Hi!

> > > I'm getting the following lockdep splat (see below).
> > > 
> > > Apparently this warning starts to be reported after applying:
> > > 
> > >  e918188611f0 ("locking: More accurate annotations for read_lock()")
> > > 
> > > It looks like a false positive to me, but it made me think a bit and
> > > IIUC there can be still a potential deadlock, even if the deadlock
> > > scenario is a bit different than what lockdep is showing.
> > > 
> > > In the assumption that read-locks are recursive only in_interrupt()
> > > context (as stated in e918188611f0), the following scenario can still
> > > happen:
> > > 
> > >  CPU0                                     CPU1
> > >  ----                                     ----
> > >  read_lock(&trig->leddev_list_lock);
> > >                                           write_lock(&trig->leddev_list_lock);
> > >  <soft-irq>
> > >  kbd_bh()
> > >    -> read_lock(&trig->leddev_list_lock);
> > > 
> > >  *** DEADLOCK ***
> > > 
> > > The write-lock is waiting on CPU1 and the second read_lock() on CPU0
> > > would be blocked by the write-lock *waiter* on CPU1 => deadlock.
> > > 
> > 
> > No, this is not a deadlock, as a write-lock waiter only blocks
> > *non-recursive* readers, so since the read_lock() in kbd_bh() is called
> > in soft-irq (which in_interrupt() returns true), so it's a recursive
> > reader and won't get blocked by the write-lock waiter.
> 
> That's right, I was missing that in_interrupt() returns true also from
> soft-irq context.
> 
> > > In that case we could prevent this deadlock condition using a workqueue
> > > to call kbd_propagate_led_state() instead of calling it directly from
> > > kbd_bh() (even if lockdep would still report the false positive).
> > > 
> > 
> > The deadlock senario reported by the following splat is:
> > 
> > 	
> > 	CPU 0:				CPU 1:					CPU 2:
> > 	-----				-----					-----
> > 	led_trigger_event():
> > 	  read_lock(&trig->leddev_list_lock);
> > 					<work queue processing>
> > 	  				ata_hsm_qs_complete():
> > 					  spin_lock_irqsave(&host->lock);
> > 					  					write_lock(&trig->leddev_list_lock);
> > 					  ata_port_freeze():
> > 					    ata_do_link_abort():
> > 					      ata_qc_complete():
> > 					        ledtrig_disk_activity():
> > 						  led_trigger_blink_oneshot():
> > 						    read_lock(&trig->leddev_list_lock);
> > 						    // ^ not in in_interrupt() context, so could get blocked by CPU 2
> > 	<interrupt>
> > 	  ata_bmdma_interrupt():
> > 	    spin_lock_irqsave(&host->lock);
> > 	  
> > , where CPU 0 is blocked by CPU 1 because of the spin_lock_irqsave() in
> > ata_bmdma_interrupt() and CPU 1 is blocked by CPU 2 because of the
> > read_lock() in led_trigger_blink_oneshot() and CPU 2 is blocked by CPU 0
> > because of an arbitrary writer on &trig->leddev_list_lock.
> > 
> > So I don't think it's false positive, but I might miss something
> > obvious, because I don't know what the code here actually does ;-)
> 
> With the CPU2 part it all makes sense now and lockdep was right. :)
> 
> At this point I think we could just schedule a separate work to do the
> led trigger and avoid calling it with host->lock held and that should
> prevent the deadlock. I'll send a patch to do that.

Let's... not do that, unless we have no choice.

Would it help if leddev_list_lock used _irqsave() locking?

Best regards,
								Pavel
-- 
http://www.livejournal.com/~pavelmachek