/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright 2009 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kmem.h>
#include <sys/user.h>
#include <sys/proc.h>
#include <sys/cred.h>
#include <sys/disp.h>
#include <sys/buf.h>
#include <sys/vfs.h>
#include <sys/vfs_opreg.h>
#include <sys/vnode.h>
#include <sys/fdio.h>
#include <sys/file.h>
#include <sys/uio.h>
#include <sys/conf.h>
#include <sys/statvfs.h>
#include <sys/mount.h>
#include <sys/pathname.h>
#include <sys/cmn_err.h>
#include <sys/debug.h>
#include <sys/sysmacros.h>
#include <sys/conf.h>
#include <sys/mkdev.h>
#include <sys/swap.h>
#include <sys/sunddi.h>
#include <sys/sunldi.h>
#include <sys/dktp/fdisk.h>
#include <sys/fs/pc_label.h>
#include <sys/fs/pc_fs.h>
#include <sys/fs/pc_dir.h>
#include <sys/fs/pc_node.h>
#include <fs/fs_subr.h>
#include <sys/modctl.h>
#include <sys/dkio.h>
#include <sys/open.h>
#include <sys/mntent.h>
#include <sys/policy.h>
#include <sys/atomic.h>
#include <sys/sdt.h>
/*
* The majority of PC media use a 512 sector size, but
* occasionally you will run across a 1k sector size.
* For media with a 1k sector size, fd_strategy() requires
* the I/O size to be a 1k multiple; so when the sector size
* is not yet known, always read 1k.
*/
#define PC_SAFESECSIZE (PC_SECSIZE * 2)
static int pcfs_pseudo_floppy(dev_t);
static int pcfsinit(int, char *);
static int pcfs_mount(struct vfs *, struct vnode *, struct mounta *,
struct cred *);
static int pcfs_unmount(struct vfs *, int, struct cred *);
static int pcfs_root(struct vfs *, struct vnode **);
static int pcfs_statvfs(struct vfs *, struct statvfs64 *);
static int pc_syncfsnodes(struct pcfs *);
static int pcfs_sync(struct vfs *, short, struct cred *);
static int pcfs_vget(struct vfs *vfsp, struct vnode **vpp, struct fid *fidp);
static void pcfs_freevfs(vfs_t *vfsp);
static int pc_readfat(struct pcfs *fsp, uchar_t *fatp);
static int pc_writefat(struct pcfs *fsp, daddr_t start);
static int pc_getfattype(struct pcfs *fsp);
static void pcfs_parse_mntopts(struct pcfs *fsp);
/*
* pcfs mount options table
*/
static char *nohidden_cancel[] = { MNTOPT_PCFS_HIDDEN, NULL };
static char *hidden_cancel[] = { MNTOPT_PCFS_NOHIDDEN, NULL };
static char *nofoldcase_cancel[] = { MNTOPT_PCFS_FOLDCASE, NULL };
static char *foldcase_cancel[] = { MNTOPT_PCFS_NOFOLDCASE, NULL };
static char *clamptime_cancel[] = { MNTOPT_PCFS_NOCLAMPTIME, NULL };
static char *noclamptime_cancel[] = { MNTOPT_PCFS_CLAMPTIME, NULL };
static char *atime_cancel[] = { MNTOPT_NOATIME, NULL };
static char *noatime_cancel[] = { MNTOPT_ATIME, NULL };
static mntopt_t mntopts[] = {
/*
* option name cancel option default arg flags opt data
*/
{ MNTOPT_PCFS_NOHIDDEN, nohidden_cancel, NULL, 0, NULL },
{ MNTOPT_PCFS_HIDDEN, hidden_cancel, NULL, MO_DEFAULT, NULL },
{ MNTOPT_PCFS_NOFOLDCASE, nofoldcase_cancel, NULL, MO_DEFAULT, NULL },
{ MNTOPT_PCFS_FOLDCASE, foldcase_cancel, NULL, 0, NULL },
{ MNTOPT_PCFS_CLAMPTIME, clamptime_cancel, NULL, MO_DEFAULT, NULL },
{ MNTOPT_PCFS_NOCLAMPTIME, noclamptime_cancel, NULL, NULL, NULL },
{ MNTOPT_NOATIME, noatime_cancel, NULL, NULL, NULL },
{ MNTOPT_ATIME, atime_cancel, NULL, NULL, NULL },
{ MNTOPT_PCFS_TIMEZONE, NULL, "+0", MO_DEFAULT | MO_HASVALUE, NULL },
{ MNTOPT_PCFS_SECSIZE, NULL, NULL, MO_HASVALUE, NULL }
};
static mntopts_t pcfs_mntopts = {
sizeof (mntopts) / sizeof (mntopt_t),
mntopts
};
int pcfsdebuglevel = 0;
/*
* pcfslock: protects the list of mounted pc filesystems "pc_mounttab.
