Hi Dave,
On 2020/11/30 上午6:47, Dave Chinner wrote:
On Mon, Nov 23, 2020 at 08:41:10AM +0800, Shiyang Ruan wrote:
The call trace is like this:
memory_failure()
pgmap->ops->memory_failure() => pmem_pgmap_memory_failure()
gendisk->fops->block_lost() => pmem_block_lost() or
md_blk_block_lost()
sb->s_ops->storage_lost() => xfs_fs_storage_lost()
xfs_rmap_query_range()
xfs_storage_lost_helper()
mf_recover_controller->recover_fn => \
memory_failure_dev_pagemap_kill_procs()
The collect_procs() and kill_procs() are moved into a callback which
is passed from memory_failure() to xfs_storage_lost_helper(). So we
can call it when a file assocaited is found, instead of creating a
file list and iterate it.
The fsdax & reflink support for XFS is not contained in this patchset.
This looks promising - the overall architecture is a lot more
generic and less dependent on knowing about memory, dax or memory
failures. A few comments that I think would further improve
understanding the patchset and the implementation:
Thanks for your kindly comment. It gives me confidence.
- the order of the patches is inverted. It should start with a
single patch introducing the mf_recover_controller structure for
callbacks, then introduce pgmap->ops->memory_failure, then
->block_lost, then the pmem and md implementations of ->block
list, then ->storage_lost and the XFS implementations of
->storage_lost.
Yes, it will be easier to understand the patchset in this order.
But I have something unsure: for example, I introduce ->memory_failure()
firstly, but the implementation of ->memory_failure() needs to call
->block_lost() which is supposed to be introduced in the next patch. So,
I am not sure the code is supposed to be what in the implementation of
->memory_failure() in pmem? To avoid this situation, I committed the
patches in the inverted order: lowest level first, then its caller, and
then caller's caller.
I am trying to sort out the order. How about this:
Patch i.
Introduce ->memory_failure()
- just introduce interface, without implementation
Patch i++.
Introduce ->block_lost()
- introduce interface and implement ->memory_failure()
in pmem, so that it can call ->block_lost()
Patch i++.
(similar with above, skip...)
- I think the names "block_lost" and "storage_lost" are misleading.
It's more like a "media failure" or a general "data corruption"
event at a specific physical location. The data may not be "lost"
but only damaged, so we might be able to recover from it without
"losing" anything. Hence I think they could be better named,
perhaps just "->corrupt_range"
'corrupt' sounds better. (I'm not good at naming functions...)
- need to pass a {offset,len} pair through the chain, not just a
single offset. This will allow other types of devices to report
different ranges of failures, from a single sector to an entire
device.
Yes, it's better to add the length. I restrictively thought that
memory-failure on pmem should affect one single page at one time.
- I'm not sure that passing the mf_recover_controller structure
through the corruption event chain is the right thing to do here.
A block device could generate this storage failure callback if it
detects an unrecoverable error (e.g. during a MD media scrub or
rebuild/resilver failure) and in that case we don't have PFNs or
memory device failure functions to perform.
IOWs, I think the action that is taken needs to be independent of
the source that generated the error. Even for a pmem device, we
can be using the page cache, so it may be possible to recover the
pmem error by writing the cached page (if it exists) back over the
pmem.
Hence I think that the recover function probably needs to be moved
to the address space ops, because what we do to recover from the
error is going to be dependent on type of mapping the filesystem
is using. If it's a DAX mapping, we call back into a generic DAX
function that does the vma walk and process kill functions. If it
is a page cache mapping, then if the page is cached then we can
try to re-write it to disk to fix the bad data, otherwise we treat
it like a writeback error and report it on the next
write/fsync/close operation done on that file.
This gets rid of the mf_recover_controller altogether and allows
the interface to be used by any sort of block device for any sort
of bottom-up reporting of media/device failures.
Moving the recover function to the address_space ops looks a better
idea. But I think that the error handler for page cache mapping is
finished well in memory-failure. The memory-failure is also reused to
handles anonymous page. If we move the recover function to
address_space ops, I think we also need to refactor the existing handler
for page cache mapping, which may affect anonymous page handling. This
makes me confused...
I rewrote the call trace:
memory_failure()
* dax mapping case
pgmap->ops->memory_failure() =>
pmem_pgmap_memory_failure()
gendisk->fops->block_corrupt_range() =>
- pmem_block_corrupt_range()
- md_blk_block_corrupt_range()
sb->s_ops->storage_currupt_range() =>
xfs_fs_storage_corrupt_range()
xfs_rmap_query_range()
xfs_storage_lost_helper()
mapping->a_ops->corrupt_range() =>
xfs_dax_aops.xfs_dax_corrupt_range
memory_failure_dev_pagemap_kill_procs()
* page cache mapping case
mapping->a_ops->corrupt_range() =>
xfs_address_space_operations.xfs_xxx
memory_failure_generic_kill_procs()
It's rough and not completed yet. Hope for your comment.
--
Thanks,
Ruan Shiyang.
Cheers,
Dave.