linux/Documentation/md/raid5-ppl.txt
Tomasz Majchrzak 1532d9e87e raid5-ppl: PPL support for disks with write-back cache enabled
In order to provide data consistency with PPL for disks with write-back
cache enabled all data has to be flushed to disks before next PPL
entry. The disks to be flushed are marked in the bitmap. It's modified
under a mutex and it's only read after PPL io unit is submitted.

A limitation of 64 disks in the array has been introduced to keep data
structures and implementation simple. RAID5 arrays with so many disks are
not likely due to high risk of multiple disks failure. Such restriction
should not be a real life limitation.

With write-back cache disabled next PPL entry is submitted when data write
for current one completes. Data flush defers next log submission so trigger
it when there are no stripes for handling found.

As PPL assures all data is flushed to disk at request completion, just
acknowledge flush request when PPL is enabled.

Signed-off-by: Tomasz Majchrzak <tomasz.majchrzak@intel.com>
Signed-off-by: Shaohua Li <sh.li@alibaba-inc.com>
2018-01-15 14:29:42 -08:00

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Partial Parity Log
Partial Parity Log (PPL) is a feature available for RAID5 arrays. The issue
addressed by PPL is that after a dirty shutdown, parity of a particular stripe
may become inconsistent with data on other member disks. If the array is also
in degraded state, there is no way to recalculate parity, because one of the
disks is missing. This can lead to silent data corruption when rebuilding the
array or using it is as degraded - data calculated from parity for array blocks
that have not been touched by a write request during the unclean shutdown can
be incorrect. Such condition is known as the RAID5 Write Hole. Because of
this, md by default does not allow starting a dirty degraded array.
Partial parity for a write operation is the XOR of stripe data chunks not
modified by this write. It is just enough data needed for recovering from the
write hole. XORing partial parity with the modified chunks produces parity for
the stripe, consistent with its state before the write operation, regardless of
which chunk writes have completed. If one of the not modified data disks of
this stripe is missing, this updated parity can be used to recover its
contents. PPL recovery is also performed when starting an array after an
unclean shutdown and all disks are available, eliminating the need to resync
the array. Because of this, using write-intent bitmap and PPL together is not
supported.
When handling a write request PPL writes partial parity before new data and
parity are dispatched to disks. PPL is a distributed log - it is stored on
array member drives in the metadata area, on the parity drive of a particular
stripe. It does not require a dedicated journaling drive. Write performance is
reduced by up to 30%-40% but it scales with the number of drives in the array
and the journaling drive does not become a bottleneck or a single point of
failure.
Unlike raid5-cache, the other solution in md for closing the write hole, PPL is
not a true journal. It does not protect from losing in-flight data, only from
silent data corruption. If a dirty disk of a stripe is lost, no PPL recovery is
performed for this stripe (parity is not updated). So it is possible to have
arbitrary data in the written part of a stripe if that disk is lost. In such
case the behavior is the same as in plain raid5.
PPL is available for md version-1 metadata and external (specifically IMSM)
metadata arrays. It can be enabled using mdadm option --consistency-policy=ppl.
There is a limitation of maximum 64 disks in the array for PPL. It allows to
keep data structures and implementation simple. RAID5 arrays with so many disks
are not likely due to high risk of multiple disks failure. Such restriction
should not be a real life limitation.