This has existed for some time in the form of the lfs_traverse
function, however lfs_traverse is relatively unconventional and
has proven to not have been the most intuitive for users.
As pointed out by davidefer, the lookahead pointer modular arithmetic
does not work around integer overflow when the pointer size is not a
multiple of the block count.
To avoid overflow problems, the easy solution is to stop trying to
work around integer overflows and keep the lookahead offset inside the
block device. To make this work, the ack was modified into a resetable
counter that is decremented every block allocation.
As a plus, quite a bit of the allocation logic ended up simplified.
Note: It's still expected to modify lfs_utils.h when porting littlefs
to a new target/system. There's just too much room for system-specific
improvements, such as taking advantage of CRC hardware.
Rather, encouraging modification of lfs_util.h and making it easy to
modify and debug should result in better integration with the consuming
systems.
This just adds a bunch of quality-of-life improvements that should help
development and integration in littlefs.
- Macros that require no side-effects are all-caps
- System includes are only brought in when needed
- Malloc/free wrappers
- LFS_NO_* checks for quickly disabling things at the command line
- At least a little-bit more docs
Rather than tracking all in-flight blocks blocks during a lookahead,
littlefs uses an ack scheme to mark the first allocated block that
hasn't reached the disk yet. littlefs assumes all blocks since the
last ack are bad or in-flight, and uses this to know when it's out
of storage.
However, these unacked allocations were still being populated in the
lookahead buffer. If the whole block device fits in the lookahead
buffer, _and_ littlefs managed to scan around the whole storage while
an unacked block was still in-flight, it would assume the block was
free and misallocate it.
The fix is to only fill the lookahead buffer up to the last ack.
The internal free structure was restructured to simplify the runtime
calculation of lookahead size.
- Write on read-only file to return LFS_ERR_BADF
- Renaming directory onto file to return LFS_ERR_NOTEMPTY
- Changed LFS_ERR_INVAL in lfs_file_seek to assert
An annoying part of filesystems is that the software library can change
independently of the on-disk structures. For this reason versioning is
very important, and must be handled separately for the software and
on-disk parts.
In this patch, littlefs provides two version numbers at compile time,
with major and minor parts, in the form of 6 macros.
LFS_VERSION // Library version, uint32_t encoded
LFS_VERSION_MAJOR // Major - Backwards incompatible changes
LFS_VERSION_MINOR // Minor - Feature additions
LFS_DISK_VERSION // On-disk version, uint32_t encoded
LFS_DISK_VERSION_MAJOR // Major - Backwards incompatible changes
LFS_DISK_VERSION_MINOR // Minor - Feature additions
Note that littlefs will error if it finds a major version number that
is different, or a minor version number that has regressed.
As a copy-on-write filesystem, the truncate function is a very nice
function to have, as it can take advantage of reusing the data already
written out to disk.
littlefs had an unwritten assumption that the block device's program
size would be a multiple of the read size, and the block size would
be a multiple of the program size. This has already caused confusion
for users. Added a note and assert to catch unexpected geometries
early.
Also found that the prog/erase functions indicated they must return
LFS_ERR_CORRUPT to catch bad blocks. This is no longer true as errors
are found by CRC.
As it was, if a user operated on a directory while at the same
time iterating over the directory, the directory objects could
fall out of sync. In the best case, files may be skipped while
removing everything in a file, in the worst case, a very poorly
timed directory relocate could be missed.
Simple fix is to add the same directory tracking that is currently
in use for files, at a small code+complexity cost.
Short story, files are no longer committed to directories during
file sync/close if the last write did not complete successfully.
This avoids a set of interesting user-experience issues related
to the end-of-life behaviour of the filesystem.
As a filesystem approaches end-of-life, the chances of running into
LFS_ERR_NOSPC grows rather quickly. Since this condition occurs after
at the end of a devices life, it's likely that operating in these
conditions hasn't been tested thoroughly.
In the specific case of file-writes, you can hit an LFS_ERR_NOSPC after
parts of the file have been written out. If the program simply continues
and closes the file, the file is written out half completed. Since
littlefs has a strong garuntee the prevents half-writes, it's unlikely
this state of the file would be expected.
To make things worse, since close is also responsible for memory
cleanup, it's actually _impossible_ to continue working as it was
without leaking memory.
By prevent the file commits, end-of-life behaviour should at least retain
a previous copy of the filesystem without any surprises.
The littlefs allows buffers to be passed statically in the case
that a system does not have a heap. Unfortunately, this means we
can't round up in the case of an unaligned lookahead buffer.
Double unfortunately, rounding down after clamping to the block device
size could result in a lookahead of zero for block devices < 32 blocks
large.
