python-peps/peps/pep-0533.rst

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PEP: 533
Title: Deterministic cleanup for iterators
Version: $Revision$
Last-Modified: $Date$
Author: Nathaniel J. Smith
BDFL-Delegate: Yury Selivanov <yury@edgedb.com>
Status: Deferred
Type: Standards Track
Content-Type: text/x-rst
Created: 18-Oct-2016
Post-History: 18-Oct-2016
Abstract
========
We propose to extend the iterator protocol with a new
``__(a)iterclose__`` slot, which is called automatically on exit from
``(async) for`` loops, regardless of how they exit. This allows for
convenient, deterministic cleanup of resources held by iterators
without reliance on the garbage collector. This is especially valuable
for asynchronous generators.
Note on timing
==============
In practical terms, the proposal here is divided into two separate
parts: the handling of async iterators, which should ideally be
implemented ASAP, and the handling of regular iterators, which is a
larger but more relaxed project that can't start until 3.7 at the
earliest. But since the changes are closely related, and we probably
don't want to end up with async iterators and regular iterators
diverging in the long run, it seems useful to look at them together.
Background and motivation
=========================
Python iterables often hold resources which require cleanup. For
example: ``file`` objects need to be closed; the :pep:`WSGI spec
<333>` adds a ``close`` method
on top of the regular iterator protocol and demands that consumers
call it at the appropriate time (though forgetting to do so is a
`frequent source of bugs
<http://blog.dscpl.com.au/2012/10/obligations-for-calling-close-on.html>`_);
and :pep:`342` (based on :pep:`325`) extended generator objects to add a
``close`` method to allow generators to clean up after themselves.
Generally, objects that need to clean up after themselves also define
a ``__del__`` method to ensure that this cleanup will happen
eventually, when the object is garbage collected. However, relying on
the garbage collector for cleanup like this causes serious problems in
several cases:
- In Python implementations that do not use reference counting
(e.g. PyPy, Jython), calls to ``__del__`` may be arbitrarily delayed
-- yet many situations require *prompt* cleanup of
resources. Delayed cleanup produces problems like crashes due to
file descriptor exhaustion, or WSGI timing middleware that collects
bogus times.
- Async generators (:pep:`525`) can only perform cleanup under the
supervision of the appropriate coroutine runner. ``__del__`` doesn't
have access to the coroutine runner; indeed, the coroutine runner
might be garbage collected before the generator object. So relying
on the garbage collector is effectively impossible without some kind
of language extension. (:pep:`525` does provide such an extension, but
it has a number of limitations that this proposal fixes; see the
"alternatives" section below for discussion.)
.. XX add discussion of:
- Causality preservation, context preservation
- Exception swallowing
Fortunately, Python provides a standard tool for doing resource
cleanup in a more structured way: ``with`` blocks. For example, this
code opens a file but relies on the garbage collector to close it::
def read_newline_separated_json(path):
for line in open(path):
yield json.loads(line)
for document in read_newline_separated_json(path):
...
and recent versions of CPython will point this out by issuing a
``ResourceWarning``, nudging us to fix it by adding a ``with`` block::
def read_newline_separated_json(path):
with open(path) as file_handle: # <-- with block
for line in file_handle:
yield json.loads(line)
for document in read_newline_separated_json(path): # <-- outer for loop
...
But there's a subtlety here, caused by the interaction of ``with``
blocks and generators. ``with`` blocks are Python's main tool for
managing cleanup, and they're a powerful one, because they pin the
lifetime of a resource to the lifetime of a stack frame. But this
assumes that someone will take care of cleaning up the stack
frame... and for generators, this requires that someone ``close``
them.
In this case, adding the ``with`` block *is* enough to shut up the
``ResourceWarning``, but this is misleading -- the file object cleanup
here is still dependent on the garbage collector. The ``with`` block
will only be unwound when the ``read_newline_separated_json``
generator is closed. If the outer ``for`` loop runs to completion then
the cleanup will happen immediately; but if this loop is terminated
early by a ``break`` or an exception, then the ``with`` block won't
fire until the generator object is garbage collected.