* pcfs_lock: (inside per filesystem structure "pcfs")
* per filesystem lock. Most of the vfsops and vnodeops are
* protected by this lock.
* pcnodes_lock: protects the pcnode hash table "pcdhead", "pcfhead".
*
* Lock hierarchy: pcfslock > pcfs_lock > pcnodes_lock
*
* pcfs_mountcount: used to prevent module unloads while there is still
* pcfs state from a former mount hanging around. With
* forced umount support, the filesystem module must not
* be allowed to go away before the last VFS_FREEVFS()
* call has been made.
* Since this is just an atomic counter, there's no need
* for locking.
*/
kmutex_t pcfslock;
krwlock_t pcnodes_lock;
uint32_t pcfs_mountcount;
static int pcfstype;
static vfsdef_t vfw = {
VFSDEF_VERSION,
"pcfs",
pcfsinit,
VSW_HASPROTO|VSW_CANREMOUNT|VSW_STATS|VSW_CANLOFI,
&pcfs_mntopts
};
extern struct mod_ops mod_fsops;
static struct modlfs modlfs = {
&mod_fsops,
"PC filesystem",
&vfw
};
static struct modlinkage modlinkage = {
MODREV_1,
&modlfs,
NULL
};
int
_init(void)
{
int error;
#if !defined(lint)
/* make sure the on-disk structures are sane */
ASSERT(sizeof (struct pcdir) == 32);
ASSERT(sizeof (struct pcdir_lfn) == 32);
#endif
mutex_init(&pcfslock, NULL, MUTEX_DEFAULT, NULL);
rw_init(&pcnodes_lock, NULL, RW_DEFAULT, NULL);
error = mod_install(&modlinkage);
if (error) {
mutex_destroy(&pcfslock);
rw_destroy(&pcnodes_lock);
}
return (error);
}
int
_fini(void)
{
int error;
/*
* If a forcedly unmounted instance is still hanging around,
* we cannot allow the module to be unloaded because that would
* cause panics once the VFS framework decides it's time to call
* into VFS_FREEVFS().
