321 lines
15 KiB
ReStructuredText
321 lines
15 KiB
ReStructuredText
Storage model
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^^^^^^^^^^^^^
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*A storage model is a model that captures key physical aspects of data
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structure in a data store. A filesystem is the logical structure organizing
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data on top of the storage device.*
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The filesystem assumes several features or limitations of the storage device
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and utilizes them or applies measures to guarantee reliability. BTRFS in
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particular is based on a COW (copy on write) mode of writing, i.e. not updating
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data in place but rather writing a new copy to a different location and then
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atomically switching the pointers.
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In an ideal world, the device does what it promises. The filesystem assumes
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that this may not be true so additional mechanisms are applied to either detect
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misbehaving hardware or get valid data by other means. The devices may (and do)
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apply their own detection and repair mechanisms but we won't assume any.
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The following assumptions about storage devices are considered (sorted by
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importance, numbers are for further reference):
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1. atomicity of reads and writes of blocks/sectors (the smallest unit of data
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the device presents to the upper layers)
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2. there's a flush command that instructs the device to forcibly order writes
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before and after the command; alternatively there's a barrier command that
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facilitates the ordering but may not flush the data
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3. data sent to write to a given device offset will be written without further
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changes to the data and to the offset
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4. writes can be reordered by the device, unless explicitly serialized by the
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flush command
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5. reads and writes can be freely reordered and interleaved
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The consistency model of BTRFS builds on these assumptions. The logical data
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updates are grouped, into a generation, written on the device, serialized by
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the flush command and then the super block is written ending the generation.
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All logical links among metadata comprising a consistent view of the data may
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not cross the generation boundary.
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When things go wrong
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^^^^^^^^^^^^^^^^^^^^
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**No or partial atomicity of block reads/writes (1)**
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- *Problem*: a partial block contents is written (*torn write*), e.g. due to a
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power glitch or other electronics failure during the read/write
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- *Detection*: checksum mismatch on read
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- *Repair*: use another copy or rebuild from multiple blocks using some encoding
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scheme
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**The flush command does not flush (2)**
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This is perhaps the most serious problem and impossible to mitigate by
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filesystem without limitations and design restrictions. What could happen in
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the worst case is that writes from one generation bleed to another one, while
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still letting the filesystem consider the generations isolated. Crash at any
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point would leave data on the device in an inconsistent state without any hint
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what exactly got written, what is missing and leading to stale metadata link
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information.
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Devices usually honor the flush command, but for performance reasons may do
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internal caching, where the flushed data are not yet persistently stored. A
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power failure could lead to a similar scenario as above, although it's less
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likely that later writes would be written before the cached ones. This is
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beyond what a filesystem can take into account. Devices or controllers are
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usually equipped with batteries or capacitors to write the cache contents even
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after power is cut. (*Battery backed write cache*)
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**Data get silently changed on write (3)**
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Such thing should not happen frequently, but still can happen spuriously due
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the complex internal workings of devices or physical effects of the storage
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media itself.
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* *Problem*: while the data are written atomically, the contents get changed
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* *Detection*: checksum mismatch on read
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* *Repair*: use another copy or rebuild from multiple blocks using some
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encoding scheme
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**Data get silently written to another offset (3)**
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This would be another serious problem as the filesystem has no information
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when it happens. For that reason the measures have to be done ahead of time.
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This problem is also commonly called *ghost write*.
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The metadata blocks have the checksum embedded in the blocks, so a correct
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atomic write would not corrupt the checksum. It's likely that after reading
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such block the data inside would not be consistent with the rest. To rule that
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out there's embedded block number in the metadata block. It's the logical
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block number because this is what the logical structure expects and verifies.
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The following is based on information publicly available, user feedback,
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community discussions or bug report analyses. It's not complete and further
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research is encouraged when in doubt.
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Main memory
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^^^^^^^^^^^
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The data structures and raw data blocks are temporarily stored in computer
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memory before they get written to the device. It is critical that memory is
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reliable because even simple bit flips can have vast consequences and lead to
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damaged structures, not only in the filesystem but in the whole operating
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system.
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Based on experience in the community, memory bit flips are more common than one
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would think. When it happens, it's reported by the tree-checker or by a checksum
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mismatch after reading blocks. There are some very obvious instances of bit
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flips that happen, e.g. in an ordered sequence of keys in metadata blocks. We can
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easily infer from the other data what values get damaged and how. However, fixing
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that is not straightforward and would require cross-referencing data from the
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entire filesystem to see the scope.