The correct solution requires that all *users* of this API wrap every
``for`` loop in its own ``with`` block::
with closing(read_newline_separated_json(path)) as genobj:
for document in genobj:
...
This gets even worse if we consider the idiom of decomposing a complex
pipeline into multiple nested generators::
def read_users(path):
with closing(read_newline_separated_json(path)) as gen:
for document in gen:
yield User.from_json(document)
def users_in_group(path, group):
with closing(read_users(path)) as gen:
for user in gen:
if user.group == group:
yield user
In general if you have N nested generators then you need N+1 ``with``
blocks to clean up 1 file. And good defensive programming would
suggest that any time we use a generator, we should assume the
possibility that there could be at least one ``with`` block somewhere
in its (potentially transitive) call stack, either now or in the
future, and thus always wrap it in a ``with``. But in practice,
basically nobody does this, because programmers would rather write
buggy code than tiresome repetitive code. In simple cases like this
there are some workarounds that good Python developers know (e.g. in
this simple case it would be idiomatic to pass in a file handle
instead of a path and move the resource management to the top level),
but in general we cannot avoid the use of ``with``/``finally`` inside
of generators, and thus dealing with this problem one way or
another. When beauty and correctness fight then beauty tends to win,
so it's important to make correct code beautiful.
Still, is this worth fixing? Until async generators came along I would
have argued yes, but that it was a low priority, since everyone seems
to be muddling along okay -- but async generators make it much more
urgent. Async generators cannot do cleanup *at all* without some
mechanism for deterministic cleanup that people will actually use, and
async generators are particularly likely to hold resources like file
descriptors. (After all, if they weren't doing I/O, they'd be
generators, not async generators.) So we have to do something, and it
might as well be a comprehensive fix to the underlying problem. And
it's much easier to fix this now when async generators are first
rolling out, than it will be to fix it later.
The proposal itself is simple in concept: add a ``__(a)iterclose__``
method to the iterator protocol, and have (async) ``for`` loops call
it when the loop is exited, even if this occurs via ``break`` or
exception unwinding. Effectively, we're taking the current cumbersome
idiom (``with`` block + ``for`` loop) and merging them together into a
fancier ``for``. This may seem non-orthogonal, but makes sense when
you consider that the existence of generators means that ``with``
blocks actually depend on iterator cleanup to work reliably, plus
experience showing that iterator cleanup is often a desirable feature
in its own right.
Alternatives
============
PEP 525 asyncgen hooks
----------------------
:pep:`PEP 525 proposes a set of global thread-local hooks
<525#finalization>`
managed by new ``sys.{get/set}_asyncgen_hooks()`` functions, which
allow event loops to integrate with the garbage collector to run
cleanup for async generators. In principle, this proposal and :pep:`525`
are complementary, in the same way that ``with`` blocks and
``__del__`` are complementary: this proposal takes care of ensuring
deterministic cleanup in most cases, while :pep:`525`'s GC hooks clean up
anything that gets missed. But ``__aiterclose__`` provides a number of
advantages over GC hooks alone:
- The GC hook semantics aren't part of the abstract async iterator
protocol, but are instead restricted `specifically to the async
generator concrete type
<https://mail.python.org/pipermail/python-dev/2016-September/146129.html>`_. If
you have an async iterator implemented using a class, like::
class MyAsyncIterator:
async def __anext__():
...
then you can't refactor this into an async generator without
changing its semantics, and vice-versa. This seems very
unpythonic. (It also leaves open the question of what exactly
class-based async iterators are supposed to do, given that they face
exactly the same cleanup problems as async generators.)
``__aiterclose__``, on the other hand, is defined at the protocol
level, so it's duck-type friendly and works for all iterators, not
just generators.
