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This document describes the concept of crossrelease feature. Signed-off-by: Byungchul Park <byungchul.park@lge.com> Signed-off-by: Peter Zijlstra (Intel) <peterz@infradead.org> Cc: Linus Torvalds <torvalds@linux-foundation.org> Cc: Peter Zijlstra <peterz@infradead.org> Cc: Thomas Gleixner <tglx@linutronix.de> Cc: akpm@linux-foundation.org Cc: boqun.feng@gmail.com Cc: kernel-team@lge.com Cc: kirill@shutemov.name Cc: npiggin@gmail.com Cc: walken@google.com Cc: willy@infradead.org Link: http://lkml.kernel.org/r/1502089981-21272-15-git-send-email-byungchul.park@lge.com Signed-off-by: Ingo Molnar <mingo@kernel.org>
875 lines
26 KiB
Plaintext
875 lines
26 KiB
Plaintext
Crossrelease
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============
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Started by Byungchul Park <byungchul.park@lge.com>
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Contents:
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(*) Background
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- What causes deadlock
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- How lockdep works
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(*) Limitation
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- Limit lockdep
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- Pros from the limitation
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- Cons from the limitation
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- Relax the limitation
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(*) Crossrelease
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- Introduce crossrelease
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- Introduce commit
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(*) Implementation
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- Data structures
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- How crossrelease works
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(*) Optimizations
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- Avoid duplication
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- Lockless for hot paths
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(*) APPENDIX A: What lockdep does to work aggresively
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(*) APPENDIX B: How to avoid adding false dependencies
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==========
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Background
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==========
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What causes deadlock
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--------------------
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A deadlock occurs when a context is waiting for an event to happen,
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which is impossible because another (or the) context who can trigger the
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event is also waiting for another (or the) event to happen, which is
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also impossible due to the same reason.
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For example:
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A context going to trigger event C is waiting for event A to happen.
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A context going to trigger event A is waiting for event B to happen.
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A context going to trigger event B is waiting for event C to happen.
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A deadlock occurs when these three wait operations run at the same time,
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because event C cannot be triggered if event A does not happen, which in
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turn cannot be triggered if event B does not happen, which in turn
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cannot be triggered if event C does not happen. After all, no event can
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be triggered since any of them never meets its condition to wake up.
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A dependency might exist between two waiters and a deadlock might happen
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due to an incorrect releationship between dependencies. Thus, we must
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define what a dependency is first. A dependency exists between them if:
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1. There are two waiters waiting for each event at a given time.
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2. The only way to wake up each waiter is to trigger its event.
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3. Whether one can be woken up depends on whether the other can.
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Each wait in the example creates its dependency like:
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Event C depends on event A.
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Event A depends on event B.
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Event B depends on event C.
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NOTE: Precisely speaking, a dependency is one between whether a
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waiter for an event can be woken up and whether another waiter for
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another event can be woken up. However from now on, we will describe
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a dependency as if it's one between an event and another event for
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simplicity.
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And they form circular dependencies like:
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-> C -> A -> B -
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/ \
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\ /
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----------------
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where 'A -> B' means that event A depends on event B.
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Such circular dependencies lead to a deadlock since no waiter can meet
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its condition to wake up as described.
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CONCLUSION
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Circular dependencies cause a deadlock.
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How lockdep works
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-----------------
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Lockdep tries to detect a deadlock by checking dependencies created by
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lock operations, acquire and release. Waiting for a lock corresponds to
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waiting for an event, and releasing a lock corresponds to triggering an
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event in the previous section.
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In short, lockdep does:
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1. Detect a new dependency.
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2. Add the dependency into a global graph.
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3. Check if that makes dependencies circular.
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4. Report a deadlock or its possibility if so.
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For example, consider a graph built by lockdep that looks like:
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A -> B -
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\
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-> E
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/
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C -> D -
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where A, B,..., E are different lock classes.
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Lockdep will add a dependency into the graph on detection of a new
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dependency. For example, it will add a dependency 'E -> C' when a new
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dependency between lock E and lock C is detected. Then the graph will be:
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A -> B -
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\
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-> E -
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/ \
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-> C -> D - \
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/ /
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\ /
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------------------
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where A, B,..., E are different lock classes.
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This graph contains a subgraph which demonstrates circular dependencies:
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-> E -
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/ \
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-> C -> D - \
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/ /
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\ /
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------------------
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where C, D and E are different lock classes.
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This is the condition under which a deadlock might occur. Lockdep
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reports it on detection after adding a new dependency. This is the way
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how lockdep works.
