# When to use recursive mutex?

I understand recursive mutex allows mutex to be locked more than once without getting to a deadlock and should be unlocked the same number of times. But in what specific situations do you need to use a recursive mutex? I'm looking for design/code-level situations.

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Not actually a dupe, but overlapping: stackoverflow.com/questions/187761/…. That question asks "why on earth would anyone want to use a non-recursive mutex". This question asks "why on earth would anyone want to use a recursive mutex?". It's like alien civilisations colliding ;-) –  Steve Jessop Mar 10 '10 at 11:49
@Steve: Yes, I did check that thread before but I just didn't get the answer I was looking for... I'm actually looking for specific designs where it is really needed.. –  jasonline Mar 10 '10 at 12:37
I'm pretty sure there are none, or at least none simple and obviously-good-design enough to serve as killer apps. Any function which takes a mutex can be replaced by two functions, one which takes it and one which doesn't. Any function which wants to call such a function can call the appropriate one according to whether the mutex in question is already held. Any design in which you call functions without knowing whether or not you already hold a mutex which is relevant to that function, is probably broken. But look at almost any Java to see code which gains brevity from recursive locking. –  Steve Jessop Mar 10 '10 at 12:54

For example when you have function that calls it recursively, and you want to get synchronized access to it:

``````void foo() {
... mutex_acquire();
... foo();
... mutex_release();
}
``````

without a recursive mutex you would have to create an "entry point" function first, and this becomes cumbersome when you have a set of functions that are mutually recursive. Without recursive mutex:

``````void foo_entry() {
mutex_acquire(); foo(); mutex_release(); }

void foo() { ... foo(); ... }
``````
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While that is true, locking has a great deal of overhead, and so it might not be a bad idea to create thread unsafe versions of the code, first, and then create a lightweight threadsafe wrapper for it. –  Michael Aaron Safyan Mar 10 '10 at 8:18
@Michael: if your mutex implementation supports recursive locking at all, chances are it will support it efficiently. All that's usually required is that the lock function does "if (mutex.owner == thisthread) { ++lockcount; return; }". If you don't have the lock then you're reading the owner field unsynchronized, but provided the implementation knows that reads and writes of the mutex.owner field are atomic (e.g. word reads on x86), you can't get a false positive. If you do have the lock then you can't get a false negative because nothing can change the owner while you hold it. –  Steve Jessop Mar 10 '10 at 11:43
"you can't get a false positive". I should probably mention that there are some further assumptions there - primarily that each time a thread acquires or releases a mutex, the kernel ensures that the mutex.owner field is changed in a way which is visible to that thread (either change it from the thread, or flush the thread's cache of it, or whatever). –  Steve Jessop Mar 10 '10 at 11:51
@Steve, regardless, is it useful to have an unsynchronized implementation in addition to a threadsafe one, because the initial acquisition and final release of the mutex do impose a great deal of overhead, which would be unnecessary in single-threaded code. Also, one cannot assume that the mutex implementation will not suspend signals or do some other expensive operation during the intermediate locks and releases. –  Michael Aaron Safyan Mar 11 '10 at 10:39
Sure, libraries generally shouldn't have built-in thread-safety unless they actually create threads themselves or explicitly operate on multiple threads specified by their clients. Not for performance, but as a separation of concerns - combining multiple self-synchronising chunks of code can rapidly get quite complicated, with locking order and perhaps a need for atomic operations involving data in both domains. So applications need to be able to take over responsibility. Occasionally it doesn't make sense to offer a non-threadsafe version (an unsafe thread pool?), else it should be the norm. –  Steve Jessop Mar 11 '10 at 11:38

It would certainly be a problem if a thread blocked trying to acquire (again) a mutex it already owned...

Is there a reason to not permit a mutex to be acquired multiple times by the same thread?

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Simplicity of implementation, I think. Also, here's a reasonable factor against recursive mutexes: stackoverflow.com/questions/187761/…. I suspect Java may have pretty much obliterated the average programmer's familiarity with, or ability to use, non-recursive locks. –  Steve Jessop Mar 10 '10 at 11:57

Recursive and non-recursive mutexes have different use cases. No mutex type can easily replace the other. Non-recursive mutexes have less overhead, and recursive mutexes have in some situations useful or even needed semantics and in other situations dangerous or even broken semantics. In most cases, someone can replace any strategy using recursive mutexes with a different safer and more efficient strategy based on the usage of non-recursive mutexes.

• If you just want to exclude other threads from using your mutex protected resource, then you could use any mutex type, but might want to use the non-recursive mutex because of its smaller overhead.
• If you want to call functions recursively, which lock the same mutex, then they either
• have to use one recursive mutex, or
• have to unlock and lock the same non-recursive mutex again and again (beware of concurrent threads!), or
• have to somehow annotate which mutexes they already locked (simulating recursive ownership/mutexes).
• If you want to lock several mutex-protected objects from a set of such objects, where the sets could have been built by merging, you can choose
• to use per object exactly one mutex, allowing more threads to work in parallel, or
• to use per object one reference to any possibly shared recursive mutex, to lower the probability of failing to lock all mutexes together, or
• to use per object one comparable reference to any possibly shared non-recursive mutex, circumventing the intent to lock multiple times.
• If you want to release a lock in a different thread than it has been locked, then you have to use non-recursive locks (or recursive locks which explicitly allow this instead of throwing exceptions).
• If you want to use synchronization variables, then you need to be able to explicitly unlock the mutex while waiting on any synchronization variable, so that the resource is allowed to be used in other threads. That is only sanely possible with non-recursive mutexes, because recursive mutexes could already have been locked by the caller of the current function.
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Not sure I agree that "have to unlock and lock the same non-recursive mutex again and again (beware of concurrent threads!)" is viable, even with the warning. If you're not ready to release the resource (either it's in an inconsistent state or you don't want anyone else mucking about with it), do not unlock/recur/lock. I guarantee at some point another thread will sneak in and bite you where the sun don't shine :-) I won't downvote since the rest of the answer is actually very good - I just thought I'd bring that up. –  paxdiablo May 11 '12 at 7:32
See stackoverflow.com/questions/10546867/… for what bought this on. –  paxdiablo May 11 '12 at 7:33
and here too: stackoverflow.com/q/10548284/462608 –  TheIndependentAquarius May 11 '12 at 9:20

If you want to see an example of code that uses recursive mutexes, look at the sources for "Electric Fence". It's one of the common Unix tools for "bounds checking" before Valgrind came along.

Just compile and link it with your program with sources, and start stepping through it.

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