*/
if (pcfs_mountcount)
return (EBUSY);
error = mod_remove(&modlinkage);
if (error)
return (error);
mutex_destroy(&pcfslock);
rw_destroy(&pcnodes_lock);
/*
* Tear down the operations vectors
*/
(void) vfs_freevfsops_by_type(pcfstype);
vn_freevnodeops(pcfs_fvnodeops);
vn_freevnodeops(pcfs_dvnodeops);
return (0);
}
int
_info(struct modinfo *modinfop)
{
return (mod_info(&modlinkage, modinfop));
}
/* ARGSUSED1 */
static int
pcfsinit(int fstype, char *name)
{
static const fs_operation_def_t pcfs_vfsops_template[] = {
VFSNAME_MOUNT, { .vfs_mount = pcfs_mount },
VFSNAME_UNMOUNT, { .vfs_unmount = pcfs_unmount },
VFSNAME_ROOT, { .vfs_root = pcfs_root },
VFSNAME_STATVFS, { .vfs_statvfs = pcfs_statvfs },
VFSNAME_SYNC, { .vfs_sync = pcfs_sync },
VFSNAME_VGET, { .vfs_vget = pcfs_vget },
VFSNAME_FREEVFS, { .vfs_freevfs = pcfs_freevfs },
NULL, NULL
};
int error;
error = vfs_setfsops(fstype, pcfs_vfsops_template, NULL);
if (error != 0) {
cmn_err(CE_WARN, "pcfsinit: bad vfs ops template");
return (error);
}
error = vn_make_ops("pcfs", pcfs_fvnodeops_template, &pcfs_fvnodeops);
if (error != 0) {
(void) vfs_freevfsops_by_type(fstype);
cmn_err(CE_WARN, "pcfsinit: bad file vnode ops template");
return (error);
}
error = vn_make_ops("pcfsd", pcfs_dvnodeops_template, &pcfs_dvnodeops);
if (error != 0) {
(void) vfs_freevfsops_by_type(fstype);
vn_freevnodeops(pcfs_fvnodeops);
cmn_err(CE_WARN, "pcfsinit: bad dir vnode ops template");
return (error);
}
pcfstype = fstype;
(void) pc_init();
pcfs_mountcount = 0;
return (0);
}
static struct pcfs *pc_mounttab = NULL;
extern struct pcfs_args pc_tz;
/*
* Define some special logical drives we use internal to this file.
*/
#define BOOT_PARTITION_DRIVE 99
#define PRIMARY_DOS_DRIVE 1
#define UNPARTITIONED_DRIVE 0
static int
pcfs_device_identify(
struct vfs *vfsp,
struct mounta *uap,
struct cred *cr,
int *dos_ldrive,
dev_t *xdev)
{
struct pathname special;
char *c;
struct vnode *svp = NULL;
struct vnode *lvp = NULL;
int oflag, aflag;
int error;
/*
* Resolve path name of special file being mounted.
*/
if (error = pn_get(uap->spec, UIO_USERSPACE, &special)) {
return (error);
}
*dos_ldrive = -1;
if (error =
lookupname(special.pn_path, UIO_SYSSPACE, FOLLOW, NULLVPP, &svp)) {
/*
* If there's no device node, the name specified most likely
* maps to a PCFS-style "partition specifier" to select a
* harddisk primary/logical partition. Disable floppy-specific
* checks in such cases unless an explicit :A or :B is
* requested.
*/
/*
* Split the pathname string at the last ':' separator.
* If there's no ':' in the device name, or the ':' is the
* last character in the string, the name is invalid and
* the error from the previous lookup will be returned.
*/
c = strrchr(special.pn_path, ':');
if (c == NULL || strlen(c) == 0)
goto devlookup_done;
*c++ = '\0';
/*
* PCFS partition name suffixes can be:
* - "boot" to indicate the X86BOOT partition
* - a drive letter [c-z] for the "DOS logical drive"
* - a drive number 1..24 for the "DOS logical drive"
* - a "floppy name letter", 'a' or 'b' (just strip this)
*/
if (strcasecmp(c, "boot") == 0) {
/*
* The Solaris boot partition is requested.
*/
*dos_ldrive = BOOT_PARTITION_DRIVE;
} else if (strspn(c, "0123456789") == strlen(c)) {
/*
* All digits - parse the partition number.
*/
long drvnum = 0;
if ((error = ddi_strtol(c, NULL, 10, &drvnum)) == 0) {
/*
* A number alright - in the allowed range ?
*/
if (drvnum > 24 || drvnum == 0)
error = ENXIO;
}
if (error)
goto devlookup_done;
*dos_ldrive = (int)drvnum;
} else if (strlen(c) == 1) {
/*
* A single trailing character was specified.
* - [c-zC-Z] means a harddisk partition, and
* we retrieve the partition number.
* - [abAB] means a floppy drive, so we swallow
* the "drive specifier" and test later
* whether the physical device is a floppy.