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CONCLUSION
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Lockdep detects a deadlock or its possibility by checking if circular
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dependencies were created after adding each new dependency.
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==========
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Limitation
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==========
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Limit lockdep
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-------------
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Limiting lockdep to work on only typical locks e.g. spin locks and
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mutexes, which are released within the acquire context, the
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implementation becomes simple but its capacity for detection becomes
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limited. Let's check pros and cons in next section.
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Pros from the limitation
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------------------------
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Given the limitation, when acquiring a lock, locks in a held_locks
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cannot be released if the context cannot acquire it so has to wait to
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acquire it, which means all waiters for the locks in the held_locks are
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stuck. It's an exact case to create dependencies between each lock in
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the held_locks and the lock to acquire.
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For example:
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CONTEXT X
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---------
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acquire A
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acquire B /* Add a dependency 'A -> B' */
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release B
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release A
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where A and B are different lock classes.
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When acquiring lock A, the held_locks of CONTEXT X is empty thus no
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dependency is added. But when acquiring lock B, lockdep detects and adds
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a new dependency 'A -> B' between lock A in the held_locks and lock B.
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They can be simply added whenever acquiring each lock.
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And data required by lockdep exists in a local structure, held_locks
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embedded in task_struct. Forcing to access the data within the context,
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lockdep can avoid racy problems without explicit locks while handling
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the local data.
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Lastly, lockdep only needs to keep locks currently being held, to build
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a dependency graph. However, relaxing the limitation, it needs to keep
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even locks already released, because a decision whether they created
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dependencies might be long-deferred.
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To sum up, we can expect several advantages from the limitation:
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1. Lockdep can easily identify a dependency when acquiring a lock.
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2. Races are avoidable while accessing local locks in a held_locks.
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3. Lockdep only needs to keep locks currently being held.
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CONCLUSION
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Given the limitation, the implementation becomes simple and efficient.
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Cons from the limitation
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------------------------
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Given the limitation, lockdep is applicable only to typical locks. For
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example, page locks for page access or completions for synchronization
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cannot work with lockdep.
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Can we detect deadlocks below, under the limitation?
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Example 1:
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CONTEXT X CONTEXT Y CONTEXT Z
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--------- --------- ----------
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mutex_lock A
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lock_page B
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lock_page B
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mutex_lock A /* DEADLOCK */
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unlock_page B held by X
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unlock_page B
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mutex_unlock A
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mutex_unlock A
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where A and B are different lock classes.
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No, we cannot.
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Example 2:
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CONTEXT X CONTEXT Y
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--------- ---------
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mutex_lock A
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mutex_lock A
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wait_for_complete B /* DEADLOCK */
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complete B
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mutex_unlock A
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mutex_unlock A
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where A is a lock class and B is a completion variable.
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No, we cannot.
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CONCLUSION
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Given the limitation, lockdep cannot detect a deadlock or its
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possibility caused by page locks or completions.
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Relax the limitation
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--------------------
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Under the limitation, things to create dependencies are limited to
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typical locks. However, synchronization primitives like page locks and
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completions, which are allowed to be released in any context, also
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create dependencies and can cause a deadlock. So lockdep should track
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these locks to do a better job. We have to relax the limitation for
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these locks to work with lockdep.
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Detecting dependencies is very important for lockdep to work because
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adding a dependency means adding an opportunity to check whether it
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causes a deadlock. The more lockdep adds dependencies, the more it
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thoroughly works. Thus Lockdep has to do its best to detect and add as
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many true dependencies into a graph as possible.
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For example, considering only typical locks, lockdep builds a graph like:
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A -> B -
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\
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-> E
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/
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C -> D -
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where A, B,..., E are different lock classes.
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On the other hand, under the relaxation, additional dependencies might
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be created and added. Assuming additional 'FX -> C' and 'E -> GX' are
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added thanks to the relaxation, the graph will be:
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A -> B -
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\
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-> E -> GX
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/
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FX -> C -> D -
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where A, B,..., E, FX and GX are different lock classes, and a suffix
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'X' is added on non-typical locks.
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The latter graph gives us more chances to check circular dependencies
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than the former. However, it might suffer performance degradation since
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relaxing the limitation, with which design and implementation of lockdep
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can be efficient, might introduce inefficiency inevitably. So lockdep
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should provide two options, strong detection and efficient detection.
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Choosing efficient detection:
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Lockdep works with only locks restricted to be released within the
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acquire context. However, lockdep works efficiently.