The assert in littlefs does catch this case, but rounding down prevents
support for < 32 block devices.
The solution is to simply require a 32-bit aligned buffer with an
assert. This avoids runtime problems while allowing a user to pass
in the correct buffer for < 32 block devices. Rounding up can be
handled at higher API levels.
Deduplication and deorphan steps aren't required under indentical
conditions, but they can be processed in the same iteration of the
filesystem. Since lfs_alloc (requires deorphan) occurs on most write
calls to the filesystem (requires deduplication), it was simpler to
just compine the steps into a single lfs_deorphan step.
Also traded out the places where lfs_rename/lfs_remove just defer
operations to the deorphan step. This adds a bit of code, but also
significantly speeds up directory operations.
The "move problem" has been present in littlefs for a while, but I haven't
come across a solution worth implementing for various reasons.
The problem is simple: how do we move directory entries across
directories atomically? Since multiple directory entries are involved,
we can't rely entirely on the atomic block updates. It ends up being
a bit of a puzzle.
To make the problem more complicated, any directory block update can
fail due to wear, and cause the directory block to need to be relocated.
This happens rarely, but brings a large number of corner cases.
---
The solution in this patch is simple:
1. Mark source as "moving"
2. Copy source to destination
3. Remove source
If littlefs ever runs into a "moving" entry, that means a power loss
occured during a move. Either the destination entry exists or it
doesn't. In this case we just search the entire filesystem for the
destination entry.
This is expensive, however the chance of a power loss during a move
is relatively low.
Simply limiting the lookahead region to the size of
the block device fixes the problem.
Also added logic to limit the allocated region and
floor to nearest word, since the additional memory
couldn't really be used effectively.
Zero attributes are actually supported at the moment, but this change
will allow entry attribute to be added in a backwards compatible manner.
Each dir entry is now prefixed with a 32 bit tag:
4b - entry type
4b - data structure
8b - entry len
8b - attribute len
8b - name len
A full entry on disk looks a bit like this:
[- 8 -|- 8 -|- 8 -|- 8 -|-- elen --|-- alen --|-- nlen --]
[ type | elen | alen | nlen | entry | attrs | name ]
The actually contents of the attributes section is a bit handwavey
until the first attributes are implemented, but to put plans in place:
Each attribute will be prefixed with only a byte that indicates the type
of attribute. Attributes should be sorted based on portability, since
unknown attributes will force attribute parsing to stop.
This provides a path for adding inlined files in the future, which
requires multiple lengths to distinguish between the file data and name.
As an extra bonus, the directory can now be iterated over even if the
types are unknown, since the name's representation is consistent on all
entry types.
This does come at the cost of reducing types from 16-bits to 8-bits, but
I doubt this will become a problem.
Before, the littlefs relied on the underlying block device
to report corruption that occurs when writing data to disk.
This requirement is easy to miss or implement incorrectly, since
the error detection is only required when a block becomes corrupted,
which is very unlikely to happen until late in the block device's
lifetime.
The littlefs can detect corruption itself by reading back written data.
This requires a bit of care to reuse the available buffers, and may rely
on checksums to avoid additional RAM requirements.
This does have a runtime penalty with the extra read operations, but
should make the littlefs much more robust to different implementations.
More documentation may still by worthwhile (design documentation?),
but for now this provides a reasonable baseline.
- readme
- license
- header documentation
This provides a limited form of wear leveling. While wear is
not actually balanced across blocks, the filesystem can recover
from corrupted blocks and extend the lifetime of a device nearly
as much as dynamic wear leveling.
For use-cases where wear is important, it would be better to use
a full form of dynamic wear-leveling at the block level. (or
consider a logging filesystem).
Corrupted block handling was simply added on top of the existing
logic in place for the filesystem, so it's a bit more noodly than
it may have to be, but it gets the work done.
This adds a fully independent layer between the rest of the filesystem
and the block device. This requires some additionally logic around cache
invalidation and flushing, but removes the need for any higher layer to
consider read/write sizes less than what is supported by the hardware.
Additionally, these caches can be used for possible speed improvements.
This is left up to the user to optimize for their use cases. For very
limited embedded systems with byte-level read/writes, the caches could
be omitted completely, or they could even be the size of a full block
for minimizing storage access.
(A full block may not be the best for speed, consider if only a small
portion of the read block is used, but I'll leave that evaluation as an
exercise for any consumers of this library)
Adopted buffer followed by size. The other order was original
chosen due to some other functions with a more complicated
parameter list.
This convention is important, as the bd api is one of the main
apis facing porting efforts.
