On Thu, Jun 4, 2020 at 10:57 AM Thomas Hellström (Intel) thomas_os@shipmail.org wrote:
On 6/4/20 10:12 AM, Daniel Vetter wrote: ...
Thread A:
mutex_lock(A); mutex_unlock(A); dma_fence_signal();Thread B:
mutex_lock(A); dma_fence_wait(); mutex_unlock(A);Thread B is blocked on A signalling the fence, but A never gets around to that because it cannot acquire the lock A.
Note that dma_fence_wait() is allowed to be nested within dma_fence_begin/end_signalling sections. To allow this to happen the read lock needs to be upgraded to a write lock, which means that any other lock is acquired between the dma_fence_begin_signalling() call and the call to dma_fence_wait(), and still held, this will result in an immediate lockdep complaint. The only other option would be to not annotate such calls, defeating the point. Therefore these annotations cannot be sprinkled over the code entirely mindless to avoid false positives.
Just realized, isn't that example actually a true positive, or at least a great candidate for a true positive, since if another thread reenters that signaling path, it will block on that mutex, and the fence would never be signaled unless there is another signaling path?
Not sure I understand fully, but I think the answer is "it's complicated".
dma_fence are meant to be a DAG (directed acyclic graph). Now it would be nice to enforce that, and i915 has some attempts to that effect, but these annotations here don't try to pull off that miracle. I'm assuming that all the dependencies between dma_fence don't create a loop, and instead I'm only focusing on deadlocks between dma_fences and other locks. Usually an async work looks like this:
1. wait for a bunch of dma_fence that we have as dependencies 2. do work (e.g. atomic commit) 3. signal the dma_fence that represents our work
This can happen on the cpu in a kthread or worker, or on the gpu. Now for reasons you might want to have a per-work mutex or something and hold that while going through all this, and this is the false positive I'm thinking off. Of course, if your fences aren't a DAG, or if you're holding a mutex that's shared with some other work which is part of your dependency chain, then this goes boom. But it doesn't have to.
I think in general it's best to purely rely on ordering, and remove as much locking as possible. This is the design behind the atomic modeset commit code, which is does not take any mutexes in the commit path, at least not in the helpers. Drivers can still do stuff of course. Then the only locks you're left with are spinlocks (maybe irq safe ones) to coordinate with interrupt handlers, workers, handle the wait/wake queues, manage work/scheduler run queues and all that stuff, and no spinlocks.
Now for the case where you have something like the below:
thread 1:
dma_fence_begin_signalling() mutex_lock(a); dma_fence_wait(b1); mutex_unlock(a);
dma_fence_signal(b2); dma_fence_end_signalling();
That's indeed a bit problematic, assuming you're annotating stuff correctly, and the locking is actually required. I've seen a few of these, and annotating the properly needs care:
- often the mutex_lock/unlock is not needed, and just gets in the way. This was the case for the original atomic modeset commit work patches, which again locked all the modeset locks. But strict ordering of commit work was all that was needed to make this work, plus making sure data structure lifetimes are handled correctly too. I think the tendency to abuse locking to handle lifetime and ordering problems is fairly common, but it can lead to lots of trouble. Ime all async work items with the above problematic pattern can be fixed like this.
- other often case is that the dma_fence_begin_signalling() can&should be pushed down past the mutex_lock, and maybe even past the dma_fence_wait, depending upon when/how the dma_fence is published. The fence signalling critical section can still extend past the mutex_unlock, lockdep and semantics are fine with that (I think at least). This is more the case for execbuf tails, where you take locks, set up some async work, publish the fences and then begin to process these fences (which could just be pushing the work to the job scheduler, but could also involve running it directly in the userspace process thread context, but with locks already dropped).
So I wouldn't go out and say these are true positives, just maybe unecessary locking and over-eager annotations, without any real bugs in the code.
Or am I completely off the track and you're thinking of something else?
Although I agree the conclusion is sound: These annotations cannot be sprinkled mindlessly over the code.
