Instead of using a raw `KBuffer` and letting each implementation to
populating the specific flags on its own, we change things so we only
let each FileSystem implementation to validate the flag and its value
but then store it in a HashMap which its key is the flag name and
the value is a special new class called `FileSystemSpecificOption`
which wraps around `AK::Variant<...>`.
This approach has multiple advantages over the previous:
- It allows runtime inspection of what the user has set on a `MountFile`
description for a specific filesystem.
- It ensures accidental overriding of filesystem specific option that
was already set is not possible
- It removes ugly casting of a `KBuffer` contents to a strongly-typed
values. Instead, a strongly-typed `AK::Variant` is used which ensures
we always get a value without doing any casting.
Please note that we have removed support for ASCII string-oriented flags
as there were no actual use cases, and supporting such type would make
`FileSystemSpecificOption` more complicated unnecessarily for now.
The superblock of an ext2 filesystem is always found on the storage
device at offset 1024. This 1024 number was hardcoded in the Ext2FS
code.
This commit:
* adds a constexpr to replace the hardcoded 1024 values
* removes a comment about one of the the hardcoded 1024 values which is
now umnecessary
This is a large commit, since this is essentially a complete rewrite of
the key low-level functions that handle reading/writing blocks. This is,
however, a necessary prerequisite of being able to write holes.
The previous version of `flush_block_list()` (along with its numerous
helper functions) was entirely reliant on all blocks being sequential.
In contrast to the previous implementation, the new version
of `flush_block_list()` simply writes out the difference between the old
block list and the new block list by calculating the correct indirect
block(s) to update based on the relevant block's logical index.
`compute_block_list()` has also been rewritten, since the estimated
amount of meta blocks was incorrectly calculated for files with holes as
a result of the estimated amount of blocks being a function of the file
size. Since it isn't possible to accurately compute the shape of the
block list without traversing it, we no longer try to perform such a
computation, and instead simply search through all of the allocated
indirect blocks.
`compute_block_list_with_meta_blocks()` has also been removed in favor
of the new `compute_meta_blocks()`, since meta blocks are fundamentally
distinct from data blocks due to there being no mapping between any
logical block index and the physical block index.
Since we now only store blocks that are actually allocated, it is
entirely valid for the block list to be empty, so this commit lifts the
restrictions on accessing inodes with an empty block list.
Previously, attempting to update an ext2 inode with a UID or GID
larger than 65535 would overflow. We now write the high bits of UIDs
and GIDs to the same place that Linux does within the `osd2` struct.
We first must flush the superblock through the BlockBasedFileSystem
methods properly and only then clear the DiskCache pointer, to prevent a
possible kernel panic due to nullptr dereference.
Since this is the block size that file system drivers *should* set,
let's name it the logical block size, just like most file systems such
as ext2 already do anyways.
This never was a logical block size, it always was a device specific
block size. Ideally the block size would change in accordance to
whatever the driver wants to use, but that is a change for the future.
For now, let's get rid of this confusing naming.
This also makes it easier to understand and reference where these
(sometimes rather arbitrary) calculations come from.
This also fixes a bug where group_index_from_block_index assumed 1KiB
blocks.
This is a preparation before we can create a usable mechanism to use
filesystem-specific mount flags.
To keep some compatibility with userland code, LibC and LibCore mount
functions are kept being usable, but now instead of doing an "atomic"
syscall, they do multiple syscalls to perform the complete procedure of
mounting a filesystem.
The FileBackedFileSystem IntrusiveList in the VFS code is now changed to
be protected by a Mutex, because when we mount a new filesystem, we need
to check if a filesystem is already created for a given source_fd so we
do a scan for that OpenFileDescription in that list. If we fail to find
an already-created filesystem we create a new one and register it in the
list if we successfully mounted it. We use a Mutex because we might need
to initiate disk access during the filesystem creation, which will take
other mutexes in other parts of the kernel, therefore making it not
possible to take a spinlock while doing this.
"Wherever applicable" = most places, actually :^), especially for
networking and filesystem timestamps.
This includes changes to unzip, which uses DOSPackedTime, since that is
changed for the FAT file systems.
There was only one permanent storage location for these: as a member
in the Mount class.
That member is never modified after Mount initialization, so we don't
need to worry about races there.