*/
*c = tolower(*c);
if (*c == 'a' || *c == 'b') {
*dos_ldrive = UNPARTITIONED_DRIVE;
} else if (*c < 'c' || *c > 'z') {
error = ENXIO;
goto devlookup_done;
} else {
*dos_ldrive = 1 + *c - 'c';
}
} else {
/*
* Can't parse this - pass through previous error.
*/
goto devlookup_done;
}
error = lookupname(special.pn_path, UIO_SYSSPACE, FOLLOW,
NULLVPP, &svp);
} else {
*dos_ldrive = UNPARTITIONED_DRIVE;
}
devlookup_done:
pn_free(&special);
if (error)
return (error);
ASSERT(*dos_ldrive >= UNPARTITIONED_DRIVE);
/*
* Verify caller's permission to open the device special file.
*/
if ((vfsp->vfs_flag & VFS_RDONLY) != 0 ||
((uap->flags & MS_RDONLY) != 0)) {
oflag = FREAD;
aflag = VREAD;
} else {
oflag = FREAD | FWRITE;
aflag = VREAD | VWRITE;
}
error = vfs_get_lofi(vfsp, &lvp);
if (error > 0) {
if (error == ENOENT)
error = ENODEV;
goto out;
} else if (error == 0) {
*xdev = lvp->v_rdev;
} else {
*xdev = svp->v_rdev;
if (svp->v_type != VBLK) {
error = ENOTBLK;
goto out;
}
if ((error = secpolicy_spec_open(cr, svp, oflag)) != 0)
goto out;
}
if (getmajor(*xdev) >= devcnt) {
error = ENXIO;
goto out;
}
if ((error = VOP_ACCESS(svp, aflag, 0, cr, NULL)) != 0)
goto out;
out:
if (svp != NULL)
VN_RELE(svp);
if (lvp != NULL)
VN_RELE(lvp);
return (error);
}
static int
pcfs_device_ismounted(
struct vfs *vfsp,
int dos_ldrive,
dev_t xdev,
int *remounting,
dev_t *pseudodev)
{
struct pcfs *fsp;
int remount = *remounting;
/*
* Ensure that this logical drive isn't already mounted, unless
* this is a REMOUNT request.
* Note: The framework will perform this check if the "...:c"
* PCFS-style "logical drive" syntax has not been used and an
* actually existing physical device is backing this filesystem.
* Once all block device drivers support PC-style partitioning,
* this codeblock can be dropped.
*/
*pseudodev = xdev;
if (dos_ldrive) {
mutex_enter(&pcfslock);
for (fsp = pc_mounttab; fsp; fsp = fsp->pcfs_nxt)
if (fsp->pcfs_xdev == xdev &&
fsp->pcfs_ldrive == dos_ldrive) {
mutex_exit(&pcfslock);
if (remount) {
return (0);
} else {
return (EBUSY);
}
}
/*
* Assign a unique device number for the vfs
* The old way (getudev() + a constantly incrementing
* major number) was wrong because it changes vfs_dev
* across mounts and reboots, which breaks nfs file handles.
* UFS just uses the real dev_t. We can't do that because
* of the way pcfs opens fdisk partitons (the :c and :d
* partitions are on the same dev_t). Though that _might_
* actually be ok, since the file handle contains an
* absolute block number, it's probably better to make them
* different. So I think we should retain the original
* dev_t, but come up with a different minor number based
* on the logical drive that will _always_ come up the same.
* For now, we steal the upper 6 bits.
*/
#ifdef notdef
/* what should we do here? */
if (((getminor(xdev) >> 12) & 0x3F) != 0)
printf("whoops - upper bits used!\n");
#endif
*pseudodev = makedevice(getmajor(xdev),
((dos_ldrive << 12) | getminor(xdev)) & MAXMIN32);
if (vfs_devmounting(*pseudodev, vfsp)) {
mutex_exit(&pcfslock);
return (EBUSY);
}
if (vfs_devismounted(*pseudodev)) {
mutex_exit(&pcfslock);
if (remount) {
return (0);
} else {
return (EBUSY);
}
}
mutex_exit(&pcfslock);
} else {
*pseudodev = xdev;
if (vfs_devmounting(*pseudodev, vfsp)) {
return (EBUSY);
}
if (vfs_devismounted(*pseudodev))
if (remount) {
return (0);
} else {
return (EBUSY);
}
}
/*
* This is not a remount. Even if MS_REMOUNT was requested,
* the caller needs to proceed as it would on an ordinary
* mount.