Yup, that much is for sure. -Daniel
/Thomas
v2: handle soft/hardirq ctx better against write side and dont forget EXPORT_SYMBOL, drivers can't use this otherwise.
v3: Kerneldoc.
v4: Some spelling fixes from Mika
Cc: Mika Kuoppala mika.kuoppala@intel.com Cc: Thomas Hellstrom thomas.hellstrom@intel.com Cc: linux-media@vger.kernel.org Cc: linaro-mm-sig@lists.linaro.org Cc: linux-rdma@vger.kernel.org Cc: amd-gfx@lists.freedesktop.org Cc: intel-gfx@lists.freedesktop.org Cc: Chris Wilson chris@chris-wilson.co.uk Cc: Maarten Lankhorst maarten.lankhorst@linux.intel.com Cc: Christian König christian.koenig@amd.com Signed-off-by: Daniel Vetter daniel.vetter@intel.com
Documentation/driver-api/dma-buf.rst | 12 +- drivers/dma-buf/dma-fence.c | 161 +++++++++++++++++++++++++++ include/linux/dma-fence.h | 12 ++ 3 files changed, 182 insertions(+), 3 deletions(-)
diff --git a/Documentation/driver-api/dma-buf.rst b/Documentation/driver-api/dma-buf.rst index 63dec76d1d8d..05d856131140 100644 --- a/Documentation/driver-api/dma-buf.rst +++ b/Documentation/driver-api/dma-buf.rst @@ -100,11 +100,11 @@ CPU Access to DMA Buffer Objects .. kernel-doc:: drivers/dma-buf/dma-buf.c :doc: cpu access
-Fence Poll Support -~~~~~~~~~~~~~~~~~~ +Implicit Fence Poll Support +~~~~~~~~~~~~~~~~~~~~~~~~~~~
.. kernel-doc:: drivers/dma-buf/dma-buf.c
- :doc: fence polling
:doc: implicit fence polling
Kernel Functions and Structures Reference
@@ -133,6 +133,12 @@ DMA Fences .. kernel-doc:: drivers/dma-buf/dma-fence.c :doc: DMA fences overview
+DMA Fence Signalling Annotations +~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+.. kernel-doc:: drivers/dma-buf/dma-fence.c
- :doc: fence signalling annotation
- DMA Fences Functions Reference
diff --git a/drivers/dma-buf/dma-fence.c b/drivers/dma-buf/dma-fence.c index 656e9ac2d028..0005bc002529 100644 --- a/drivers/dma-buf/dma-fence.c +++ b/drivers/dma-buf/dma-fence.c @@ -110,6 +110,160 @@ u64 dma_fence_context_alloc(unsigned num) } EXPORT_SYMBOL(dma_fence_context_alloc);
+/**
- DOC: fence signalling annotation
- Proving correctness of all the kernel code around &dma_fence through code
- review and testing is tricky for a few reasons:
- It is a cross-driver contract, and therefore all drivers must follow the
- same rules for lock nesting order, calling contexts for various functions
- and anything else significant for in-kernel interfaces. But it is also
- impossible to test all drivers in a single machine, hence brute-force N vs.
- N testing of all combinations is impossible. Even just limiting to the
- possible combinations is infeasible.
- There is an enormous amount of driver code involved. For render drivers
- there's the tail of command submission, after fences are published,
- scheduler code, interrupt and workers to process job completion,
- and timeout, gpu reset and gpu hang recovery code. Plus for integration
- with core mm with have &mmu_notifier, respectively &mmu_interval_notifier,
- and &shrinker. For modesetting drivers there's the commit tail functions
- between when fences for an atomic modeset are published, and when the
- corresponding vblank completes, including any interrupt processing and
- related workers. Auditing all that code, across all drivers, is not
- feasible.
- Due to how many other subsystems are involved and the locking hierarchies
- this pulls in there is extremely thin wiggle-room for driver-specific
- differences. &dma_fence interacts with almost all of the core memory
- handling through page fault handlers via &dma_resv, dma_resv_lock() and
- dma_resv_unlock(). On the other side it also interacts through all
- allocation sites through &mmu_notifier and &shrinker.
- Furthermore lockdep does not handle cross-release dependencies, which means
- any deadlocks between dma_fence_wait() and dma_fence_signal() can't be caught
- at runtime with some quick testing. The simplest example is one thread
- waiting on a &dma_fence while holding a lock::
lock(A);
dma_fence_wait(B);
unlock(A);
- while the other thread is stuck trying to acquire the same lock, which
- prevents it from signalling the fence the previous thread is stuck waiting
- on::
lock(A);
unlock(A);
dma_fence_signal(B);
- By manually annotating all code relevant to signalling a &dma_fence we can
- teach lockdep about these dependencies, which also helps with the validation
- headache since now lockdep can check all the rules for us::
- cookie = dma_fence_begin_signalling();
- lock(A);
- unlock(A);
- dma_fence_signal(B);
- dma_fence_end_signalling(cookie);
- For using dma_fence_begin_signalling() and dma_fence_end_signalling() to
- annotate critical sections the following rules need to be observed:
- All code necessary to complete a &dma_fence must be annotated, from the
- point where a fence is accessible to other threads, to the point where
- dma_fence_signal() is called. Un-annotated code can contain deadlock issues,
- and due to the very strict rules and many corner cases it is infeasible to
- catch these just with review or normal stress testing.
