+brauner for "struct file" lifetime

On Thu, Aug 15, 2024 at 7:45 PM Suren Baghdasaryan [off-list ref] wrote:

On Thu, Aug 15, 2024 at 9:47 AM Andrii Nakryiko
[off-list ref] wrote:

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On Thu, Aug 15, 2024 at 6:44 AM Mateusz Guzik [off-list ref] wrote:

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On Tue, Aug 13, 2024 at 08:36:03AM -0700, Suren Baghdasaryan wrote:

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On Mon, Aug 12, 2024 at 11:18 PM Mateusz Guzik [off-list ref] wrote:

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On Mon, Aug 12, 2024 at 09:29:17PM -0700, Andrii Nakryiko wrote:

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Now that files_cachep is SLAB_TYPESAFE_BY_RCU, we can safely access
vma->vm_file->f_inode lockless only under rcu_read_lock() protection,
attempting uprobe look up speculatively.

Stupid question: Is this uprobe stuff actually such a hot codepath
that it makes sense to optimize it to be faster than the page fault
path?

(Sidenote: I find it kinda interesting that this is sort of going back
in the direction of the old Speculative Page Faults design.)

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We rely on newly added mmap_lock_speculation_{start,end}() helpers to
validate that mm_struct stays intact for entire duration of this
speculation. If not, we fall back to mmap_lock-protected lookup.

This allows to avoid contention on mmap_lock in absolutely majority of
cases, nicely improving uprobe/uretprobe scalability.

Here I have to admit to being mostly ignorant about the mm, so bear with
me. :>

I note the result of find_active_uprobe_speculative is immediately stale
in face of modifications.

The thing I'm after is that the mmap_lock_speculation business adds
overhead on archs where a release fence is not a de facto nop and I
don't believe the commit message justifies it. Definitely a bummer to
add merely it for uprobes. If there are bigger plans concerning it
that's a different story of course.

With this in mind I have to ask if instead you could perhaps get away
with the already present per-vma sequence counter?

per-vma sequence counter does not implement acquire/release logic, it
relies on vma->vm_lock for synchronization. So if we want to use it,
we would have to add additional memory barriers here. This is likely
possible but as I mentioned before we would need to ensure the
pagefault path does not regress. OTOH mm->mm_lock_seq already halfway
there (it implements acquire/release logic), we just had to ensure
mmap_write_lock() increments mm->mm_lock_seq.

So, from the release fence overhead POV I think whether we use
mm->mm_lock_seq or vma->vm_lock, we would still need a proper fence
here.

Per my previous e-mail I'm not particularly familiar with mm internals,
so I'm going to handwave a little bit with my $0,03 concerning multicore
in general and if you disagree with it that's your business. For the
time being I have no interest in digging into any of this.

Before I do, to prevent this thread from being a total waste, here are
some remarks concerning the patch with the assumption that the core idea
lands.

From the commit message:

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Now that files_cachep is SLAB_TYPESAFE_BY_RCU, we can safely access
vma->vm_file->f_inode lockless only under rcu_read_lock() protection,
attempting uprobe look up speculatively.

Just in case I'll note a nit that this paragraph will need to be removed
since the patch adding the flag is getting dropped.

Yep, of course, I'll update all that for the next revision (I'll wait
for non-RFC patches to land first before reposting).

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A non-nit which may or may not end up mattering is that the flag (which
*is* set on the filep slab cache) makes things more difficult to
validate. Normal RCU usage guarantees that the object itself wont be
freed as long you follow the rules. However, the SLAB_TYPESAFE_BY_RCU
flag weakens it significantly -- the thing at hand will always be a
'struct file', but it may get reallocated to *another* file from under
you. Whether this aspect plays a role here I don't know.

Yes, that's ok and is accounted for. We care about that memory not
going even from under us (I'm not even sure if it matters that it is
still a struct file, tbh; I think that shouldn't matter as we are
prepared to deal with completely garbage values read from struct
file).

Correct, with SLAB_TYPESAFE_BY_RCU we do need an additional check that
vma->vm_file has not been freed and reused. That's where
mmap_lock_speculation_{start|end} helps us. For vma->vm_file to change
from under us one would have to take mmap_lock for write. If that
happens mmap_lock_speculation_{start|end} should detect that and
terminate our speculation.