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Choosing strong detection:
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Lockdep works with all synchronization primitives. However, lockdep
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suffers performance degradation.
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CONCLUSION
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Relaxing the limitation, lockdep can add additional dependencies giving
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additional opportunities to check circular dependencies.
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============
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Crossrelease
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============
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Introduce crossrelease
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----------------------
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In order to allow lockdep to handle additional dependencies by what
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might be released in any context, namely 'crosslock', we have to be able
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to identify those created by crosslocks. The proposed 'crossrelease'
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feature provoides a way to do that.
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Crossrelease feature has to do:
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1. Identify dependencies created by crosslocks.
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2. Add the dependencies into a dependency graph.
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That's all. Once a meaningful dependency is added into graph, then
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lockdep would work with the graph as it did. The most important thing
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crossrelease feature has to do is to correctly identify and add true
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dependencies into the global graph.
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A dependency e.g. 'A -> B' can be identified only in the A's release
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context because a decision required to identify the dependency can be
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made only in the release context. That is to decide whether A can be
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released so that a waiter for A can be woken up. It cannot be made in
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other than the A's release context.
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It's no matter for typical locks because each acquire context is same as
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its release context, thus lockdep can decide whether a lock can be
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released in the acquire context. However for crosslocks, lockdep cannot
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make the decision in the acquire context but has to wait until the
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release context is identified.
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Therefore, deadlocks by crosslocks cannot be detected just when it
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happens, because those cannot be identified until the crosslocks are
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released. However, deadlock possibilities can be detected and it's very
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worth. See 'APPENDIX A' section to check why.
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CONCLUSION
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Using crossrelease feature, lockdep can work with what might be released
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in any context, namely crosslock.
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Introduce commit
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----------------
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Since crossrelease defers the work adding true dependencies of
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crosslocks until they are actually released, crossrelease has to queue
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all acquisitions which might create dependencies with the crosslocks.
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Then it identifies dependencies using the queued data in batches at a
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proper time. We call it 'commit'.
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There are four types of dependencies:
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1. TT type: 'typical lock A -> typical lock B'
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Just when acquiring B, lockdep can see it's in the A's release
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context. So the dependency between A and B can be identified
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immediately. Commit is unnecessary.
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2. TC type: 'typical lock A -> crosslock BX'
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Just when acquiring BX, lockdep can see it's in the A's release
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context. So the dependency between A and BX can be identified
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immediately. Commit is unnecessary, too.
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3. CT type: 'crosslock AX -> typical lock B'
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When acquiring B, lockdep cannot identify the dependency because
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there's no way to know if it's in the AX's release context. It has
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to wait until the decision can be made. Commit is necessary.
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4. CC type: 'crosslock AX -> crosslock BX'
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When acquiring BX, lockdep cannot identify the dependency because
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there's no way to know if it's in the AX's release context. It has
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to wait until the decision can be made. Commit is necessary.
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But, handling CC type is not implemented yet. It's a future work.
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Lockdep can work without commit for typical locks, but commit step is
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necessary once crosslocks are involved. Introducing commit, lockdep
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performs three steps. What lockdep does in each step is:
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1. Acquisition: For typical locks, lockdep does what it originally did
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and queues the lock so that CT type dependencies can be checked using
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it at the commit step. For crosslocks, it saves data which will be
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used at the commit step and increases a reference count for it.
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2. Commit: No action is reauired for typical locks. For crosslocks,
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lockdep adds CT type dependencies using the data saved at the
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acquisition step.
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3. Release: No changes are required for typical locks. When a crosslock
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is released, it decreases a reference count for it.
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CONCLUSION
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Crossrelease introduces commit step to handle dependencies of crosslocks
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in batches at a proper time.
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==============
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Implementation
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==============
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Data structures
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---------------
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Crossrelease introduces two main data structures.
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1. hist_lock
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This is an array embedded in task_struct, for keeping lock history so
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that dependencies can be added using them at the commit step. Since
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it's local data, it can be accessed locklessly in the owner context.
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The array is filled at the acquisition step and consumed at the
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commit step. And it's managed in circular manner.
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2. cross_lock
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One per lockdep_map exists. This is for keeping data of crosslocks
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and used at the commit step.
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How crossrelease works
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----------------------
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It's the key of how crossrelease works, to defer necessary works to an
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appropriate point in time and perform in at once at the commit step.
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Let's take a look with examples step by step, starting from how lockdep
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works without crossrelease for typical locks.