- &struct dma_resv deserves a special note, since the readers are only
- protected by rcu. This means the signalling critical section starts as soon
- as the new fences are installed, even before dma_resv_unlock() is called.
- The only exception are fast paths and opportunistic signalling code, which
- calls dma_fence_signal() purely as an optimization, but is not required to
- guarantee completion of a &dma_fence. The usual example is a wait IOCTL
- which calls dma_fence_signal(), while the mandatory completion path goes
- through a hardware interrupt and possible job completion worker.
- To aid composability of code, the annotations can be freely nested, as long
- as the overall locking hierarchy is consistent. The annotations also work
- both in interrupt and process context. Due to implementation details this
- requires that callers pass an opaque cookie from
- dma_fence_begin_signalling() to dma_fence_end_signalling().
- Validation against the cross driver contract is implemented by priming
- lockdep with the relevant hierarchy at boot-up. This means even just
- testing with a single device is enough to validate a driver, at least as
- far as deadlocks with dma_fence_wait() against dma_fence_signal() are
- concerned.
- */
+#ifdef CONFIG_LOCKDEP +struct lockdep_map dma_fence_lockdep_map = {
.name = "dma_fence_map"+};
+/**
- dma_fence_begin_signalling - begin a critical DMA fence signalling section
- Drivers should use this to annotate the beginning of any code section
- required to eventually complete &dma_fence by calling dma_fence_signal().
- The end of these critical sections are annotated with
- dma_fence_end_signalling().
- Returns:
- Opaque cookie needed by the implementation, which needs to be passed to
- dma_fence_end_signalling().
- */
+bool dma_fence_begin_signalling(void) +{
/* explicitly nesting ... */if (lock_is_held_type(&dma_fence_lockdep_map, 1))return true;/* rely on might_sleep check for soft/hardirq locks */if (in_atomic())return true;/* ... and non-recursive readlock */lock_acquire(&dma_fence_lockdep_map, 0, 0, 1, 1, NULL, _RET_IP_);return false;+} +EXPORT_SYMBOL(dma_fence_begin_signalling);
+/**
- dma_fence_end_signalling - end a critical DMA fence signalling section
- Closes a critical section annotation opened by dma_fence_begin_signalling().
- */
+void dma_fence_end_signalling(bool cookie) +{
if (cookie)return;lock_release(&dma_fence_lockdep_map, _RET_IP_);+} +EXPORT_SYMBOL(dma_fence_end_signalling);
+void __dma_fence_might_wait(void) +{
bool tmp;tmp = lock_is_held_type(&dma_fence_lockdep_map, 1);if (tmp)lock_release(&dma_fence_lockdep_map, _THIS_IP_);lock_map_acquire(&dma_fence_lockdep_map);lock_map_release(&dma_fence_lockdep_map);if (tmp)lock_acquire(&dma_fence_lockdep_map, 0, 0, 1, 1, NULL, _THIS_IP_);+} +#endif
- /**
- dma_fence_signal_locked - signal completion of a fence
- @fence: the fence to signal
@@ -170,14 +324,19 @@ int dma_fence_signal(struct dma_fence *fence) { unsigned long flags; int ret;
bool tmp; if (!fence) return -EINVAL;tmp = dma_fence_begin_signalling();spin_lock_irqsave(fence->lock, flags); ret = dma_fence_signal_locked(fence); spin_unlock_irqrestore(fence->lock, flags);dma_fence_end_signalling(tmp);return ret;} EXPORT_SYMBOL(dma_fence_signal);
@@ -210,6 +369,8 @@ dma_fence_wait_timeout(struct dma_fence *fence, bool intr, signed long timeout)
might_sleep();
__dma_fence_might_wait();trace_dma_fence_wait_start(fence); if (fence->ops->wait) ret = fence->ops->wait(fence, intr, timeout);diff --git a/include/linux/dma-fence.h b/include/linux/dma-fence.h index 3347c54f3a87..3f288f7db2ef 100644 --- a/include/linux/dma-fence.h +++ b/include/linux/dma-fence.h @@ -357,6 +357,18 @@ dma_fence_get_rcu_safe(struct dma_fence __rcu **fencep) } while (1); }
+#ifdef CONFIG_LOCKDEP +bool dma_fence_begin_signalling(void); +void dma_fence_end_signalling(bool cookie); +#else +static inline bool dma_fence_begin_signalling(void) +{
return true;+} +static inline void dma_fence_end_signalling(bool cookie) {} +static inline void __dma_fence_might_wait(void) {} +#endif
- int dma_fence_signal(struct dma_fence *fence); int dma_fence_signal_locked(struct dma_fence *fence); signed long dma_fence_default_wait(struct dma_fence *fence,
Quoting Daniel Vetter (2020-06-04 10:21:46)
On Thu, Jun 4, 2020 at 10:57 AM Thomas Hellström (Intel) thomas_os@shipmail.org wrote:
On 6/4/20 10:12 AM, Daniel Vetter wrote: ...
