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Because sometimes it's more practical than designing a solution around queues, I would like to write a simple wrapper to make an iterator thread safe. So far, I had inspiration from these topics and came up with two ideas:

Idea 1

class LockedIterator(object):
    def __init__(self, it):
        self._lock = threading.Lock()
        self._it = it.__iter__()
        if hasattr(self._it, 'close'):
            def close(self):
                with self._lock:
            self.__setattr__('close', close)

    def __iter__(self):
        return self

    def next(self):
        with self._lock:
            return self._it.next()

What I don't like about it, is that it gets a bit lengthy if I have to specify all possible methods - okay, I can't - such as the special case for generators. Also, I might have some other iterator with even more specific methods that have now become hidden.

Idea 2

class LockedIterator(object):
    def __init__(self, it):
        self._lock = threading.Lock()
        self._it = it.__iter__()

    def __getattr__(self, item):
        attr = getattr(self._it, item)
        if callable(attr):
            def hooked(*args, **kwargs):
                with self._lock:
                    return attr(*args, **kwargs)
            setattr(self, item, hooked)
            return hooked

This is more concise, but it can only intercept calls, and not, for example, direct property changes. (Those properties are now hidden to prevent problems.) More importantly, it makes it so that Python does no longer recognize my object as an iterator!

What is the best way of making this work for all iterators (or even better: all objects), without creating a leaky abstraction? I'm not too worried about locking when it's not necessary, but if you can come up with a solution that circumvents that, great!

share|improve this question
Can't the thing being iterated still get mutated in between getting each bit with next? – GP89 Nov 19 '12 at 15:28
@GP89 I'm not sure what you're asking. The whole point of creating a locked iterator, is that I can use it safely among several threads, without having to work with queues. All these threads should be allowed to do anything with that iterator, except for adding/removing attributes, maybe. – Thijs van Dien Nov 19 '12 at 15:33
threading locks are themselves context managers, so you can simplify all the try-except-finally code down to just with self._lock: – Paul McGuire Nov 19 '12 at 15:56
@PaulMcGuire Thanks! That cleans it up a bit. – Thijs van Dien Nov 19 '12 at 16:09
I'm at a loss of trying to figure out when you'd need to share an iterator across threads, instead of sharing a concurrent collection. The whole design makes me feel uneasy - trying to avoid the need to use a proper queue seems like a very leaky abstraction already. – millimoose Nov 19 '12 at 19:13
up vote 4 down vote accepted

First, are you aware of the GIL? Attempts to write multi-threaded Python typically end up in slower run-time than with a straightforward single-threaded version.

Your first attempt at making access to an iterator thread-safe seems quite reasonable. You can make it a bit more readable by using a generator:

def locked_iter(it):
    it = iter(it)
    lock = threading.Lock()
    while 1:
            with lock:
                value = it.next()
        except StopIteration:
        yield value
share|improve this answer
I am aware of the benefits and limitations of threads in Python. In my case, I have to deal with network latency. Your solution seems nice (and you deserve my upvote), but still it does not offer a way to keep any of the other attributes a particular kind of iterator might have. I decided not to ask my question in terms of one use case I have now, especially because I would like the solution to be more general. – Thijs van Dien Nov 19 '12 at 20:26
@tvdien If the iterator has other attributes, then it's not really an iterator, interface-wise — in that case we are talking about proxying arbitrary objects. This is possible in Python, but it requires tricky code to handle special methods—the only way to make it work is by creating classes on-the-fly. The result is slowish, hard to maintain, and rarely worth the effort. – user4815162342 Nov 19 '12 at 20:52
@tvdien I'm trying to understand the "network latency" requirement. How do Python threads help you with network latency? And what is wrong with using thread-safe queues, the standard multithreaded idiom? – user4815162342 Nov 19 '12 at 20:53
It is my understanding that any object having both next and __iter__ methods can be considered an interator. As mentioned above, my current project is a password breaker. Since it works over SOAP, there is a considerable delay between request and response. While I'm waiting for one response, I can send the next request. The speed increased significantly. As to why I'd like to avoid queues, it too is described in the conversation above. Is it better to create a variable and not yield next(it)? – Thijs van Dien Nov 19 '12 at 21:02
@tvdien Existence of __iter__ makes an object an iterable, capable of producing iterator(s). An iterator actually produces values, and as such only the next method. yield next(it) would be incorrect because it would inadvertently catch StopIteration raised where the generator is being used. – user4815162342 Nov 19 '12 at 21:23

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