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acquire A /* Push A onto held_locks */
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acquire B /* Push B onto held_locks and add 'A -> B' */
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acquire C /* Push C onto held_locks and add 'B -> C' */
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release C /* Pop C from held_locks */
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release B /* Pop B from held_locks */
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release A /* Pop A from held_locks */
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where A, B and C are different lock classes.
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NOTE: This document assumes that readers already understand how
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lockdep works without crossrelease thus omits details. But there's
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one thing to note. Lockdep pretends to pop a lock from held_locks
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when releasing it. But it's subtly different from the original pop
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operation because lockdep allows other than the top to be poped.
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In this case, lockdep adds 'the top of held_locks -> the lock to acquire'
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dependency every time acquiring a lock.
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After adding 'A -> B', a dependency graph will be:
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A -> B
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where A and B are different lock classes.
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And after adding 'B -> C', the graph will be:
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A -> B -> C
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where A, B and C are different lock classes.
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Let's performs commit step even for typical locks to add dependencies.
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Of course, commit step is not necessary for them, however, it would work
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well because this is a more general way.
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acquire A
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/*
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* Queue A into hist_locks
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*
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* In hist_locks: A
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* In graph: Empty
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*/
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acquire B
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/*
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* Queue B into hist_locks
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*
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* In hist_locks: A, B
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* In graph: Empty
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*/
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acquire C
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/*
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* Queue C into hist_locks
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*
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* In hist_locks: A, B, C
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* In graph: Empty
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*/
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commit C
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/*
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* Add 'C -> ?'
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* Answer the following to decide '?'
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* What has been queued since acquire C: Nothing
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*
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* In hist_locks: A, B, C
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* In graph: Empty
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*/
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release C
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commit B
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/*
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* Add 'B -> ?'
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* Answer the following to decide '?'
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* What has been queued since acquire B: C
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*
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* In hist_locks: A, B, C
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* In graph: 'B -> C'
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*/
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release B
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commit A
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/*
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* Add 'A -> ?'
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* Answer the following to decide '?'
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* What has been queued since acquire A: B, C
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*
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* In hist_locks: A, B, C
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* In graph: 'B -> C', 'A -> B', 'A -> C'
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*/
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release A
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where A, B and C are different lock classes.
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In this case, dependencies are added at the commit step as described.
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After commits for A, B and C, the graph will be:
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A -> B -> C
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where A, B and C are different lock classes.
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NOTE: A dependency 'A -> C' is optimized out.
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We can see the former graph built without commit step is same as the
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latter graph built using commit steps. Of course the former way leads to
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earlier finish for building the graph, which means we can detect a
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deadlock or its possibility sooner. So the former way would be prefered
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when possible. But we cannot avoid using the latter way for crosslocks.
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Let's look at how commit steps work for crosslocks. In this case, the
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commit step is performed only on crosslock AX as real. And it assumes
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|
that the AX release context is different from the AX acquire context.
|
|
|
|
BX RELEASE CONTEXT BX ACQUIRE CONTEXT
|
|
------------------ ------------------
|
|
acquire A
|
|
/*
|
|
* Push A onto held_locks
|
|
* Queue A into hist_locks
|
|
*
|
|
* In held_locks: A
|
|
* In hist_locks: A
|
|
* In graph: Empty
|
|
*/
|
|
|
|
acquire BX
|
|
/*
|
|
* Add 'the top of held_locks -> BX'
|
|
*
|
|
* In held_locks: A
|
|
* In hist_locks: A
|
|
* In graph: 'A -> BX'
|
|
*/
|
|
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
It must be guaranteed that the following operations are seen after
|
|
acquiring BX globally. It can be done by things like barrier.
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
acquire C
|
|
/*
|
|
* Push C onto held_locks
|
|
* Queue C into hist_locks
|
|
*
|
|
* In held_locks: C
|
|
* In hist_locks: C
|
|
* In graph: 'A -> BX'
|
|
*/
|
|
|
|
release C
|
|
/*
|
|
* Pop C from held_locks
|
|
*
|
|
* In held_locks: Empty
|
|
* In hist_locks: C
|
|
* In graph: 'A -> BX'
|
|
*/
|
|
acquire D
|
|
/*
|
|
* Push D onto held_locks
|
|
* Queue D into hist_locks
|
|
* Add 'the top of held_locks -> D'
|
|
*
|
|
* In held_locks: A, D
|
|
* In hist_locks: A, D
|
|
* In graph: 'A -> BX', 'A -> D'
|
|
*/
|
|
acquire E
|
|
/*
|
|
* Push E onto held_locks
|
|
* Queue E into hist_locks
|
|
*
|
|
* In held_locks: E
|
|
* In hist_locks: C, E
|
|
* In graph: 'A -> BX', 'A -> D'
|
|
*/
|
|
|
|
release E
|
|
/*
|
|
* Pop E from held_locks
|
|
*
|
|
* In held_locks: Empty
|
|
* In hist_locks: D, E
|
|
* In graph: 'A -> BX', 'A -> D'
|
|
*/
|
|
release D
|
|
/*
|
|
* Pop D from held_locks
|
|
*
|
|
* In held_locks: A
|
|
* In hist_locks: A, D
|
|
* In graph: 'A -> BX', 'A -> D'
|
|
*/
|
|
commit BX
|
|
/*
|
|
* Add 'BX -> ?'
