v1.7.8.1 (2021-06-13):
- Fixed bug preventing new directories from appearing in listings
- Fixed Release version of driver still not working on XP
v1.7.8 (2021-06-09):
- ~~Upgraded zstd to version 1.5.0~~ Not in ReactOS as it introduces deprecated code
- Fixed regression stopping driver from working under XP
- Fixed compilation on clang
- Fixed corruption issue when Linux mount option inode_cache had been used
- Fixed recursion issue involving virtual directory \$Root
v1.7.6 (2021-01-14):
- Fixed race condition when booting with Quibble
- No longer need to restart Windows after initial installation
- Forced maximum file name to 255 UTF-8 characters, to match Linux driver
- Fixed issue where directories could be created with trailing backslash
- Fixed potential deadlock when Windows calls NtCreateSection during flush
- Miscellaneous bug fixes
v1.7.4 (2020-08-23):
- Fixed issue when running compressed EXEs
- Changed build system to cmake
- Upgraded zstd to version 1.4.5
- Added support for FSCTL_GET_RETRIEVAL_POINTERS
- Miscellaneous bug fixes
The upstream driver is not maintained and the file system itself
is in a semi-abandoned state.
Originally imported at 3a3ef631d1
The driver is written by Lee Jae-Hong, updated by Bo Brantén.
ReactOS porting made by Peter Hater and Pierre Schweitzer.
Follow updates at http://www.acc.umu.se/~bosse/
FS Recognizer code is left to keep the FS support as an
installable driver.
CORE-11040
The upstream driver is not maintained and the file system itself
is in a semi-abandoned state.
Originally imported at e308102f4a
The driver is written by Mark W Piper, updated by Bo Brantén.
ReactOS porting made by Peter Hater and Pierre Schweitzer.
Follow updates at http://www.acc.umu.se/~bosse/
FS Recognizer code is left to keep the FS support as an
installable driver.
CORE-11005
[AUTOCHK] Add also support for scanning FATX volumes.
The Format(), FormatEx(), Chkdsk(), ChkdskEx() functions exposed by the
U*.DLL user-mode FS library dlls are different (and have different
prototypes) than the similarly-named functions exported by FMIFS.DLL .
In particular, what we used to call "xxxChkdskEx()" and "xxxFormatEx()"
in our U*.DLL libraries actually correspond more, from their arguments,
to the "Chkdsk()" and "Format()" functions in Windows' U*.DLL . Their
*Ex() counterparts instead take most of the parameters through a
structure passed by pointer.
On FMIFS.DLL side, while FMIFS!Chkdsk() calls U*.DLL!Chkdsk() and
FMIFS!ChkdskEx() calls U*.DLL!ChkdskEx() (and we do not implement these
*Ex() functions at the moment), both FMIFS!Format() and FMIFS!FormatEx()
call U*.DLL!Format() instead, while FMIFS!FormatEx2() calls
U*.DLL!FormatEx() (that we do not implement yet either) !!
To improve that, refactor the calls to these U*.DLL functions so as to
respect the more compatible prototypes: They contain the correct number
of parameters in a compatible order. However, some of the parameters do
not have the same types yet: the strings are kept here in PUNICODE_STRINGS,
while on Windows they are passed via an undocumented DSTRING struct, and
the FMIFS callback is instead a MESSAGE struct/class on Windows.
Finally, the MEDIA_TYPE parameter in U*.DLL!Format() is equivalent, yet
not fully 100% in 1-to-1 correspondence, with the FMIFS_MEDIA_FLAG used
in the corresponding FMIFS.DLL functions.
One thing to notice is that the U*.DLL!Format() (and the Ex) functions
support a BOOLEAN (a flag resp.) for telling that a backwards-compatible
FS version should be used instead of the (default) latest FS version.
This is used e.g. by the FAT FS, where by default FAT32 is selected
(depending also on other constraints like, the disk and the partition
sizes), unless that bit is set in which case, FAT16 (or 12) is used.
- Reduce the diff with upstream by aliasing malloc() and free()
with RtlAllocateHeap() and RtlFreeHeap() respectively.
- Fix a memory leak in the failure code path of the do-while
memory reallocation loop for IOCTL_BTRFS_QUERY_FILESYSTEMS
in is_mounted_multi_device().
Fixes GCC 8 warning:
sdk/lib/fslib/vfatlib/check/boot.c:173:27: error: '%02x' directive writing between 2 and 8 bytes into a region of size between 0 and 15 [-Werror=format-overflow=]
sprintf(buf, "%s%u:%02x/%02x", first ? "" : ", ",
^~~~
sdk/lib/fslib/vfatlib/check/boot.c:173:16: note: directive argument in the range [0, 2147483647]
sprintf(buf, "%s%u:%02x/%02x", first ? "" : ", ",
^~~~~~~~~~~~~~~~
sdk/lib/fslib/vfatlib/check/boot.c:173:3: note: 'sprintf' output between 8 and 31 bytes into a destination of size 20
sprintf(buf, "%s%u:%02x/%02x", first ? "" : ", ",
^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
(unsigned)(p - (uint8_t *) b), *p, *q);
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
(So the fun begins)
In spite of what VFATLIB headers pretend, there's not magic in FAT boot sector.
The 3 first bytes are just the jump instruction (to the boot code). No jump, no boot.
Also, some (many?) FAT implementations rely on the jump code to help detecting that
a FAT volume is really a FAT volume. Like MS FastFAT. Or our own FAT recognizer in FS_REC.
The story is that, up to that commit, we zeroed the 3 first bytes; leading to broken
FAT volumes.
This got hidden in most cases by the fact that during setup, when we install boot
loader, we erase parts of the boot sector, including the jump instruction, making the
volume valid again. But that wouldn't fix secondary volumes where the boot loader isn't
installed.
And, also, imagine a scenario where you want to install ReactOS on a newly formatted volume
with MS FastFAT instead of our own implementation... That would simply not work to
the fact that the driver wouldn't recognize the fresh formatted volume!
(So the non fashion begins)
Fix this by putting a not that valid jump into the boot sector when formatting our
partitions. That way, our volume is always regarding a FAT view point. But, instead of
putting values that mean (nearly) nothing. We should also put a dummy bootloader
displaying the user and error message, as done by dosfstools.
(So the hope begins)
This opens the way for trying to install ReactOS with MS FastFAT (doesn't work yet).
CORE-11819
CORE-14362
It's critical not to perform any write on a volume without an exclusive lock on it.
That lock is only acquired if ChkDsk is started in RW mode.
Also added an assert in write routine, to make sure that when we're about to perform
a write operation, we're really allowed to do so.
This will avoid volume corruptions when a simple "chkdsk" is issued from cmd.
To put it simple: check will really check now, and won't attempt any repair.
CORE-14119
For instance, when repair is required, we can ask the caller whether we should
continue or not in case locking failed.
Also, introduced a hack for 1st stage where IopParseDevice() hack is in usage
so that broken NTSTATUS is diverted to appropriate status.
That way, usetup will properly continue even if locking failed (due to its
callback stub!)
CORE-14087