- Code that wants to work on non-CPython implementations like PyPy
cannot in general rely on GC for cleanup. Without
``__aiterclose__``, it's more or less guaranteed that developers who
develop and test on CPython will produce libraries that leak
resources when used on PyPy. Developers who do want to target
alternative implementations will either have to take the defensive
approach of wrapping every ``for`` loop in a ``with`` block, or else
carefully audit their code to figure out which generators might
possibly contain cleanup code and add ``with`` blocks around those
only. With ``__aiterclose__``, writing portable code becomes easy
and natural.
- An important part of building robust software is making sure that
exceptions always propagate correctly without being lost. One of the
most exciting things about async/await compared to traditional
callback-based systems is that instead of requiring manual chaining,
the runtime can now do the heavy lifting of propagating errors,
making it *much* easier to write robust code. But, this beautiful
new picture has one major gap: if we rely on the GC for generator
cleanup, then exceptions raised during cleanup are lost. So, again,
with ``__aiterclose__``, developers who care about this kind of
robustness will either have to take the defensive approach of
wrapping every ``for`` loop in a ``with`` block, or else carefully
audit their code to figure out which generators might possibly
contain cleanup code. ``__aiterclose__`` plugs this hole by
performing cleanup in the caller's context, so writing more robust
code becomes the path of least resistance.
- The WSGI experience suggests that there exist important
iterator-based APIs that need prompt cleanup and cannot rely on the
GC, even in CPython. For example, consider a hypothetical WSGI-like
API based around async/await and async iterators, where a response
handler is an async generator that takes request headers + an async
iterator over the request body, and yields response headers + the
response body. (This is actually the use case that got me interested
in async generators in the first place, i.e. this isn't
hypothetical.) If we follow WSGI in requiring that child iterators
must be closed properly, then without ``__aiterclose__`` the
absolute most minimalistic middleware in our system looks something
like::
async def noop_middleware(handler, request_header, request_body):
async with aclosing(handler(request_body, request_body)) as aiter:
async for response_item in aiter:
yield response_item
Arguably in regular code one can get away with skipping the ``with``
block around ``for`` loops, depending on how confident one is that
one understands the internal implementation of the generator. But
here we have to cope with arbitrary response handlers, so without
``__aiterclose__``, this ``with`` construction is a mandatory part
of every middleware.
``__aiterclose__`` allows us to eliminate the mandatory boilerplate
and an extra level of indentation from every middleware::
async def noop_middleware(handler, request_header, request_body):
async for response_item in handler(request_header, request_body):
yield response_item
So the ``__aiterclose__`` approach provides substantial advantages
over GC hooks.
This leaves open the question of whether we want a combination of GC
hooks + ``__aiterclose__``, or just ``__aiterclose__`` alone. Since
the vast majority of generators are iterated over using a ``for`` loop
or equivalent, ``__aiterclose__`` handles most situations before the
GC has a chance to get involved. The case where GC hooks provide
additional value is in code that does manual iteration, e.g.::
agen = fetch_newline_separated_json_from_url(...)
while True:
document = await type(agen).__anext__(agen)
if document["id"] == needle:
break
# doesn't do 'await agen.aclose()'
If we go with the GC-hooks + ``__aiterclose__`` approach, this
generator will eventually be cleaned up by GC calling the generator
``__del__`` method, which then will use the hooks to call back into
the event loop to run the cleanup code.
If we go with the no-GC-hooks approach, this generator will eventually
be garbage collected, with the following effects:
- its ``__del__`` method will issue a warning that the generator was
not closed (similar to the existing "coroutine never awaited"
warning).
- The underlying resources involved will still be cleaned up, because
the generator frame will still be garbage collected, causing it to
drop references to any file handles or sockets it holds, and then
those objects's ``__del__`` methods will release the actual
operating system resources.
- But, any cleanup code inside the generator itself (e.g. logging,
buffer flushing) will not get a chance to run.
