so try again
|
||
log.debug(f"Succeeded after {attempts} attempts")
|
||
break # Success!
|
||
else:
|
||
raise OperationFailed(f"Failed after {MAX_ATTEMPTS} attempts") from exc
|
||
|
||
|
||
Simplifying if-elif chains
|
||
--------------------------
|
||
|
||
if-elif chains that need to rebind the checked condition currently need to
|
||
be written using nested if-else statements::
|
||
|
||
|
||
m = pattern.match(data)
|
||
if m:
|
||
...
|
||
else:
|
||
m = other_pattern.match(data)
|
||
if m:
|
||
...
|
||
else:
|
||
m = yet_another_pattern.match(data)
|
||
if m:
|
||
...
|
||
else:
|
||
...
|
||
|
||
As with :pep:`572`, this PEP allows the else/if portions of that chain to be
|
||
condensed, making their consistent and mutually exclusive structure more
|
||
readily apparent::
|
||
|
||
m = pattern.match(data)
|
||
if m:
|
||
...
|
||
elif m := other_pattern.match(data):
|
||
...
|
||
elif m := yet_another_pattern.match(data):
|
||
...
|
||
else:
|
||
...
|
||
|
||
Unlike :pep:`572`, this PEP requires that the assignment target be explicitly
|
||
indicated as local before the first use as a ``:=`` target, either by
|
||
binding it to a value (as shown above), or else by including an appropriate
|
||
explicit type declaration::
|
||
|
||
m: typing.re.Match
|
||
if m := pattern.match(data):
|
||
...
|
||
elif m := other_pattern.match(data):
|
||
...
|
||
elif m := yet_another_pattern.match(data):
|
||
...
|
||
else:
|
||
...
|
||
|
||
|
||
Capturing intermediate values from comprehensions
|
||
-------------------------------------------------
|
||
|
||
The proposal in this PEP makes it straightforward to capture and reuse
|
||
intermediate values in comprehensions and generator expressions by
|
||
exporting them to the containing block scope::
|
||
|
||
factor: int
|
||
while any(n % (factor := p) == 0 for p in small_primes):
|
||
n //= factor
|
||
|
||
total = 0
|
||
partial_sums = [total += value for value in data]
|
||
|
||
|
||
Allowing lambda expressions to act more like re-usable code thunks
|
||
------------------------------------------------------------------
|
||
|
||
This PEP allows the classic closure usage example::
|
||
|
||
def make_counter(start=0):
|
||
x = start
|
||
def counter(step=1):
|
||
nonlocal x
|
||
x += step
|
||
return x
|
||
return counter
|
||
|
||
To be abbreviated as::
|
||
|
||
def make_counter(start=0):
|
||
x = start
|
||
return lambda step=1: x += step
|
||
|
||
While the latter form is still a conceptually dense piece of code, it can be
|
||
reasonably argued that the lack of boilerplate (where the "def", "nonlocal",
|
||
and "return" keywords and two additional repetitions of the "x" variable name
|
||
have been replaced with the "lambda" keyword) may make it easier to read in
|
||
practice.
|
||
|
||
|
||
Relationship with PEP 572
|
||
=========================
|
||
|
||
The case for allowing inline assignments at all is made in :pep:`572`. This
|
||
competing PEP was initially going to propose an alternate surface syntax
|
||
(``EXPR given NAME = EXPR``), while retaining the expression semantics from
|
||
:pep:`572`, but that changed when discussing one of the initial motivating use
|
||
cases for allowing embedded assignments at all: making it possible to easily
|
||
calculate cumulative sums in comprehensions and generator expressions.
|
||
|
||
As a result of that, and unlike :pep:`572`, this PEP focuses primarily on use
|
||
cases for inline augmented assignment. It also has the effect of converting
|
||
cases that currently inevitably raise ``UnboundLocalError`` at function call
|
||
time to report a new compile time ``TargetNameError``.
|
||
|
||
New syntax for a name rebinding expression (``NAME := TARGET``) is then added
|
||
not only to handle the same use cases as are identified in :pep:`572`, but also
|
||
as a lower level primitive to help illustrate, implement and explain
|
||
the new augmented assignment semantics, rather than being the sole change being
|
||
proposed.
|
||
|
||
The author of this PEP believes that this approach makes the value of the new
|
||
flexibility in name rebinding clearer, while also mitigating many of the
|
||
potential concerns raised with :pep:`572` around explaining when to use
|
||
``NAME = EXPR`` over ``NAME := EXPR`` (and vice-versa), without resorting to
|
||
prohibiting the bare statement form of ``NAME := EXPR`` outright (such
|
||
that ``NAME := EXPR`` is a compile error, but ``(NAME := EXPR)`` is permitted).
|
||
|
||
|
||
Acknowledgements
|
||
================
|
||
|
||
The PEP author wishes to thank Chris Angelico for his work on :pep:`572`, and his
|
||
efforts to create a coherent summary of the great many sprawling discussions
|
||
that spawned on both python-ideas and python-dev, as well as Tim Peters for
|
||
the in-depth discussion of parent local scoping that prompted the above
|
||
scoping proposal for augmented assignments inside scoped expressions.
|
||
|
||
Eric Snow's feedback on a pre-release version of this PEP helped make it
|
||
significantly more readable.
|
||
|
||
|
||
References
|
||
==========
|
||
|
||
.. [1] The beginning of Tim's genexp & comprehension scoping thread
|
||
(https://mail.python.org/pipermail/python-ideas/2018-May/050367.html)
|
||
|
||
.. [2] Reintroducing the original cumulative sums use case
|
||
(https://mail.python.org/pipermail/python-ideas/2018-May/050544.html)
|
||
|
||
.. [3] Tim's language reference level explanation of his proposed scoping semantics
|
||
(https://mail.python.org/pipermail/python-ideas/2018-May/050729.html)
|
||
|
||
.. [4] Guido's endorsement of Tim's proposed genexp & comprehension scoping
|
||
(https://mail.python.org/pipermail/python-ideas/2018-May/050411.html)
|
||
|
||
|
||
Copyright
|
||
=========
|
||
|
||
This document has been placed in the public domain.
|
||
|
||
|
||
|
||
..
|
||
Local Variables:
|
||
mode: indented-text
|
||
indent-tabs-mode: nil
|
||
sentence-end-double-space: t
|
||
fill-column: 70
|
||
coding: utf-8
|
||
End:
|