|
|
* What has been queued since acquire BX: C, E
|
|
*
|
|
* In held_locks: Empty
|
|
* In hist_locks: D, E
|
|
* In graph: 'A -> BX', 'A -> D',
|
|
* 'BX -> C', 'BX -> E'
|
|
*/
|
|
|
|
release BX
|
|
/*
|
|
* In held_locks: Empty
|
|
* In hist_locks: D, E
|
|
* In graph: 'A -> BX', 'A -> D',
|
|
* 'BX -> C', 'BX -> E'
|
|
*/
|
|
release A
|
|
/*
|
|
* Pop A from held_locks
|
|
*
|
|
* In held_locks: Empty
|
|
* In hist_locks: A, D
|
|
* In graph: 'A -> BX', 'A -> D',
|
|
* 'BX -> C', 'BX -> E'
|
|
*/
|
|
|
|
where A, BX, C,..., E are different lock classes, and a suffix 'X' is
|
|
added on crosslocks.
|
|
|
|
Crossrelease considers all acquisitions after acqiuring BX are
|
|
candidates which might create dependencies with BX. True dependencies
|
|
will be determined when identifying the release context of BX. Meanwhile,
|
|
all typical locks are queued so that they can be used at the commit step.
|
|
And then two dependencies 'BX -> C' and 'BX -> E' are added at the
|
|
commit step when identifying the release context.
|
|
|
|
The final graph will be, with crossrelease:
|
|
|
|
-> C
|
|
/
|
|
-> BX -
|
|
/ \
|
|
A - -> E
|
|
\
|
|
-> D
|
|
|
|
where A, BX, C,..., E are different lock classes, and a suffix 'X' is
|
|
added on crosslocks.
|
|
|
|
However, the final graph will be, without crossrelease:
|
|
|
|
A -> D
|
|
|
|
where A and D are different lock classes.
|
|
|
|
The former graph has three more dependencies, 'A -> BX', 'BX -> C' and
|
|
'BX -> E' giving additional opportunities to check if they cause
|
|
deadlocks. This way lockdep can detect a deadlock or its possibility
|
|
caused by crosslocks.
|
|
|
|
CONCLUSION
|
|
|
|
We checked how crossrelease works with several examples.
|
|
|
|
|
|
=============
|
|
Optimizations
|
|
=============
|
|
|
|
Avoid duplication
|
|
-----------------
|
|
|
|
Crossrelease feature uses a cache like what lockdep already uses for
|
|
dependency chains, but this time it's for caching CT type dependencies.
|
|
Once that dependency is cached, the same will never be added again.
|
|
|
|
|
|
Lockless for hot paths
|
|
----------------------
|
|
|
|
To keep all locks for later use at the commit step, crossrelease adopts
|
|
a local array embedded in task_struct, which makes access to the data
|
|
lockless by forcing it to happen only within the owner context. It's
|
|
like how lockdep handles held_locks. Lockless implmentation is important
|
|
since typical locks are very frequently acquired and released.
|
|
|
|
|
|
=================================================
|
|
APPENDIX A: What lockdep does to work aggresively
|
|
=================================================
|
|
|
|
A deadlock actually occurs when all wait operations creating circular
|
|
dependencies run at the same time. Even though they don't, a potential
|
|
deadlock exists if the problematic dependencies exist. Thus it's
|
|
meaningful to detect not only an actual deadlock but also its potential
|
|
possibility. The latter is rather valuable. When a deadlock occurs
|
|
actually, we can identify what happens in the system by some means or
|
|
other even without lockdep. However, there's no way to detect possiblity
|
|
without lockdep unless the whole code is parsed in head. It's terrible.
|
|
Lockdep does the both, and crossrelease only focuses on the latter.