The solution here -- as the warning would indicate -- is to fix the
code so that it calls ``__aiterclose__``, e.g. by using a ``with``
block::
async with aclosing(fetch_newline_separated_json_from_url(...)) as agen:
while True:
document = await type(agen).__anext__(agen)
if document["id"] == needle:
break
Basically in this approach, the rule would be that if you want to
manually implement the iterator protocol, then it's your
responsibility to implement all of it, and that now includes
``__(a)iterclose__``.
GC hooks add non-trivial complexity in the form of (a) new global
interpreter state, (b) a somewhat complicated control flow (e.g.,
async generator GC always involves resurrection, so the details of PEP
442 are important), and (c) a new public API in asyncio (``await
loop.shutdown_asyncgens()``) that users have to remember to call at
the appropriate time. (This last point in particular somewhat
undermines the argument that GC hooks provide a safe backup to
guarantee cleanup, since if ``shutdown_asyncgens()`` isn't called
correctly then I *think* it's possible for generators to be silently
discarded without their cleanup code being called; compare this to the
``__aiterclose__``-only approach where in the worst case we still at
least get a warning printed. This might be fixable.) All this
considered, GC hooks arguably aren't worth it, given that the only
people they help are those who want to manually call ``__anext__`` yet
don't want to manually call ``__aiterclose__``. But Yury disagrees
with me on this :-). And both options are viable.
Always inject resources, and do all cleanup at the top level
------------------------------------------------------------
Several commentators on python-dev and python-ideas have suggested
that a pattern to avoid these problems is to always pass resources in
from above, e.g. ``read_newline_separated_json`` should take a file
object rather than a path, with cleanup handled at the top level::
def read_newline_separated_json(file_handle):
for line in file_handle:
yield json.loads(line)
def read_users(file_handle):
for document in read_newline_separated_json(file_handle):
yield User.from_json(document)
with open(path) as file_handle:
for user in read_users(file_handle):
...
This works well in simple cases; here it lets us avoid the "N+1
``with`` blocks problem". But unfortunately, it breaks down quickly
when things get more complex. Consider if instead of reading from a
file, our generator was reading from a streaming HTTP GET request --
while handling redirects and authentication via OAUTH. Then we'd
really want the sockets to be managed down inside our HTTP client
library, not at the top level. Plus there are other cases where
``finally`` blocks embedded inside generators are important in their
own right: db transaction management, emitting logging information
during cleanup (one of the major motivating use cases for WSGI
``close``), and so forth. So this is really a workaround for simple
cases, not a general solution.
More complex variants of __(a)iterclose__
-----------------------------------------
The semantics of ``__(a)iterclose__`` are somewhat inspired by
``with`` blocks, but context managers are more powerful:
``__(a)exit__`` can distinguish between a normal exit versus exception
unwinding, and in the case of an exception it can examine the
exception details and optionally suppress
propagation. ``__(a)iterclose__`` as proposed here does not have these
powers, but one can imagine an alternative design where it did.
However, this seems like unwarranted complexity: experience suggests
that it's common for iterables to have ``close`` methods, and even to
have ``__exit__`` methods that call ``self.close()``, but I'm not
aware of any common cases that make use of ``__exit__``'s full
power. I also can't think of any examples where this would be
useful. And it seems unnecessarily confusing to allow iterators to
affect flow control by swallowing exceptions -- if you're in a
situation where you really want that, then you should probably use a
real ``with`` block anyway.
Specification
=============
This section describes where we want to eventually end up, though
there are some backwards compatibility issues that mean we can't jump
directly here. A later section describes the transition plan.
Guiding principles
------------------
Generally, ``__(a)iterclose__`` implementations should:
- be idempotent,
- perform any cleanup that is appropriate on the assumption that the
iterator will not be used again after ``__(a)iterclose__`` is
called. In particular, once ``__(a)iterclose__`` has been called
then calling ``__(a)next__`` produces undefined behavior.
And generally, any code which starts iterating through an iterable
with the intention of exhausting it, should arrange to make sure that
``__(a)iterclose__`` is eventually called, whether or not the iterator
is actually exhausted.
