|Title:||Protecting cleanup statements from interruptions|
|Author:||Paul Colomiets <paul at colomiets.name>|
- PEP Deferral
- Unresolved Issues
- Alternative Python Implementations Support
- Alternative Names
- Alternative Proposals
This PEP proposes a way to protect Python code from being interrupted inside a finally clause or during context manager cleanup.
Further exploration of the concepts covered in this PEP has been deferred for lack of a current champion interested in promoting the goals of the PEP and collecting and incorporating feedback, and with sufficient available time to do so effectively.
Python has two nice ways to do cleanup. One is a finally statement and the other is a context manager (usually called using a with statement). However, neither is protected from interruption by KeyboardInterrupt or GeneratorExit caused by generator.throw(). For example:
lock.acquire() try: print('starting') do_something() finally: print('finished') lock.release()
If KeyboardInterrupt occurs just after the second print() call, the lock will not be released. Similarly, the following code using the with statement is affected:
from threading import Lock class MyLock: def __init__(self): self._lock_impl = Lock() def __enter__(self): self._lock_impl.acquire() print("LOCKED") def __exit__(self): print("UNLOCKING") self._lock_impl.release() lock = MyLock() with lock: do_something
If KeyboardInterrupt occurs near any of the print() calls, the lock will never be released.
A similar case occurs with coroutines. Usually coroutine libraries want to interrupt the coroutine with a timeout. The generator.throw() method works for this use case, but there is no way of knowing if the coroutine is currently suspended from inside a finally clause.
def run_locked(): yield connection.sendall('LOCK') try: yield do_something() yield do_something_else() finally: yield connection.sendall('UNLOCK') with timeout(5): yield run_locked()
In the example above, yield something means to pause executing the current coroutine and to execute coroutine something until it finishes execution. Therefore, the coroutine library itself needs to maintain a stack of generators. The connection.sendall() call waits until the socket is writable and does a similar thing to what socket.sendall() does.
The with statement ensures that all code is executed within 5 seconds timeout. It does so by registering a callback in the main loop, which calls generator.throw() on the top-most frame in the coroutine stack when a timeout happens.
The greenlets extension works in a similar way, except that it doesn't need yield to enter a new stack frame. Otherwise considerations are similar.
A new flag on the frame object is proposed. It is set to True if this frame is currently executing a finally clause. Internally, the flag must be implemented as a counter of nested finally statements currently being executed.
The internal counter also needs to be incremented during execution of the SETUP_WITH and WITH_CLEANUP bytecodes, and decremented when execution for these bytecodes is finished. This allows to also protect __enter__() and __exit__() methods.
A new function for the sys module is proposed. This function sets a callback which is executed every time f_in_cleanup becomes false. Callbacks get a frame object as their sole argument, so that they can figure out where they are called from.
The setting is thread local and must be stored in the PyThreadState structure.
Two new functions are proposed for the inspect module: isframeincleanup() and getcleanupframe().
isframeincleanup(), given a frame or generator object as its sole argument, returns the value of the f_in_cleanup attribute of a frame itself or of the gi_frame attribute of a generator.
getcleanupframe(), given a frame object as its sole argument, returns the innermost frame which has a true value of f_in_cleanup, or None if no frames in the stack have a nonzero value for that attribute. It starts to inspect from the specified frame and walks to outer frames using f_back pointers, just like getouterframes() does.
An example implementation of a SIGINT handler that interrupts safely might look like:
import inspect, sys, functools def sigint_handler(sig, frame): if inspect.getcleanupframe(frame) is None: raise KeyboardInterrupt() sys.setcleanuphook(functools.partial(sigint_handler, 0))
A coroutine example is out of scope of this document, because its implementation depends very much on a trampoline (or main loop) used by coroutine library.
Given the statement
with open(filename): do_something()
Python can be interrupted after open() is called, but before the SETUP_WITH bytecode is executed. There are two possible decisions:
Protect with expressions. This would require another bytecode, since currently there is no way of recognizing the start of the with expression.
Let the user write a wrapper if he considers it important for the use-case. A safe wrapper might look like this:
class FileWrapper(object): def __init__(self, filename, mode): self.filename = filename self.mode = mode def __enter__(self): self.file = open(self.filename, self.mode) def __exit__(self): self.file.close()
Alternatively it can be written using the contextmanager() decorator:
@contextmanager def open_wrapper(filename, mode): file = open(filename, mode) try: yield file finally: file.close()
This code is safe, as the first part of the generator (before yield) is executed inside the SETUP_WITH bytecode of the caller.
Sometimes a finally clause or an __enter__()/__exit__() method can raise an exception. Usually this is not a problem, since more important exceptions like KeyboardInterrupt or SystemExit should be raised instead. But it may be nice to be able to keep the original exception inside a __context__ attribute. So the cleanup hook signature may grow an exception argument:
def sigint_handler(sig, frame) if inspect.getcleanupframe(frame) is None: raise KeyboardInterrupt() sys.setcleanuphook(retry_sigint) def retry_sigint(frame, exception=None): if inspect.getcleanupframe(frame) is None: raise KeyboardInterrupt() from exception
There is no need to have three arguments like in the __exit__ method since there is a __traceback__ attribute in exception in Python 3.
However, this will set the __cause__ for the exception, which is not exactly what's intended. So some hidden interpreter logic may be used to put a __context__ attribute on every exception raised in a cleanup hook.
The example from the first section is not totally safe. Let's take a closer look:
lock.acquire() try: do_something() finally: lock.release()
The problem might occur if the code is interrupted just after lock.acquire() is executed but before the try block is entered.