Thread A:
mutex_lock(A); mutex_unlock(A); dma_fence_signal();Thread B:
mutex_lock(A); dma_fence_wait(); mutex_unlock(A);Thread B is blocked on A signalling the fence, but A never gets around to that because it cannot acquire the lock A.
Note that dma_fence_wait() is allowed to be nested within dma_fence_begin/end_signalling sections. To allow this to happen the read lock needs to be upgraded to a write lock, which means that any other lock is acquired between the dma_fence_begin_signalling() call and the call to dma_fence_wait(), and still held, this will result in an immediate lockdep complaint. The only other option would be to not annotate such calls, defeating the point. Therefore these annotations cannot be sprinkled over the code entirely mindless to avoid false positives.
Just realized, isn't that example actually a true positive, or at least a great candidate for a true positive, since if another thread reenters that signaling path, it will block on that mutex, and the fence would never be signaled unless there is another signaling path?
Not sure I understand fully, but I think the answer is "it's complicated".
See cd8084f91c02 ("locking/lockdep: Apply crossrelease to completions")
dma_fence usage here is nothing but another name for a completion. -Chris
On Thu, Jun 4, 2020 at 11:27 AM Chris Wilson chris@chris-wilson.co.uk wrote:
Quoting Daniel Vetter (2020-06-04 10:21:46)
On Thu, Jun 4, 2020 at 10:57 AM Thomas Hellström (Intel) thomas_os@shipmail.org wrote:
On 6/4/20 10:12 AM, Daniel Vetter wrote: ...
Thread A:
mutex_lock(A); mutex_unlock(A); dma_fence_signal();Thread B:
mutex_lock(A); dma_fence_wait(); mutex_unlock(A);Thread B is blocked on A signalling the fence, but A never gets around to that because it cannot acquire the lock A.
Note that dma_fence_wait() is allowed to be nested within dma_fence_begin/end_signalling sections. To allow this to happen the read lock needs to be upgraded to a write lock, which means that any other lock is acquired between the dma_fence_begin_signalling() call and the call to dma_fence_wait(), and still held, this will result in an immediate lockdep complaint. The only other option would be to not annotate such calls, defeating the point. Therefore these annotations cannot be sprinkled over the code entirely mindless to avoid false positives.
Just realized, isn't that example actually a true positive, or at least a great candidate for a true positive, since if another thread reenters that signaling path, it will block on that mutex, and the fence would never be signaled unless there is another signaling path?
Not sure I understand fully, but I think the answer is "it's complicated".
See cd8084f91c02 ("locking/lockdep: Apply crossrelease to completions")
dma_fence usage here is nothing but another name for a completion.
Quoting from my previous cover letter:
"I've dragged my feet for years on this, hoping that cross-release lockdep would do this for us, but well that never really happened unfortunately. So here we are."
I discussed this with Peter, cross-release not getting in is pretty final it seems. The trouble is false positives without explicit begin/end annotations reviewed by humans - ime from just these few examples you just can't guess this stuff by computeres, you need real brains thinking about all the edge cases, and where exactly the critical section starts and ends. Without that you're just going to drown in a sea of false positives and yuck.
So yeah I had hopes for cross-release too, unfortunately that was entirely in vain and a distraction.
Now I guess it would be nice if there's a per-class completion_begin/end annotation for the more generic problem. But then also most people don't have a cross-driver completion api contract like dma_fence is, with some of the most ridiculous over the top constraints of what's possible and what's not possible on each side of the cross-release. We do have a bit an outsized benefit (in pain reduction) vs cost ratio here. -Daniel
linaro-mm-sig@lists.linaro.org
-
Chris Wilson -
Daniel Vetter