Changes to iteration
--------------------
The core proposal is the change in behavior of ``for`` loops. Given
this Python code::
for VAR in ITERABLE:
LOOP-BODY
else:
ELSE-BODY
we desugar to the equivalent of::
_iter = iter(ITERABLE)
_iterclose = getattr(type(_iter), "__iterclose__", lambda: None)
try:
traditional-for VAR in _iter:
LOOP-BODY
else:
ELSE-BODY
finally:
_iterclose(_iter)
where the "traditional-for statement" here is meant as a shorthand for
the classic 3.5-and-earlier ``for`` loop semantics.
Besides the top-level ``for`` statement, Python also contains several
other places where iterators are consumed. For consistency, these
should call ``__iterclose__`` as well using semantics equivalent to
the above. This includes:
- ``for`` loops inside comprehensions
- ``*`` unpacking
- functions which accept and fully consume iterables, like
``list(it)``, ``tuple(it)``, ``itertools.product(it1, it2, ...)``,
and others.
In addition, a ``yield from`` that successfully exhausts the called
generator should as a last step call its ``__iterclose__``
method. (Rationale: ``yield from`` already links the lifetime of the
calling generator to the called generator; if the calling generator is
closed when half-way through a ``yield from``, then this will already
automatically close the called generator.)
Changes to async iteration
--------------------------
We also make the analogous changes to async iteration constructs,
except that the new slot is called ``__aiterclose__``, and it's an
async method that gets ``await``\ed.
Modifications to basic iterator types
-------------------------------------
Generator objects (including those created by generator
comprehensions):
- ``__iterclose__`` calls ``self.close()``
- ``__del__`` calls ``self.close()`` (same as now), and additionally
issues a ``ResourceWarning`` if the generator wasn't exhausted. This
warning is hidden by default, but can be enabled for those who want
to make sure they aren't inadvertently relying on CPython-specific
GC semantics.
Async generator objects (including those created by async generator
comprehensions):
- ``__aiterclose__`` calls ``self.aclose()``
- ``__del__`` issues a ``RuntimeWarning`` if ``aclose`` has not been
called, since this probably indicates a latent bug, similar to the
"coroutine never awaited" warning.
QUESTION: should file objects implement ``__iterclose__`` to close the
file? On the one hand this would make this change more disruptive; on
the other hand people really like writing ``for line in open(...):
...``, and if we get used to iterators taking care of their own
cleanup then it might become very weird if files don't.
New convenience functions
-------------------------
The ``operator`` module gains two new functions, with semantics
equivalent to the following::
def iterclose(it):
if not isinstance(it, collections.abc.Iterator):
raise TypeError("not an iterator")
if hasattr(type(it), "__iterclose__"):
type(it).__iterclose__(it)
async def aiterclose(ait):
if not isinstance(it, collections.abc.AsyncIterator):
raise TypeError("not an iterator")
if hasattr(type(ait), "__aiterclose__"):
await type(ait).__aiterclose__(ait)
The ``itertools`` module gains a new iterator wrapper that can be used
to selectively disable the new ``__iterclose__`` behavior::
# QUESTION: I feel like there might be a better name for this one?
class preserve(iterable):
def __init__(self, iterable):
self._it = iter(iterable)
def __iter__(self):
return self
def __next__(self):
return next(self._it)
def __iterclose__(self):
# Swallow __iterclose__ without passing it on
pass
Example usage (assuming that file objects implements
``__iterclose__``)::
with open(...) as handle:
# Iterate through the same file twice:
for line in itertools.preserve(handle):
...
handle.seek(0)
for line in itertools.preserve(handle):
...