There is no way the code can be fixed unmodified. The actual fix depends very much on the use case. Usually code can be fixed using a with statement:
with lock: do_something()
However, for coroutines one usually can't use the with statement because you need to yield for both the acquire and release operations. So the code might be rewritten like this:
try: yield lock.acquire() do_something() finally: yield lock.release()
The actual locking code might need more code to support this use case, but the implementation is usually trivial, like this: check if the lock has been acquired and unlock if it is.
Even if a signal handler is prepared to check the f_in_cleanup flag, InterruptedError might be raised in the cleanup handler, because the respective system call returned an EINTR error. The primary use cases are prepared to handle this:
- Posix mutexes never return EINTR
- Networking libraries are always prepared to handle EINTR
- Coroutine libraries are usually interrupted with the throw() method, not with a signal
The platform-specific function siginterrupt() might be used to remove the need to handle EINTR. However, it may have hardly predictable consequences, for example SIGINT a handler is never called if the main thread is stuck inside an IO routine.
A better approach would be to have the code, which is usually used in cleanup handlers, be prepared to handle InterruptedError explicitly. An example of such code might be a file-based lock implementation.
signal.pthread_sigmask can be used to block signals inside cleanup handlers which can be interrupted with EINTR.
Some coroutine libraries may need to set a timeout for the finally clause itself. For example:
try: do_something() finally: with timeout(0.5): try: yield do_slow_cleanup() finally: yield do_fast_cleanup()
With current semantics, timeout will either protect the whole with block or nothing at all, depending on the implementation of each library. What the author intended is to treat do_slow_cleanup as ordinary code, and do_fast_cleanup as a cleanup (a non-interruptible one).
A similar case might occur when using greenlets or tasklets.
This case can be fixed by exposing f_in_cleanup as a counter, and by calling a cleanup hook on each decrement. A coroutine library may then remember the value at timeout start, and compare it on each hook execution.
But in practice, the example is considered to be too obscure to take into account.
It should be decided if the default SIGINT handler should be modified to use the described mechanism. The initial proposition is to keep old behavior, for two reasons:
- Most application do not care about cleanup on exit (either they do not have external state, or they modify it in crash-safe way).
- Cleanup may take too much time, not giving user a chance to interrupt an application.
The latter case can be fixed by allowing an unsafe break if a SIGINT handler is called twice, but it seems not worth the complexity.
We consider f_in_cleanup an implementation detail. The actual implementation may have some fake frame-like object passed to signal handler, cleanup hook and returned from getcleanupframe(). The only requirement is that the inspect module functions work as expected on these objects. For this reason, we also allow to pass a generator object to the isframeincleanup() function, which removes the need to use the gi_frame attribute.
It might be necessary to specify that getcleanupframe() must return the same object that will be passed to cleanup hook at the next invocation.
The original proposal had a f_in_finally frame attribute, as the original intention was to protect finally clauses. But as it grew up to protecting __enter__ and __exit__ methods too, the f_in_cleanup name seems better. Although the __enter__ method is not a cleanup routine, it at least relates to cleanup done by context managers.
setcleanuphook, isframeincleanup and getcleanupframe can be unobscured to set_cleanup_hook, is_frame_in_cleanup and get_cleanup_frame, although they follow the naming convention of their respective modules.
This can make getcleanupframe() unnecessary. But for yield-based coroutines you need to propagate it yourself. Making it writable leads to somewhat unpredictable behavior of setcleanuphook().
These bytecodes can be used to protect the expression inside the with statement, as well as making counter increments more explicit and easy to debug (visible inside a disassembly). Some middle ground might be chosen, like END_FINALLY and SETUP_WITH implicitly decrementing the counter (END_FINALLY is present at end of every with suite).
However, adding new bytecodes must be considered very carefully.
The original intention was to expose a minimum of needed functionality. However, as we consider the frame flag f_in_cleanup an implementation detail, we may expose it as a counter.
Similarly, if we have a counter we may need to have the cleanup hook called on every counter decrement. It's unlikely to have much performance impact as nested finally clauses are an uncommon case.
As an alternative to set the flag inside the SETUP_WITH and WITH_CLEANUP bytecodes, we can introduce a flag CO_CLEANUP. When the interpreter starts to execute code with CO_CLEANUP set, it sets f_in_cleanup for the whole function body. This flag is set for code objects of __enter__ and __exit__ special methods. Technically it might be set on functions called __enter__ and __exit__.
This seems to be less clear solution. It also covers the case where __enter__ and __exit__ are called manually. This may be accepted either as a feature or as an unnecessary side-effect (or, though unlikely, as a bug).
It may also impose a problem when __enter__ or __exit__ functions are implemented in C, as there is no code object to check for the f_in_cleanup flag.
The frame object may be extended to have a f_cleanup_callback member which is called when f_in_cleanup is reset to 0. This would help to register different callbacks to different coroutines.
Despite its apparent beauty, this solution doesn't add anything, as the two primary use cases are:
- Setting the callback in a signal handler. The callback is inherently a single one for this case.
- Use a single callback per loop for the coroutine use case. Here, in almost all cases, there is only one loop per thread.
The original proposal included no cleanup hook specification, as there are a few ways to achieve the same using current tools:
- Using sys.settrace() and the f_trace callback. This may impose some problem to debugging, and has a big performance impact (although interrupting doesn't happen very often).
- Sleeping a bit more and trying again. For a coroutine library this is easy. For signals it may be achieved using signal.alert.
Both methods are considered too impractical and a way to catch exit from finally clauses is proposed.
|||Twisted: inlineCallbacks http://twistedmatrix.com/documents/8.1.0/api/twisted.internet.defer.html|
|||Original discussion http://mail.python.org/pipermail/python-ideas/2012-April/014705.html|
|||Issue #14730: Implementation of the PEP 419 http://bugs.python.org/issue14730|
This document has been placed in the public domain.