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I've been working on this one for a few days -

As a background, I'm working on taking a single-threaded C program and making it multi-threaded. I have recently discovered a new deadlock case, but when I look at the mutex in gdb I see that

__lock=2 yet __owner=0

This is not a recursive mutex. Has anyone seen this? The program I'm working on is a daemon and this case only happens after executing at a high-throughput rate for over 20 minutes (approximately) and then relaxing the load. If you have any ideas I'd be grateful.

Edit - I neglected to mention that all of my other threads are idle at this time.


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Some source, any source to establish context would be really helpful. – Josh Jul 14 '11 at 16:59
@nos I run it in valgrind a lot to check that things are normal, but I will do that some more to see if I've made some new mistakes. – dbeer Jul 14 '11 at 17:00
@Josh - The code overall is over 200k lines. The daemon tracks timed tasks by placing the in a queue in order and checking periodically to see if they are ready to be executed, so the only time this object and its mutex are looked at are to inspect if it is ready to be executed. If it is, it is removed from the queue and the function is called. Other than that it is only accessed to check its timing when other objects are inserted in order. – dbeer Jul 14 '11 at 17:02
If your mutex havn't been properly initialized, you could get results like this. – nos Jul 14 '11 at 18:40
@nos - that was my first thought, but this mutex is always initialized (it is only created in one function). – dbeer Jul 14 '11 at 19:07

This is to be expected. A normal (non-recursive, non-errorchecking) mutex has no need to store its owner, and some time can be saved skipping the step of looking up the caller's thread id. (This makes little difference on x86 but can be a huge difference on platforms like MIPS with broken ABIs, where there is no thread register and getting the thread id incurs a fault into kernelspace.)

The deadlock you're seeing it almost certainly due either to the thread trying to lock a mutex it already holds, or an actual logic error where two or more threads are each waiting for mutexes the other holds.

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I have to disagree - it isn't normal. The way I've tracked down deadlock in the past is by checking who owns the mutex and then inspecting that. An additional detail I should've mentioned is that all other threads are idle at this point (I will edit my post). Also, how does a non-recursive mutex have a lock of 2? My understanding is that only recusive mutexes can have a lock value > 1. – dbeer Jul 14 '11 at 17:45
This is all very implementation-specific, but I doubt the lock field is the reference count. It's almost surely just the atomic-exchange-for-locking field. I suspect 0 means unlocked, 1 means locked and uncontended, and 2 means locked with potential waiters. If in doubt, read the source. – R.. Jul 14 '11 at 18:47
@dbeer: R.. is actually right, normal mutexes don't save the owner, IIRC it's saved on recursive and error-checking mutexes, – ninjalj Jul 14 '11 at 18:51
I'm going to try making it a recursive mutex and seeing what I get. – dbeer Jul 14 '11 at 19:06
The glibc source code suggests all kinds of mutexes save the owner once a lock has been aquired in the __pthread_mutex_lock function, nptl/pthread_mutex_lock.c – nos Jul 14 '11 at 20:12
up vote 2 down vote accepted

As far as I can tell, this is due to a limitation of the pthread library. Whenever I have found parts of the code that use excessive locking and unlocking and heavily stressed that section of the code, I have had this kind of failure. I have solved them by re-writing these sections to minimize their locking, which is easier code to maintain (less error checking when re-acquiring potentially freed objects) and eliminates some overhead.

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I just fixed the issue I was having - stack corruption caused the mutex.__data.__lock value to get set to some ridiculous number (4 billion-ish) just prior to attempting the pthread_mutex_lock call. See if you can set a breakpoint, or print debugging info on the value of __lock just prior to performing the lock operation, and I'm willing to bet it's invalid right before the deadlock occurs.

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