::
@contextlib.contextmanager
def iterclosing(iterable):
it = iter(iterable)
try:
yield preserve(it)
finally:
iterclose(it)
__iterclose__ implementations for iterator wrappers
---------------------------------------------------
Python ships a number of iterator types that act as wrappers around
other iterators: ``map``, ``zip``, ``itertools.accumulate``,
``csv.reader``, and others. These iterators should define a
``__iterclose__`` method which calls ``__iterclose__`` in turn on
their underlying iterators. For example, ``map`` could be implemented
as::
# Helper function
map_chaining_exceptions(fn, items, last_exc=None):
for item in items:
try:
fn(item)
except BaseException as new_exc:
if new_exc.__context__ is None:
new_exc.__context__ = last_exc
last_exc = new_exc
if last_exc is not None:
raise last_exc
class map:
def __init__(self, fn, *iterables):
self._fn = fn
self._iters = [iter(iterable) for iterable in iterables]
def __iter__(self):
return self
def __next__(self):
return self._fn(*[next(it) for it in self._iters])
def __iterclose__(self):
map_chaining_exceptions(operator.iterclose, self._iters)
def chain(*iterables):
try:
while iterables:
for element in iterables.pop(0):
yield element
except BaseException as e:
def iterclose_iterable(iterable):
operations.iterclose(iter(iterable))
map_chaining_exceptions(iterclose_iterable, iterables, last_exc=e)
In some cases this requires some subtlety; for example, `itertools.tee`_
should not call ``__iterclose__`` on the underlying iterator until it
has been called on *all* of the clone iterators.
.. _itertools.tee: https://docs.python.org/3/library/itertools.html#itertools.tee
Example / Rationale
-------------------
The payoff for all this is that we can now write straightforward code
like::
def read_newline_separated_json(path):
for line in open(path):
yield json.loads(line)
and be confident that the file will receive deterministic cleanup
*without the end-user having to take any special effort*, even in
complex cases. For example, consider this silly pipeline::
list(map(lambda key: key.upper(),
doc["key"] for doc in read_newline_separated_json(path)))
If our file contains a document where ``doc["key"]`` turns out to be
an integer, then the following sequence of events will happen:
1. ``key.upper()`` raises an ``AttributeError``, which propagates out
of the ``map`` and triggers the implicit ``finally`` block inside
``list``.
2. The ``finally`` block in ``list`` calls ``__iterclose__()`` on the
map object.
3. ``map.__iterclose__()`` calls ``__iterclose__()`` on the generator
comprehension object.
4. This injects a ``GeneratorExit`` exception into the generator
comprehension body, which is currently suspended inside the
comprehension's ``for`` loop body.
5. The exception propagates out of the ``for`` loop, triggering the
``for`` loop's implicit ``finally`` block, which calls
``__iterclose__`` on the generator object representing the call to
``read_newline_separated_json``.
6. This injects an inner ``GeneratorExit`` exception into the body of
``read_newline_separated_json``, currently suspended at the
``yield``.
7. The inner ``GeneratorExit`` propagates out of the ``for`` loop,
triggering the ``for`` loop's implicit ``finally`` block, which
calls ``__iterclose__()`` on the file object.
8. The file object is closed.
9. The inner ``GeneratorExit`` resumes propagating, hits the boundary
of the generator function, and causes
``read_newline_separated_json``'s ``__iterclose__()`` method to
return successfully.
10. Control returns to the generator comprehension body, and the outer
``GeneratorExit`` continues propagating, allowing the
comprehension's ``__iterclose__()`` to return successfully.
11. The rest of the ``__iterclose__()`` calls unwind without incident,
back into the body of ``list``.
12. The original ``AttributeError`` resumes propagating.
(The details above assume that we implement ``file.__iterclose__``; if
not then add a ``with`` block to ``read_newline_separated_json`` and
essentially the same logic goes through.)
Of course, from the user's point of view, this can be simplified down
to just:
1. ``int.upper()`` raises an ``AttributeError``
1. The file object is closed.
2. The ``AttributeError`` propagates out of ``list``
So we've accomplished our goal of making this "just work" without the
user having to think about it.
