On Tue, Feb 21, 2017 at 05:45:53PM +0800, Coly Li wrote:
> On 2017/2/21 上午8:29, NeilBrown wrote:
> > On Mon, Feb 20 2017, Coly Li wrote:
> >
> >>> 在 2017年2月20日,下午3:04,Shaohua Li <shli@xxxxxxxxxx> 写道:
> >>>
> >>>> On Mon, Feb 20, 2017 at 01:51:22PM +1100, Neil Brown wrote:
> >>>>> On Mon, Feb 20 2017, NeilBrown wrote:
> >>>>>
> >>>>>> On Fri, Feb 17 2017, Coly Li wrote:
> >>>>>>
> >>>>>>> On 2017/2/16 下午3:04, NeilBrown wrote: I know you are
> >>>>>>> going to change this as Shaohua wantsthe spitting to
> >>>>>>> happen in a separate function, which I agree with, but
> >>>>>>> there is something else wrong here. Calling
> >>>>>>> bio_split/bio_chain repeatedly in a loop is dangerous.
> >>>>>>> It is OK for simple devices, but when one request can
> >>>>>>> wait for another request to the same device it can
> >>>>>>> deadlock. This can happen with raid1. If a resync
> >>>>>>> request calls raise_barrier() between one request and
> >>>>>>> the next, then the next has to wait for the resync
> >>>>>>> request, which has to wait for the first request. As
> >>>>>>> the first request will be stuck in the queue in
> >>>>>>> generic_make_request(), you get a deadlock.
> >>>>>>
> >>>>>> For md raid1, queue in generic_make_request(), can I
> >>>>>> understand it as bio_list_on_stack in this function? And
> >>>>>> queue in underlying device, can I understand it as the
> >>>>>> data structures like plug->pending and
> >>>>>> conf->pending_bio_list ?
> >>>>>
> >>>>> Yes, the queue in generic_make_request() is the
> >>>>> bio_list_on_stack. That is the only queue I am talking
> >>>>> about. I'm not referring to plug->pending or
> >>>>> conf->pending_bio_list at all.
> >>>>>
> >>>>>>
> >>>>>> I still don't get the point of deadlock, let me try to
> >>>>>> explain why I don't see the possible deadlock. If a bio
> >>>>>> is split, and the first part is processed by
> >>>>>> make_request_fn(), and then a resync comes and it will
> >>>>>> raise a barrier, there are 3 possible conditions, - the
> >>>>>> resync I/O tries to raise barrier on same bucket of the
> >>>>>> first regular bio. Then the resync task has to wait to
> >>>>>> the first bio drops its conf->nr_pending[idx]
> >>>>>
> >>>>> Not quite. First, the resync task (in raise_barrier()) will
> >>>>> wait for ->nr_waiting[idx] to be zero. We can assume this
> >>>>> happens immediately. Then the resync_task will increment
> >>>>> ->barrier[idx]. Only then will it wait for the first bio to
> >>>>> drop ->nr_pending[idx]. The processing of that first bio
> >>>>> will have submitted bios to the underlying device, and they
> >>>>> will be in the bio_list_on_stack queue, and will not be
> >>>>> processed until raid1_make_request() completes.
> >>>>>
> >>>>> The loop in raid1_make_request() will then call
> >>>>> make_request_fn() which will call wait_barrier(), which
> >>>>> will wait for ->barrier[idx] to be zero.
> >>>>
> >>>> Thinking more carefully about this.. the 'idx' that the
> >>>> second bio will wait for will normally be different, so there
> >>>> won't be a deadlock after all.
> >>>>
> >>>> However it is possible for hash_long() to produce the same
> >>>> idx for two consecutive barrier_units so there is still the
> >>>> possibility of a deadlock, though it isn't as likely as I
> >>>> thought at first.
> >>>
> >>> Wrapped the function pointer issue Neil pointed out into Coly's
> >>> original patch. Also fix a 'use-after-free' bug. For the
> >>> deadlock issue, I'll add below patch, please check.
> >>>
> >>> Thanks, Shaohua
> >>>
> >>
>
> Neil,
>
> Thanks for your patient explanation, I feel I come to follow up what
> you mean. Let me try to re-tell what I understand, correct me if I am
> wrong.
>
>
> >> Hmm, please hold, I am still thinking of it. With barrier bucket
> >> and hash_long(), I don't see dead lock yet. For raid10 it might
> >> happen, but once we have barrier bucket on it , there will no
> >> deadlock.
> >>
> >> My question is, this deadlock only happens when a big bio is
> >> split, and the split small bios are continuous, and the resync io
> >> visiting barrier buckets in sequntial order too. In the case if
> >> adjacent split regular bios or resync bios hit same barrier
> >> bucket, it will be a very big failure of hash design, and should
> >> have been found already. But no one complain it, so I don't
> >> convince myself tje deadlock is real with io barrier buckets
> >> (this is what Neil concerns).
