(Copy more people)
On Wed, Apr 11, 2018 at 09:50:51PM +0800, Boqun Feng wrote:
> This patch add the documentation piece for the reasoning of deadlock
> detection related to recursive read lock. The following sections are
> added:
>
> * Explain what is a recursive read lock, and what deadlock cases
> they could introduce.
>
> * Introduce the notations for different types of dependencies, and
> the definition of strong paths.
>
> * Proof for a closed strong path is both sufficient and necessary
> for deadlock detections with recursive read locks involved. The
> proof could also explain why we call the path "strong"
>
> Signed-off-by: Boqun Feng
> ---
> Documentation/locking/lockdep-design.txt | 178 +++++++++++++++++++++++++++++++
> 1 file changed, 178 insertions(+)
>
> diff --git a/Documentation/locking/lockdep-design.txt b/Documentation/locking/lockdep-design.txt
> index 9de1c158d44c..6bb9e90e2c4f 100644
> --- a/Documentation/locking/lockdep-design.txt
> +++ b/Documentation/locking/lockdep-design.txt
> @@ -284,3 +284,181 @@ Run the command and save the output, then compare against the output from
> a later run of this command to identify the leakers. This same output
> can also help you find situations where runtime lock initialization has
> been omitted.
> +
> +Recursive read locks:
> +---------------------
> +
> +Lockdep now is equipped with deadlock detection for recursive read locks.
> +
> +Recursive read locks, as their name indicates, are the locks able to be
> +acquired recursively. Unlike non-recursive read locks, recursive read locks
> +only get blocked by current write lock *holders* other than write lock
> +*waiters*, for example:
> +
> + TASK A: TASK B:
> +
> + read_lock(X);
> +
> + write_lock(X);
> +
> + read_lock(X);
> +
> +is not a deadlock for recursive read locks, as while the task B is waiting for
> +the lock X, the second read_lock() doesn't need to wait because it's a recursive
> +read lock. However if the read_lock() is non-recursive read lock, then the above
> +case is a deadlock, because even if the write_lock() in TASK B can not get the
> +lock, but it can block the second read_lock() in TASK A.
> +
> +Note that a lock can be a write lock (exclusive lock), a non-recursive read
> +lock (non-recursive shared lock) or a recursive read lock (recursive shared
> +lock), depending on the lock operations used to acquire it (more specifically,
> +the value of the 'read' parameter for lock_acquire()). In other words, a single
> +lock instance has three types of acquisition depending on the acquisition
> +functions: exclusive, non-recursive read, and recursive read.
> +
> +To be concise, we call that write locks and non-recursive read locks as
> +"non-recursive" locks and recursive read locks as "recursive" locks.
> +
> +Recursive locks don't block each other, while non-recursive locks do (this is
> +even true for two non-recursive read locks). A non-recursive lock can block the
> +corresponding recursive lock, and vice versa.
> +
> +A deadlock case with recursive locks involved is as follow:
> +
> + TASK A: TASK B:
> +
> + read_lock(X);
> + read_lock(Y);
> + write_lock(Y);
> + write_lock(X);
> +
> +Task A is waiting for task B to read_unlock() Y and task B is waiting for task
> +A to read_unlock() X.
> +
> +Dependency types and strong dependency paths:
> +---------------------------------------------
> +In order to detect deadlocks as above, lockdep needs to track different dependencies.
> +There are 4 categories for dependency edges in the lockdep graph:
> +
> +1) -(NN)->: non-recursive to non-recursive dependency. "X -(NN)-> Y" means
> + X -> Y and both X and Y are non-recursive locks.
> +
> +2) -(RN)->: recursive to non-recursive dependency. "X -(RN)-> Y" means
> + X -> Y and X is recursive read lock and Y is non-recursive lock.
> +
> +3) -(NR)->: non-recursive to recursive dependency, "X -(NR)-> Y" means
> + X -> Y and X is non-recursive lock and Y is recursive lock.
> +
> +4) -(RR)->: recursive to recursive dependency, "X -(RR)-> Y" means
> + X -> Y and both X and Y are recursive locks.
> +
> +Note that given two locks, they may have multiple dependencies between them, for example:
> +
> + TASK A:
> +
> + read_lock(X);
> + write_lock(Y);
> + ...
> +
> + TASK B:
> +
> + write_lock(X);
> + write_lock(Y);
> +
> +, we have both X -(RN)-> Y and X -(NN)-> Y in the dependency graph.
> +
> +We use -(*N)-> for edges that is either -(RN)-> or -(NN)->, the similar for -(N*)->,
> +-(*R)-> and -(R*)->
> +
> +A "path" is a series of conjunct dependency edges in the graph. And we define a
> +"strong" path, which indicates the strong dependency throughout each dependency
> +in the path, as the path that doesn't have two conjunct edges (dependencies) as
> +-(*R)-> and -(R*)->. In other words, a "strong" path is a path from a lock
> +walking to another through the lock dependencies, and if X -> Y -> Z in the
> +path (where X, Y, Z are locks), if the walk from X to Y is through a -(NR)-> or
> +-(RR)-> dependency, the walk from Y to Z must not be through a -(RN)-> or
> +-(RR)-> dependency, otherwise it's not a strong path.
> +
So Matthew's request for better deadlock detection for rwlock can be
solved by:
https://marc.info/?l=linux-kernel&m=152483640529740&w=2k
However, that will bring up a new challenge for the deadlock detection
of recursive read locks. Because in my previous design, I assumed that
a lock cannot have both non-recursive readers and recursive readers.
With that assumption, the definition of "strong" path works.
Now since rwlock_t may have both non-recursive readers and recursive
readers, then we have more interesting cases:
Case 1:
read_lock(&A);
spin_lock_irq(&B);
spin_lock(&B); // recursive
read_lock(&A);
, is a deadlock. And we have circle A -(RN)-> B -(NN)-> A (note that "N"
stands for non-recursive).