Transition plan
===============
While the majority of existing ``for`` loops will continue to produce
identical results, the proposed changes will produce
backwards-incompatible behavior in some cases. Example::
def read_csv_with_header(lines_iterable):
lines_iterator = iter(lines_iterable)
for line in lines_iterator:
column_names = line.strip().split("\t")
break
for line in lines_iterator:
values = line.strip().split("\t")
record = dict(zip(column_names, values))
yield record
This code used to be correct, but after this proposal is implemented
will require an ``itertools.preserve`` call added to the first ``for``
loop.
[QUESTION: currently, if you close a generator and then try to iterate
over it then it just raises ``Stop(Async)Iteration``, so code the
passes the same generator object to multiple ``for`` loops but forgets
to use ``itertools.preserve`` won't see an obvious error -- the second
``for`` loop will just exit immediately. Perhaps it would be better if
iterating a closed generator raised a ``RuntimeError``? Note that
files don't have this problem -- attempting to iterate a closed file
object already raises ``ValueError``.]
Specifically, the incompatibility happens when all of these factors
come together:
- The automatic calling of ``__(a)iterclose__`` is enabled
- The iterable did not previously define ``__(a)iterclose__``
- The iterable does now define ``__(a)iterclose__``
- The iterable is re-used after the ``for`` loop exits
So the problem is how to manage this transition, and those are the
levers we have to work with.
First, observe that the only async iterables where we propose to add
``__aiterclose__`` are async generators, and there is currently no
existing code using async generators (though this will start changing
very soon), so the async changes do not produce any backwards
incompatibilities. (There is existing code using async iterators, but
using the new async for loop on an old async iterator is harmless,
because old async iterators don't have ``__aiterclose__``.) In
addition, :pep:`525` was accepted on a provisional basis, and async
generators are by far the biggest beneficiary of this PEP's proposed
changes. Therefore, I think we should strongly consider enabling
``__aiterclose__`` for ``async for`` loops and async generators ASAP,
ideally for 3.6.0 or 3.6.1.
For the non-async world, things are harder, but here's a potential
transition path:
In 3.7:
Our goal is that existing unsafe code will start emitting warnings,
while those who want to opt-in to the future can do that immediately:
- We immediately add all the ``__iterclose__`` methods described
above.
- If ``from __future__ import iterclose`` is in effect, then ``for``
loops and ``*`` unpacking call ``__iterclose__`` as specified above.
- If the future is *not* enabled, then ``for`` loops and ``*``
unpacking do *not* call ``__iterclose__``. But they do call some
other method instead, e.g. ``__iterclose_warning__``.
- Similarly, functions like ``list`` use stack introspection (!!) to
check whether their direct caller has ``__future__.iterclose``
enabled, and use this to decide whether to call ``__iterclose__`` or
``__iterclose_warning__``.
- For all the wrapper iterators, we also add ``__iterclose_warning__``
methods that forward to the ``__iterclose_warning__`` method of the
underlying iterator or iterators.
- For generators (and files, if we decide to do that),
``__iterclose_warning__`` is defined to set an internal flag, and
other methods on the object are modified to check for this flag. If
they find the flag set, they issue a ``PendingDeprecationWarning``
to inform the user that in the future this sequence would have led
to a use-after-close situation and the user should use
``preserve()``.
In 3.8:
- Switch from ``PendingDeprecationWarning`` to ``DeprecationWarning``
In 3.9:
- Enable the ``__future__`` unconditionally and remove all the
``__iterclose_warning__`` stuff.
I believe that this satisfies the normal requirements for this kind of
transition -- opt-in initially, with warnings targeted precisely to
the cases that will be effected, and a long deprecation cycle.
Probably the most controversial / risky part of this is the use of
stack introspection to make the iterable-consuming functions sensitive
to a ``__future__`` setting, though I haven't thought of any situation
where it would actually go wrong yet...
Acknowledgements
================
Thanks to Yury Selivanov, Armin Rigo, and Carl Friedrich Bolz for
helpful discussion on earlier versions of this idea.
Copyright
=========
This document has been placed in the public domain.