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+static struct uprobe *find_active_uprobe_speculative(unsigned long bp_vaddr)
+{
+     const vm_flags_t flags = VM_HUGETLB | VM_MAYEXEC | VM_MAYSHARE;
+     struct mm_struct *mm = current->mm;
+     struct uprobe *uprobe;
+     struct vm_area_struct *vma;
+     struct file *vm_file;
+     struct inode *vm_inode;
+     unsigned long vm_pgoff, vm_start;
+     int seq;
+     loff_t offset;
+
+     if (!mmap_lock_speculation_start(mm, &seq))
+             return NULL;
+
+     rcu_read_lock();
+

I don't think there is a correctness problem here, but entering rcu
*after* deciding to speculatively do the lookup feels backwards.

RCU should protect VMA and file, mm itself won't go anywhere, so this seems ok.

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+     vma = vma_lookup(mm, bp_vaddr);
+     if (!vma)
+             goto bail;
+
+     vm_file = data_race(vma->vm_file);
+     if (!vm_file || (vma->vm_flags & flags) != VM_MAYEXEC)
+             goto bail;
+

If vma teardown is allowed to progress and the file got fput'ed...

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+     vm_inode = data_race(vm_file->f_inode);

... the inode can be NULL, I don't know if that's handled.

Yep, inode pointer value is part of RB-tree key, so if it's NULL, we
just won't find a matching uprobe. Same for any other "garbage"
f_inode value. Importantly, we never should dereference such inode
pointers, at least until we find a valid uprobe (in which case we keep
inode reference to it).

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More importantly though, per my previous description of
SLAB_TYPESAFE_BY_RCU, by now the file could have been reallocated and
the inode you did find is completely unrelated.

I understand the intent is to backpedal from everything should the mm
seqc change, but the above may happen to matter.

Yes, I think we took that into account. All that we care about is
memory "type safety", i.e., even if struct file's memory is reused,
it's ok, we'll eventually detect the change and will discard wrong
uprobe that we might by accident lookup (though probably in most cases
we just won't find a uprobe at all).

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+     vm_pgoff = data_race(vma->vm_pgoff);
+     vm_start = data_race(vma->vm_start);
+
+     offset = (loff_t)(vm_pgoff << PAGE_SHIFT) + (bp_vaddr - vm_start);
+     uprobe = find_uprobe_rcu(vm_inode, offset);
+     if (!uprobe)
+             goto bail;
+
+     /* now double check that nothing about MM changed */
+     if (!mmap_lock_speculation_end(mm, seq))
+             goto bail;

This leaks the reference obtained by find_uprobe_rcu().

find_uprobe_rcu() doesn't obtain a reference, uprobe is RCU-protected,
and if caller need a refcount bump it will have to use
try_get_uprobe() (which might fail).

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+
+     rcu_read_unlock();
+
+     /* happy case, we speculated successfully */
+     return uprobe;
+bail:
+     rcu_read_unlock();
+     return NULL;
+}

Now to some handwaving, here it is:

The core of my concern is that adding more work to down_write on the
mmap semaphore comes with certain side-effects and plausibly more than a
sufficient speed up can be achieved without doing it.

AFAIK writers of mmap_lock are not considered a fast path. In a sense
yes, we made any writer a bit heavier but OTOH we also made
mm->mm_lock_seq a proper sequence count which allows us to locklessly
check if mmap_lock is write-locked. I think you asked whether there
will be other uses for mmap_lock_speculation_{start|end} and yes. For
example, I am planning to use them for printing /proc/{pid}/maps
without taking mmap_lock (when it's uncontended).

What would be the goal of this - to avoid cacheline bouncing of the
mmap lock between readers? Or to allow mmap_write_lock() to preempt
/proc/{pid}/maps readers who started out uncontended?

Is the idea that you'd change show_map_vma() to first do something
like get_file_active() to increment the file refcount (because
otherwise the dentry can be freed under you and you need the dentry
for path printing), then recheck your sequence count on the mm or vma
(to avoid accessing the dentry of an unrelated file that hasn't become
userspace-visible yet and may not have a proper dentry pointer yet),
then print the file path, drop the file reference again, and in the
end recheck the sequence count again before actually returning the
printed data to userspace?