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If available, ECC memory should lower the chances of bit flips, but this
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type of memory is not available in all cases. A memory test should be performed
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in case there's a visible bit flip pattern, though this may not detect a faulty
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memory module because the actual load of the system could be the factor making
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the problems appear. In recent years attacks on how the memory modules operate
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have been demonstrated (*rowhammer*) achieving specific bits to be flipped.
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While these were targeted, this shows that a series of reads or writes can
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affect unrelated parts of memory.
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Block group profiles with redundancy (like RAID1) will not protect against
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memory errors as the blocks are first stored in memory before they are written
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to the devices from the same source.
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A filesystem mounted read-only will not affect the underlying block device in
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almost 100% (with highly unlikely exceptions). The exception is a tree-log that
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needs to be replayed during mount (and before the read-only mount takes place),
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working memory is needed for that and that can be affected by bit flips.
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There's a theoretical case where bit flip changes the filesystem status from
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read-only to read-write.
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Further reading:
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* https://en.wikipedia.org/wiki/Row_hammer
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* memory overclocking, XMP, potential risks
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What to do:
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* run *memtest*, note that sometimes memory errors happen only when the system
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is under heavy load that the default memtest cannot trigger
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* memory errors may appear as filesystem going read-only due to "pre write"
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check, that verify meta data before they get written but fail some basic
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consistency checks
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* newly built systems should be tested before being put to production use,
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ideally start a IO/CPU load that will be run on such system later; namely
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systems that will utilize overclocking or special performance features
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Direct memory access (DMA)
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^^^^^^^^^^^^^^^^^^^^^^^^^^
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Another class of errors is related to DMA (direct memory access) performed
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by device drivers. While this could be considered a software error, the
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data transfers that happen without CPU assistance may accidentally corrupt
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other pages. Storage devices utilize DMA for performance reasons, the
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filesystem structures and data pages are passed back and forth, making
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errors possible in case page life time is not properly tracked.
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There are lots of quirks (device-specific workarounds) in Linux kernel
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drivers (regarding not only DMA) that are added when found. The quirks
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may avoid specific errors or disable some features to avoid worse problems.
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What to do:
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* use up-to-date kernel (recent releases or maintained long term support versions)
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* as this may be caused by faulty drivers, keep the systems up-to-date
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Rotational disks (HDD)
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^^^^^^^^^^^^^^^^^^^^^^
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Rotational HDDs typically fail at the level of individual sectors or small clusters.
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Read failures are caught on the levels below the filesystem and are returned to
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the user as *EIO - Input/output error*. Reading the blocks repeatedly may
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return the data eventually, but this is better done by specialized tools and
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filesystem takes the result of the lower layers. Rewriting the sectors may
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trigger internal remapping but this inevitably leads to data loss.
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Disk firmware is technically software but from the filesystem perspective is
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part of the hardware. IO requests are processed, and caching or various
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other optimizations are performed, which may lead to bugs under high load or
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unexpected physical conditions or unsupported use cases.
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Disks are connected by cables with two ends, both of which can cause problems
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when not attached properly. Data transfers are protected by checksums and the
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lower layers try hard to transfer the data correctly or not at all. The errors
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from badly-connecting cables may manifest as large amount of failed read or
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write requests, or as short error bursts depending on physical conditions.
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What to do:
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* check **smartctl** for potential issues
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Solid state drives (SSD)
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^^^^^^^^^^^^^^^^^^^^^^^^
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The mechanism of information storage is different from HDDs and this affects
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the failure mode as well. The data are stored in cells grouped in large blocks
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with limited number of resets and other write constraints. The firmware tries
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to avoid unnecessary resets and performs optimizations to maximize the storage
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media lifetime. The known techniques are deduplication (blocks with same
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fingerprint/hash are mapped to same physical block), compression or internal
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remapping and garbage collection of used memory cells. Due to the additional
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processing there are measures to verify the data e.g. by ECC codes.
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The observations of failing SSDs show that the whole electronic fails at once
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or affects a lot of data (e.g. stored on one chip). Recovering such data
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may need specialized equipment and reading data repeatedly does not help as
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it's possible with HDDs.
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There are several technologies of the memory cells with different
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characteristics and price. The lifetime is directly affected by the type and
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frequency of data written. Writing "too much" distinct data (e.g. encrypted)
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may render the internal deduplication ineffective and lead to a lot of rewrites
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and increased wear of the memory cells.
