NetBSD/sys/ufs/lfs/TODO
perseant 3ab94fed93 Fix a buffer overflow bug in the LFS_UBC case that manifested itself
either as a mysterious UVM error or as "panic: dirty bufs".  Verify
maximum size in lfs_malloc.

Teach lfs_updatemeta and lfs_shellsort about oversized cluster blocks from
lfs_gop_write.

When unwiring pages in lfs_gop_write, deactivate them, under the theory
that the pagedaemon wanted to free them last we knew.
2003-02-23 00:22:33 +00:00

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# $NetBSD: TODO,v 1.7 2003/02/23 00:22:33 perseant Exp $
- Lock audit. Need to check locking for multiprocessor case in particular.
- Get rid of the syscalls: make them into ioctl calls instead. This would
allow LFS to be loaded as a module. We would then ideally have an
in-kernel cleaner that runs if no userland cleaner has asserted itself.
- Get rid of lfs_segclean(); the kernel should clean a dirty segment IFF it
has passed two checkpoints containing zero live bytes.
- Now that our cache is basically all of physical memory, we need to make
sure that segwrite is not starving other important things. Need a way
to prioritize which blocks are most important to write, and write only
those before giving up the seglock to do the rest. How does this change
our notion of what a checkpoint is?
- Investigate alternate inode locking strategy: Inode locks are useful
for locking against simultaneous changes to inode size (balloc,
truncate, write) but because the assignment of disk blocks is also
covered by the segment lock, we don't really need to pay attention to
the inode lock when writing a segment, right? If this is true, the
locking problem in lfs_{bmapv,markv} goes away and lfs_reserve can go,
too.
- Fully working fsck_lfs. (Really, need a general-purpose external
partial-segment writer.)
- Get rid of DEV_BSIZE, pay attention to the media block size at mount time.
- More fs ops need to call lfs_imtime. Which ones? (Blackwell et al., 1995)
- lfs_vunref_head exists so that vnodes loaded solely for cleaning can
be put back on the *head* of the vnode free list. Make sure we
actually do this, since we now take IN_CLEANING off during segment write.
- The cleaner could be enhanced to be controlled from other processes,
and possibly perform additional tasks:
- Backups. At a minimum, turn the cleaner off and on to allow
effective live backups. More aggressively, the cleaner itself could
be the backup agent, and dump_lfs would merely be a controller.
- Cleaning time policies. Be able to tweak the cleaner's thresholds
to allow more thorough cleaning during policy-determined idle
periods (regardless of actual idleness) or put off until later
during short, intensive write periods.
- File coalescing and placement. During periods we expect to be idle,
coalesce fragmented files into one place on disk for better read
performance. Ideally, move files that have not been accessed in a
while to the extremes of the disk, thereby shortening seek times for
files that are accessed more frequently (though how the cleaner
should communicate "please put this near the beginning or end of the
disk" to the kernel is a very good question; flags to lfs_markv?).
- Versioning. When it cleans a segment it could write data for files
that were less than n versions old to tape or elsewhere. Perhaps it
could even write them back onto the disk, although that requires
more thought (and kernel mods).
- Move lfs_countlocked() into vfs_bio.c, to replace count_locked_queue;
perhaps keep the name, replace the function. Could it count referenced
vnodes as well, if it was in vfs_subr.c instead?
- Why not delete the lfs_bmapv call, just mark everything dirty that
isn't deleted/truncated? Get some numbers about what percentage of
the stuff that the cleaner thinks might be live is live. If it's
high, get rid of lfs_bmapv.
- There is a nasty problem in that it may take *more* room to write the
data to clean a segment than is returned by the new segment because of
indirect blocks in segment 2 being dirtied by the data being copied
into the log from segment 1. The suggested solution at this point is
to detect it when we have no space left on the filesystem, write the
extra data into the last segment (leaving no clean ones), make it a
checkpoint and shut down the file system for fixing by a utility
reading the raw partition. Argument is that this should never happen
and is practically impossible to fix since the cleaner would have to
theoretically build a model of the entire filesystem in memory to
detect the condition occurring. A file coalescing cleaner will help
avoid the problem, and one that reads/writes from the raw disk could
fix it.
- Need to keep vnode v_numoutput up to date for pending writes?
- If delete a file that's being executed, the version number isn't
updated, and fsck_lfs has to figure this out; case is the same as if
have an inode that no directory references, so the file should be
reattached into lost+found.
- Currently there's no notion of write error checking.
+ Failed data/inode writes should be rescheduled (kernel level bad blocking).
+ Failed superblock writes should cause selection of new superblock
for checkpointing.
- Future fantasies:
- unrm, versioning
- transactions
- extended cleaner policies (hot/cold data, data placement)
- Problem with the concept of multiple buffer headers referencing the segment:
Positives:
Don't lock down 1 segment per file system of physical memory.
Don't copy from buffers to segment memory.
Don't tie down the bus to transfer 1M.
Works on controllers supporting less than large transfers.
Disk can start writing immediately instead of waiting 1/2 rotation
and the full transfer.
Negatives:
Have to do segment write then segment summary write, since the latter
is what verifies that the segment is okay. (Is there another way
to do this?)
- The algorithm for selecting the disk addresses of the super-blocks
has to be available to the user program which checks the file system.