*/
*remounting = 0;
ASSERT(*pseudodev);
return (0);
}
/*
* Get the PCFS-specific mount options from the VFS framework.
* For "timezone" and "secsize", we need to parse the number
* ourselves and ensure its validity.
* Note: "secsize" is deliberately undocumented at this time,
* it's a workaround for devices (particularly: lofi image files)
* that don't support the DKIOCGMEDIAINFO ioctl for autodetection.
*/
static void
pcfs_parse_mntopts(struct pcfs *fsp)
{
char *c;
char *endptr;
long l;
struct vfs *vfsp = fsp->pcfs_vfs;
ASSERT(fsp->pcfs_secondswest == 0);
ASSERT(fsp->pcfs_secsize == 0);
if (vfs_optionisset(vfsp, MNTOPT_PCFS_HIDDEN, NULL))
fsp->pcfs_flags |= PCFS_HIDDEN;
if (vfs_optionisset(vfsp, MNTOPT_PCFS_FOLDCASE, NULL))
fsp->pcfs_flags |= PCFS_FOLDCASE;
if (vfs_optionisset(vfsp, MNTOPT_PCFS_NOCLAMPTIME, NULL))
fsp->pcfs_flags |= PCFS_NOCLAMPTIME;
if (vfs_optionisset(vfsp, MNTOPT_NOATIME, NULL))
fsp->pcfs_flags |= PCFS_NOATIME;
if (vfs_optionisset(vfsp, MNTOPT_PCFS_TIMEZONE, &c)) {
if (ddi_strtol(c, &endptr, 10, &l) == 0 &&
endptr == c + strlen(c)) {
/*
* A number alright - in the allowed range ?
*/
if (l <= -12*3600 || l >= 12*3600) {
cmn_err(CE_WARN, "!pcfs: invalid use of "
"'timezone' mount option - %ld "
"is out of range. Assuming 0.", l);
l = 0;
}
} else {
cmn_err(CE_WARN, "!pcfs: invalid use of "
"'timezone' mount option - argument %s "
"is not a valid number. Assuming 0.", c);
l = 0;
}
fsp->pcfs_secondswest = l;
}
/*
* The "secsize=..." mount option is a workaround for the lack of
* lofi(7d) support for DKIOCGMEDIAINFO. If PCFS wants to parse the
* partition table of a disk image and it has been partitioned with
* sector sizes other than 512 bytes, we'd fail on loopback'ed disk
* images.
* That should really be fixed in lofi ... this is a workaround.
*/
if (vfs_optionisset(vfsp, MNTOPT_PCFS_SECSIZE, &c)) {
if (ddi_strtol(c, &endptr, 10, &l) == 0 &&
endptr == c + strlen(c)) {
/*
* A number alright - a valid sector size as well ?
*/
if (!VALID_SECSIZE(l)) {
cmn_err(CE_WARN, "!pcfs: invalid use of "
"'secsize' mount option - %ld is "
"unsupported. Autodetecting.", l);
l = 0;
}
} else {
cmn_err(CE_WARN, "!pcfs: invalid use of "
"'secsize' mount option - argument %s "
"is not a valid number. Autodetecting.", c);
l = 0;
}
fsp->pcfs_secsize = l;
fsp->pcfs_sdshift = ddi_ffs(l / DEV_BSIZE) - 1;
}
}
/*
* vfs operations
*/
/*
* pcfs_mount - backend for VFS_MOUNT() on PCFS.