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There are several technologies and manufacturers so it's hard to describe them
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but there are some that exhibit similar behaviour:
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* expensive SSD will use more durable memory cells and is optimized for
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reliability and high load
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* cheap SSD is projected for a lower load ("desktop user") and is optimized for
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cost, it may employ the optimizations and/or extended error reporting
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partially or not at all
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It's not possible to reliably determine the expected lifetime of an SSD due to
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lack of information about how it works or due to lack of reliable stats provided
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by the device.
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Metadata writes tend to be the biggest component of lifetime writes to a SSD,
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so there is some value in reducing them. Depending on the device class (high
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end/low end) the features like DUP block group profiles may affect the
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reliability in both ways:
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* *high end* are typically more reliable and using *single* for data and
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metadata could be suitable to reduce device wear
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* *low end* could lack ability to identify errors so an additional redundancy
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at the filesystem level (checksums, *DUP*) could help
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Only users who consume 50 to 100% of the SSD's actual lifetime writes need to be
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concerned by the write amplification of btrfs DUP metadata. Most users will be
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far below 50% of the actual lifetime, or will write the drive to death and
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discover how many writes 100% of the actual lifetime was. SSD firmware often
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adds its own write multipliers that can be arbitrary and unpredictable and
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dependent on application behavior, and these will typically have far greater
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effect on SSD lifespan than DUP metadata. It's more or less impossible to
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predict when a SSD will run out of lifetime writes to within a factor of two, so
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it's hard to justify wear reduction as a benefit.
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Further reading:
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* https://www.snia.org/educational-library/ssd-and-deduplication-end-spinning-disk-2012
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* https://www.snia.org/educational-library/realities-solid-state-storage-2013-2013
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* https://www.snia.org/educational-library/ssd-performance-primer-2013
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* https://www.snia.org/educational-library/how-controllers-maximize-ssd-life-2013
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What to do:
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* run **smartctl** or self-tests to look for potential issues
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* keep the firmware up-to-date
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NVM express, non-volatile memory (NVMe)
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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NVMe is a type of persistent memory usually connected over a system bus (PCIe)
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or similar interface and the speeds are an order of magnitude faster than SSD.
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It is also a non-rotating type of storage, and is not typically connected by a
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cable. It's not a SCSI type device either but rather a complete specification
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for logical device interface.
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In a way the errors could be compared to a combination of SSD class and regular
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memory. Errors may exhibit as random bit flips or IO failures. There are tools
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to access the internal log (**nvme log** and **nvme-cli**) for a more detailed
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analysis.
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There are separate error detection and correction steps performed e.g. on the
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bus level and in most cases never making in to the filesystem level. Once this
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happens it could mean there's some systematic error like overheating or bad
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physical connection of the device. You may want to run self-tests (using
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**smartctl**).
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* https://en.wikipedia.org/wiki/NVM_Express
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* https://www.smartmontools.org/wiki/NVMe_Support
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Drive firmware
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^^^^^^^^^^^^^^
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Firmware is technically still software but embedded into the hardware. As all
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software has bugs, so does firmware. Storage devices can update the firmware
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and fix known bugs. In some cases the it's possible to avoid certain bugs by
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quirks (device-specific workarounds) in Linux kernel.
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A faulty firmware can cause wide range of corruptions from small and localized
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to large affecting lots of data. Self-repair capabilities may not be sufficient.
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What to do:
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* check for firmware updates in case there are known problems, note that
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updating firmware can be risky on itself
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* use up-to-date kernel (recent releases or maintained long term support versions)
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SD flash cards
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^^^^^^^^^^^^^^
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There are a lot of devices with low power consumption and thus using storage
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media based on low power consumption too, typically flash memory stored on
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a chip enclosed in a detachable card package. An improperly inserted card may be
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damaged by electrical spikes when the device is turned on or off. The chips
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storing data in turn may be damaged permanently. All types of flash memory
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have a limited number of rewrites, so the data are internally translated by FTL
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(flash translation layer). This is implemented in firmware (technically a
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software) and prone to bugs that manifest as hardware errors.
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Adding redundancy like using DUP profiles for both data and metadata can help
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in some cases but a full backup might be the best option once problems appear
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and replacing the card could be required as well.
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Hardware as the main source of filesystem corruptions
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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**If you use unreliable hardware and don't know about that, don't blame the
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filesystem when it tells you.**
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