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I am surprised to see from pstack that this code leads to deadlock! I don't see a reason for the same.

pthread_mutex_t lock;

_Cilk_for (int i = 0; i < N; ++i) {
  int ai = A[i];
  if (ai < pivot) {
    A[ia++] = ai;
  else if (ai > pivot) {
    A[ib++] = ai;
  else {
    A[ic++] = ai;

I am just using mutexes to make sure that access to A is atomic and serialized.

  • What is wrong with this code to lead to deadlock?
  • Is there a better way to implement this?
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Side note: This looks like a horrible way to implement a parallel quick sort? –  Mysticial Sep 3 '12 at 4:18
Are you calling pthread_mutex_init on lock? –  Nemo Sep 3 '12 at 4:23
This code will not deadlock. A deadlock requires, at least, holding a lock while trying to acquire another lock. You are never doing that. –  Keith Randall Sep 3 '12 at 4:24
But, yet, it is deadlocking right in front of me. –  Lazer Sep 3 '12 at 4:33

3 Answers 3

up vote 5 down vote accepted

If that's code inside a function, then you're not initialising the mutex correctly. You need to set it to PTHREAD_MUTEX_INITIALIZER (for a simple, default mutex) or do a pthread_mutex_init() on it (for more complex requirements). Without proper initialisation, you don't know what state the mutex starts in - it may well be in a locked state simply because whatever happened to be on the stack at that position looked like a locked mutex.

That's why it always needs to be initialised somehow, so that there is no doubt of the initial state.

Another potential problem you may have is this:

int ai = A[i];

You probably should protect that access with the same mutex since otherwise you may read it in a "half-state" (when another thread is only part way through updating the variable).

And, I have to say, I'm not sure that threads are being used wisely here. The use of mutexes is likely to swamp a statement like A[ia++] = ai to the point where the vast majority of time will be spent locking and unlocking the mutex. They're generally more useful where the code being processed during the lock is a little more substantial.

You may find a non-threaded variant will blow this one out of the water (but, of course, don't take my word for it - my primary optimisation mantra is "measure, don't guess").

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Thanks, this works, but I don't understand, how does the value of lock matter? –  Lazer Sep 3 '12 at 4:52
If the API provides an init mechanism (pthread_mutex_init), it matters... –  Richard Sitze Sep 3 '12 at 4:57
@paxdiablo: Any idea why a missing init() might lead to a deadlock? I am pretty sure it is a deadlock. –  Lazer Sep 3 '12 at 5:16
@Lazer: yes, without proper initialisation as per the pthreads doco, you don't know the initial state. It may start in a locked state for all we know, just because that was what was on the stack when you allocated it. See the update. –  paxdiablo Sep 3 '12 at 5:25

Your pthread_mutex_t lock is not properly initialized, so, since it is a local variable, it may contain garbage, and might be in a strangely locked state. You should call pthread_mutex_init or initialize your lock with PTHREAD_MUTEX_INITIALIZER

As others complained, you are not wisely using mutexes. The critical sections of your code are much too small.

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got it, thanks! –  Lazer Sep 3 '12 at 5:41

AFTER you fix or otherwise verify that you are in fact initializing your lock:

pstack may be privy to control mechanisms introduced by _Cilk_for that are interfering with what would otherwise be reasonable pthread code.

A quick search shows there are mutex solutions for use with Cilk - intermixing Cilk and pthreads isn't mentioned. It does look like Cilk is a layer on top of pthreads - so if Cilk chose to put a wrapper around mutex, they likely did so for a good reason. I'd suggest staying with the Cilk API.

That aside, there's a more fundamental issue with your algorithm. In your case, the overhead for creating parallel threads and synchronizing them likely dwarfs the cost of executing the code in the body of the for-loop. It's very possible this will run faster without parallelizing it.

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Yes, in-fact this is 10 times slower than serial version for some workloads. –  Lazer Sep 3 '12 at 5:10

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