*/
static int
pcfs_mount(
struct vfs *vfsp,
struct vnode *mvp,
struct mounta *uap,
struct cred *cr)
{
struct pcfs *fsp;
struct vnode *devvp;
dev_t pseudodev;
dev_t xdev;
int dos_ldrive = 0;
int error;
int remounting;
if ((error = secpolicy_fs_mount(cr, mvp, vfsp)) != 0)
return (error);
if (mvp->v_type != VDIR)
return (ENOTDIR);
mutex_enter(&mvp->v_lock);
if ((uap->flags & MS_REMOUNT) == 0 &&
(uap->flags & MS_OVERLAY) == 0 &&
(mvp->v_count != 1 || (mvp->v_flag & VROOT))) {
mutex_exit(&mvp->v_lock);
return (EBUSY);
}
mutex_exit(&mvp->v_lock);
/*
* PCFS doesn't do mount arguments anymore - everything's a mount
* option these days. In order not to break existing callers, we
* don't reject it yet, just warn that the data (if any) is ignored.
*/
if (uap->datalen != 0)
cmn_err(CE_WARN, "!pcfs: deprecated use of mount(2) with "
"mount argument structures instead of mount options. "
"Ignoring mount(2) 'dataptr' argument.");
/*
* This is needed early, to make sure the access / open calls
* are done using the correct mode. Processing this mount option
* only when calling pcfs_parse_mntopts() would lead us to attempt
* a read/write access to a possibly writeprotected device, and
* a readonly mount attempt might fail because of that.
*/
if (uap->flags & MS_RDONLY) {
vfsp->vfs_flag |= VFS_RDONLY;
vfs_setmntopt(vfsp, MNTOPT_RO, NULL, 0);
}
/*
* For most filesystems, this is just a lookupname() on the
* mount pathname string. PCFS historically has to do its own
* partition table parsing because not all Solaris architectures
* support all styles of partitioning that PC media can have, and
* hence PCFS understands "device names" that don't map to actual
* physical device nodes. Parsing the "PCFS syntax" for device
* names is done in pcfs_device_identify() - see there.
*
* Once all block device drivers that can host FAT filesystems have
* been enhanced to create device nodes for all PC-style partitions,
* this code can go away.
*/
if (error = pcfs_device_identify(vfsp, uap, cr, &dos_ldrive, &xdev))
return (error);
/*
* As with looking up the actual device to mount, PCFS cannot rely
* on just the checks done by vfs_ismounted() whether a given device
* is mounted already. The additional check against the "PCFS syntax"
* is done in pcfs_device_ismounted().
*/
remounting = (uap->flags & MS_REMOUNT);
if (error = pcfs_device_ismounted(vfsp, dos_ldrive, xdev, &remounting,
&pseudodev))
return (error);
if (remounting)
return (0);
/*
* Mount the filesystem.
* An instance structure is required before the attempt to locate
* and parse the FAT BPB. This is because mount options may change
* the behaviour of the filesystem type matching code. Precreate
* it and fill it in to a degree that allows parsing the mount
* options.
*/
devvp = makespecvp(xdev, VBLK);
if (IS_SWAPVP(devvp)) {
VN_RELE(devvp);
return (EBUSY);
}
error = VOP_OPEN(&devvp,
(vfsp->vfs_flag & VFS_RDONLY) ? FREAD : FREAD | FWRITE, cr, NULL);
if (error) {
VN_RELE(devvp);
return (error);
}
fsp = kmem_zalloc(sizeof (*fsp), KM_SLEEP);
fsp->pcfs_vfs = vfsp;
fsp->pcfs_xdev = xdev;
fsp->pcfs_devvp = devvp;
fsp->pcfs_ldrive = dos_ldrive;
mutex_init(&fsp->pcfs_lock, NULL, MUTEX_DEFAULT, NULL);
pcfs_parse_mntopts(fsp);
/*
* This is the actual "mount" - the PCFS superblock check.
*
* Find the requested logical drive and the FAT BPB therein.
* Check device type and flag the instance if media is removeable.
*
* Initializes most members of the filesystem instance structure.