|
|
|
|
Whether or not a deadlock actually occurs depends on several factors.
|
|
For example, what order contexts are switched in is a factor. Assuming
|
|
circular dependencies exist, a deadlock would occur when contexts are
|
|
switched so that all wait operations creating the dependencies run
|
|
simultaneously. Thus to detect a deadlock possibility even in the case
|
|
that it has not occured yet, lockdep should consider all possible
|
|
combinations of dependencies, trying to:
|
|
|
|
1. Use a global dependency graph.
|
|
|
|
Lockdep combines all dependencies into one global graph and uses them,
|
|
regardless of which context generates them or what order contexts are
|
|
switched in. Aggregated dependencies are only considered so they are
|
|
prone to be circular if a problem exists.
|
|
|
|
2. Check dependencies between classes instead of instances.
|
|
|
|
What actually causes a deadlock are instances of lock. However,
|
|
lockdep checks dependencies between classes instead of instances.
|
|
This way lockdep can detect a deadlock which has not happened but
|
|
might happen in future by others but the same class.
|
|
|
|
3. Assume all acquisitions lead to waiting.
|
|
|
|
Although locks might be acquired without waiting which is essential
|
|
to create dependencies, lockdep assumes all acquisitions lead to
|
|
waiting since it might be true some time or another.
|
|
|
|
CONCLUSION
|
|
|
|
Lockdep detects not only an actual deadlock but also its possibility,
|
|
and the latter is more valuable.
|
|
|
|
|
|
==================================================
|
|
APPENDIX B: How to avoid adding false dependencies
|
|
==================================================
|
|
|
|
Remind what a dependency is. A dependency exists if:
|
|
|
|
1. There are two waiters waiting for each event at a given time.
|
|
2. The only way to wake up each waiter is to trigger its event.
|
|
3. Whether one can be woken up depends on whether the other can.
|
|
|
|
For example:
|
|
|
|
acquire A
|
|
acquire B /* A dependency 'A -> B' exists */
|
|
release B
|
|
release A
|
|
|
|
where A and B are different lock classes.
|
|
|
|
A depedency 'A -> B' exists since:
|
|
|
|
1. A waiter for A and a waiter for B might exist when acquiring B.
|
|
2. Only way to wake up each is to release what it waits for.
|
|
3. Whether the waiter for A can be woken up depends on whether the
|
|
other can. IOW, TASK X cannot release A if it fails to acquire B.
|
|
|
|
For another example:
|
|
|
|
TASK X TASK Y
|
|
------ ------
|
|
acquire AX
|
|
acquire B /* A dependency 'AX -> B' exists */
|
|
release B
|
|
release AX held by Y
|
|
|
|
where AX and B are different lock classes, and a suffix 'X' is added
|
|
on crosslocks.
|
|
|
|
Even in this case involving crosslocks, the same rule can be applied. A
|
|
depedency 'AX -> B' exists since:
|
|
|
|
1. A waiter for AX and a waiter for B might exist when acquiring B.
|
|
2. Only way to wake up each is to release what it waits for.
|
|
3. Whether the waiter for AX can be woken up depends on whether the
|
|
other can. IOW, TASK X cannot release AX if it fails to acquire B.
|
|
|
|
Let's take a look at more complicated example:
|
|
|
|
TASK X TASK Y
|
|
------ ------
|
|
acquire B
|
|
release B
|
|
fork Y
|
|
acquire AX
|
|
acquire C /* A dependency 'AX -> C' exists */
|
|
release C
|
|
release AX held by Y
|
|
|
|
where AX, B and C are different lock classes, and a suffix 'X' is
|
|
added on crosslocks.
|
|
|
|
Does a dependency 'AX -> B' exist? Nope.
|
|
|
|
Two waiters are essential to create a dependency. However, waiters for
|
|
AX and B to create 'AX -> B' cannot exist at the same time in this
|
|
example. Thus the dependency 'AX -> B' cannot be created.
|
|
|
|
It would be ideal if the full set of true ones can be considered. But
|
|
we can ensure nothing but what actually happened. Relying on what
|
|
actually happens at runtime, we can anyway add only true ones, though
|
|
they might be a subset of true ones. It's similar to how lockdep works
|
|
for typical locks. There might be more true dependencies than what
|
|
lockdep has detected in runtime. Lockdep has no choice but to rely on
|
|
what actually happens. Crossrelease also relies on it.
|
|
|
|
CONCLUSION
|
|
|
|
Relying on what actually happens, lockdep can avoid adding false
|
|
dependencies.
|