Case 2:
spin_lock(&A);
read_lock(&B);
read_lock(&A); // recursive
spin_lock_irq(&B);
, is not a deadlock, even if we have circle A -(NR)-> B -(NN)-> A.
So we need to redefine "strong" path, because the block conditions
change between non-recursive locks and recursive locks: a recursive
readers can block a non-recursive readers, while a non-recursive readers
cannot block a recursive readers.
Let's mark non-recursive readers as S (shared) and writers as W, then
the "strong" path is a path without conjunct edges as -(*R)-> -(S*)-> or
-(*R)-> -(R*)->, we can prove this with similar reasoning based on the
new block conditions.
And luckily enough, we don't need to change the code too much, because
we can, rather than record RR RN NR NN, record
1) -(R/S N)->: the first lock is reader (recursive or not) and the
second is non-recursive (writer or non-recursive
reader)
2) -(R/S R)->: the first lock is reader and the second is recursive
3) -(W N)->: the first lock is writer and the second is non-recursive
4) -(W R)->: the first lock is writer and the second is recursive
, and a "strong" path is a path without conjunct edges -(*R) -(R/S*)->.
As a result, only a bit code needs to be changed, and I have already
done that in a local branch (though a lot of documention updates are
needed and I haven't done that yet for the new version).
There remains two questions before I make a move:
1. Changing the annotation for queued rwlocks needs extra work for
lockdep self test cases, but could help reveal more bugs. Do
people want this very soon?
2. Or we can focus on deadlock detections for recursive read locks
first? And if we get it settled, we can move to annotate queued
rwlocks properly.
I ask because doing those two together seems too big for a patchset, and
probably both will introduce some regression, so..
Thoughts?
Regards,
Boqun
> +We will see why the path is called "strong" in next section.
> +
> +Recursive Read Deadlock Detection:
> +----------------------------------
> +
> +We now prove two things:
> +
> +Lemma 1:
> +
> +If there is a closed strong path (i.e. a strong cirle), then there is a
> +combination of locking sequences that causes deadlock. I.e. a strong circle is
> +sufficient for deadlock detection.
> +
> +Lemma 2:
> +
> +If there is no closed strong path (i.e. strong cirle), then there is no
> +combination of locking sequences that could cause deadlock. I.e. strong
> +circles are necessary for deadlock detection.
> +
> +With these two Lemmas, we can easily say a closed strong path is both sufficient
> +and necessary for deadlocks, therefore a closed strong path is equivalent to
> +deadlock possibility. As a closed strong path stands for a dependency chain that
> +could cause deadlocks, so we call it "strong", considering there are dependency
> +circles that won't cause deadlocks.
> +
> +Proof for sufficiency (Lemma 1):
> +
> +Let's say we have a strong cirlce:
> +
> + L1 -> L2 ... -> Ln -> L1
> +
> +, which means we have dependencies:
> +
> + L1 -> L2
> + L2 -> L3
> + ...
> + Ln-1 -> Ln
> + Ln -> L1
> +
> +We now can construct a combination of locking sequences that cause deadlock:
> +
> +Firstly let's make one CPU/task get the L1 in L1 -> L2, and then another get
> +the L2 in L2 -> L3, and so on. After this, all of the Lx in Lx -> Lx+1 are
> +held by different CPU/tasks.
> +
> +And then because we have L1 -> L2, so the holder of L1 is going to acquire L2
> +in L1 -> L2, however since L2 is already held by another CPU/task, plus L1 ->
> +L2 and L2 -> L3 are not *R and R* (the definition of strong), therefore the
> +holder of L1 can not get L2, it has to wait L2's holder to release.
> +
> +Moreover, we can have a similar conclusion for L2's holder: it has to wait L3's
> +holder to release, and so on. We now can proof that Lx's holder has to wait for
> +Lx+1's holder to release, and note that Ln+1 is L1, so we have a circular
> +waiting scenario and nobody can get progress, therefore a deadlock.
> +
> +Proof for necessary (Lemma 2):
> +
> +Lemma 2 is equivalent to: If there is a deadlock scenario, then there must be a
> +strong circle in the dependency graph.
> +
> +According to Wikipedia[1], if there is a deadlock, then there must be a circular
> +waiting scenario, means there are N CPU/tasks, where CPU/task P1 is waiting for
> +a lock held by P2, and P2 is waiting for a lock held by P3, ... and Pn is waiting
> +for a lock held by P1. Let's name the lock Px is waiting as Lx, so since P1 is waiting
> +for L1 and holding Ln, so we will have Ln -> L1 in the dependency graph. Similarly,
> +we have L1 -> L2, L2 -> L3, ..., Ln-1 -> Ln in the dependency graph, which means we
> +have a circle:
> +
> + Ln -> L1 -> L2 -> ... -> Ln
> +
> +, and now let's prove the circle is strong:
> +
> +For a lock Lx, Px contributes the dependency Lx-1 -> Lx and Px+1 contributes
> +the dependency Lx -> Lx+1, and since Px is waiting for Px+1 to release Lx,
> +so Lx can not be both recursive in Lx -> Lx+1 and Lx-1 -> Lx, because recursive
> +locks don't block each other, therefore Lx-1 -> Lx and Lx -> Lx+1 can not be a
> +-(*R)-> -(R*)-> pair, and this is true for any lock in the circle, therefore,
> +the circle is strong.
> +
> +References:
> +-----------
> +[1]: https://en.wikipedia.org/wiki/Deadlock
> +[2]: Shibu, K. (2009). Intro To Embedded Systems (1st ed.). Tata McGraw-Hill
> --
> 2.16.2
>