> >
> > I think you are wrong about the design goal of a hash function.
> > When feed a sequence of inputs, with any stride (i.e. with any
> > constant difference between consecutive inputs), the output of the
> > hash function should appear to be random. A random sequence can
> > produce the same number twice in a row. If the hash function
> > produces a number from 0 to N-1, you would expect two consecutive
> > outputs to be the same about once every N inputs.
> >
>
> Yes, you are right. But when I mentioned hash conflict, I limit the
> integers in range [0, 1<<38]. 38 is (64-17-9), when a 64bit LBA
> address divided by 64MB I/O barrier unit size, its value range is
> reduced to [0, 1<<38].
>
> Maximum size of normal bio is 1MB, it could be split into 2 bios at most.
>
> For DISCARD bio, its maximum size is 4GB, it could be split into 65
> bios at most.
>
> Then in this patch, the hash question is degraded to: for any
> consecutive 65 integers in range [0, 1<<38], use hash_long() to hash
> these 65 integers into range [0, 1023], will any hash conflict happen
> among these integers ?
>
> I tried a half range [0, 1<<37] to check hash conflict, by writing a
> simple code to emulate hash calculation in the new I/O barrier patch,
> to iterate all consecutive {2, 65, 128, 512} integers in range [0,
> 1<<37] for hash conflict.
>
> On a 20 core CPU each run spent 7+ hours, finally I find no hash
> conflict detected up to 512 consecutive integers in above limited
> condition. For 1024, there are a lot hash conflict detected.
>
> [0, 1<<37] range back to [0, 63] LBA range, this is large enough for
> almost all existing md raid configuration. So for current kernel
> implementation and real world device, for a single bio, there is no
> possible hash conflict the new I/O barrier patch.
>
> If bi_iter.bi_size changes from unsigned int to unsigned long in
> future, the above assumption will be wrong. There will be hash
> conflict, and potential dead lock, which is quite implicit. Yes, I
> agree with you. No, bio split inside loop is not perfect.
>
> > Even if there was no possibility of a deadlock from a resync
> > request happening between two bios, there are other possibilities.
> >
>
> The bellowed text makes me know more about raid1 code, but confuses me
> more as well. Here comes my questions,
>
> > It is not, in general, safe to call mempool_alloc() twice in a
> > row, without first ensuring that the first allocation will get
> > freed by some other thread. raid1_write_request() allocates from
> > r1bio_pool, and then submits bios to the underlying device, which
> > get queued on bio_list_on_stack. They will not be processed until
> > after raid1_make_request() completes, so when raid1_make_request
> > loops around and calls raid1_write_request() again, it will try to
> > allocate another r1bio from r1bio_pool, and this might end up
> > waiting for the r1bio which is trapped and cannot complete.
> >
>
> Can I say that it is because blk_finish_plug() won't be called before
> raid1_make_request() returns ? Then in raid1_write_request(), mbio
> will be added into plug->pending, but before blk_finish_plug() is
> called, they won't be handled.
blk_finish_plug is called if raid1_make_request sleep. The bio is hold in
current->bio_list, not in plug list.
> > As r1bio_pool preallocates 256 entries, this is unlikely but not
> > impossible. If 256 threads all attempt a write (or read) that
> > crosses a boundary, then they will consume all 256 preallocated
> > entries, and want more. If there is no free memory, they will block
> > indefinitely.
> >
>
> If raid1_make_request() is modified into this way,
> + if (bio_data_dir(split) == READ)
> + raid1_read_request(mddev, split);
> + else
> + raid1_write_request(mddev, split);
> + if (split != bio)
> + generic_make_request(bio);
>
> Then the original bio will be added into the bio_list_on_stack of top
> level generic_make_request(), current->bio_list is initialized, when
> generic_make_request() is called nested in raid1_make_request(), the
> split bio will be added into current->bio_list and nothing else happens.
>
> After the nested generic_make_request() returns, the code back to next
> code of generic_make_request(),
> 2022 ret = q->make_request_fn(q, bio);
> 2023
> 2024 blk_queue_exit(q);
> 2025
> 2026 bio = bio_list_pop(current->bio_list);
>
> bio_list_pop() will return the second half of the split bio, and it is
So in above sequence, the curent->bio_list will has bios in below sequence:
bios to underlaying disks, second half of original bio
bio_list_pop will pop bios to underlaying disks first, handle them, then the
second half of original bio.
That said, this doesn't work for array stacked 3 layers. Because in 3-layer
array, handling the middle layer bio will make the 3rd layer bio hold to
bio_list again.
Thanks,
Shaohua
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