If we have VMA seq
counter-based detection it would be better (see below).

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An mm-wide mechanism is just incredibly coarse-grained and it may happen
to perform poorly when faced with a program which likes to mess with its
address space -- the fast path is going to keep failing and only
inducing *more* overhead as the code decides to down_read the mmap
semaphore.

Furthermore there may be work currently synchronized with down_write
which perhaps can transition to "merely" down_read, but by the time it
happens this and possibly other consumers expect a change in the
sequence counter, messing with it.

To my understanding the kernel supports parallel faults with per-vma
locking. I would find it surprising if the same machinery could not be
used to sort out uprobe handling above.

From all the above, my understanding of your objection is that
checking mmap_lock during our speculation is too coarse-grained and
you would prefer to use the VMA seq counter to check that the VMA we
are working on is unchanged. I agree, that would be ideal. I had a
quick chat with Jann about this and the conclusion we came to is that
we would need to add an additional smp_wmb() barrier inside
vma_start_write() and a smp_rmb() in the speculation code:

static inline void vma_start_write(struct vm_area_struct *vma)
{
        int mm_lock_seq;

        if (__is_vma_write_locked(vma, &mm_lock_seq))
                return;

        down_write(&vma->vm_lock->lock);
        /*
         * We should use WRITE_ONCE() here because we can have concurrent reads
         * from the early lockless pessimistic check in vma_start_read().
         * We don't really care about the correctness of that early check, but
         * we should use WRITE_ONCE() for cleanliness and to keep KCSAN happy.
         */
        WRITE_ONCE(vma->vm_lock_seq, mm_lock_seq);
+        smp_wmb();
        up_write(&vma->vm_lock->lock);
}

Note: up_write(&vma->vm_lock->lock) in the vma_start_write() is not
enough because it's one-way permeable (it's a "RELEASE operation") and
later vma->vm_file store (or any other VMA modification) can move
before our vma->vm_lock_seq store.

This makes vma_start_write() heavier but again, it's write-locking, so
should not be considered a fast path.
With this change we can use the code suggested by Andrii in
https://lore.kernel.org/all/CAEf4BzZeLg0WsYw2M7KFy0+APrPaPVBY7FbawB9vjcA2+6k69Q@mail.gmail.com/ (local)
with an additional smp_rmb():

rcu_read_lock()
vma = find_vma(...)
if (!vma) /* bail */

And maybe add some comments like:

/*
 * Load the current VMA lock sequence - we will detect if anyone concurrently
 * locks the VMA after this point.
 * Pairs with smp_wmb() in vma_start_write().
 */

vm_lock_seq = smp_load_acquire(&vma->vm_lock_seq);

/*
 * Now we just have to detect if the VMA is already locked with its current
 * sequence count.
 *
 * The following load is ordered against the vm_lock_seq load above (using
 * smp_load_acquire() for the load above), and pairs with implicit memory
 * ordering between the mm_lock_seq write in mmap_write_unlock() and the
 * vm_lock_seq write in the next vma_start_write() after that (which can only
 * occur after an mmap_write_lock()).
 */

mm_lock_seq = smp_load_acquire(&vma->mm->mm_lock_seq);
/* I think vm_lock has to be acquired first to avoid the race */
if (mm_lock_seq == vm_lock_seq)
        /* bail, vma is write-locked */
... perform uprobe lookup logic based on vma->vm_file->f_inode ...

/*
 * Order the speculative accesses above against the following vm_lock_seq
 * recheck.
 */

smp_rmb();
if (vma->vm_lock_seq != vm_lock_seq)

(As I said on the other thread: Since this now relies on
vma->vm_lock_seq not wrapping back to the same value for correctness,
I'd like to see vma->vm_lock_seq being at least an "unsigned long", or
even better, an atomic64_t... though I realize we don't currently do
that for seqlocks either.)

        /* bail, VMA might have changed */

The smp_rmb() is needed so that vma->vm_lock_seq load does not get
reordered and moved up before speculation.

I'm CC'ing Jann since he understands memory barriers way better than
me and will keep me honest.