* Returns EINVAL if no valid BPB can be found. Other errors may
* occur after I/O failures, or when invalid / unparseable partition
* tables are encountered.
*/
if (error = pc_getfattype(fsp))
goto errout;
/*
* Now that the BPB has been parsed, this structural information
* is available and known to be valid. Initialize the VFS.
*/
vfsp->vfs_data = fsp;
vfsp->vfs_dev = pseudodev;
vfsp->vfs_fstype = pcfstype;
vfs_make_fsid(&vfsp->vfs_fsid, pseudodev, pcfstype);
vfsp->vfs_bcount = 0;
vfsp->vfs_bsize = fsp->pcfs_clsize;
/*
* Validate that we can access the FAT and that it is, to the
* degree we can verify here, self-consistent.
*/
if (error = pc_verify(fsp))
goto errout;
/*
* Record the time of the mount, to return as an "approximate"
* timestamp for the FAT root directory. Since FAT roots don't
* have timestamps, this is less confusing to the user than
* claiming "zero" / Jan/01/1970.
*/
gethrestime(&fsp->pcfs_mounttime);
/*
* Fix up the mount options. Because "noatime" is made default on
* removeable media only, a fixed disk will have neither "atime"
* nor "noatime" set. We set the options explicitly depending on
* the PCFS_NOATIME flag, to inform the user of what applies.
* Mount option cancellation will take care that the mutually
* exclusive 'other' is cleared.
*/
vfs_setmntopt(vfsp,
fsp->pcfs_flags & PCFS_NOATIME ? MNTOPT_NOATIME : MNTOPT_ATIME,
NULL, 0);
/*
* All clear - insert the FS instance into PCFS' list.
*/
mutex_enter(&pcfslock);
fsp->pcfs_nxt = pc_mounttab;
pc_mounttab = fsp;
mutex_exit(&pcfslock);
atomic_inc_32(&pcfs_mountcount);
return (0);
errout:
(void) VOP_CLOSE(devvp,
vfsp->vfs_flag & VFS_RDONLY ? FREAD : FREAD | FWRITE,
1, (offset_t)0, cr, NULL);
VN_RELE(devvp);
mutex_destroy(&fsp->pcfs_lock);
kmem_free(fsp, sizeof (*fsp));
return (error);
}
static int
pcfs_unmount(
struct vfs *vfsp,
int flag,
struct cred *cr)
{
struct pcfs *fsp, *fsp1;
if (secpolicy_fs_unmount(cr, vfsp) != 0)
return (EPERM);
fsp = VFSTOPCFS(vfsp);
/*
* We don't have to lock fsp because the VVFSLOCK in vfs layer will
* prevent lookuppn from crossing the mount point.
* If this is not a forced umount request and there's ongoing I/O,
* don't allow the mount to proceed.
*/
if (flag & MS_FORCE)
vfsp->vfs_flag |= VFS_UNMOUNTED;
else if (fsp->pcfs_nrefs)
return (EBUSY);
mutex_enter(&pcfslock);
/*
* If this is a forced umount request or if the fs instance has
* been marked as beyond recovery, allow the umount to proceed
* regardless of state. pc_diskchanged() forcibly releases all
* inactive vnodes/pcnodes.
*/
if (flag & MS_FORCE || fsp->pcfs_flags & PCFS_IRRECOV) {
rw_enter(&pcnodes_lock, RW_WRITER);
pc_diskchanged(fsp);
rw_exit(&pcnodes_lock);
}
/* now there should be no pcp node on pcfhead or pcdhead. */
if (fsp == pc_mounttab) {
pc_mounttab = fsp->pcfs_nxt;
} else {
for (fsp1 = pc_mounttab; fsp1 != NULL; fsp1 = fsp1->pcfs_nxt)
if (fsp1->pcfs_nxt == fsp)
fsp1->pcfs_nxt = fsp->pcfs_nxt;
}
mutex_exit(&pcfslock);
/*
* Since we support VFS_FREEVFS(), there's no need to
* free the fsp right now. The framework will tell us
* when the right time to do so has arrived by calling
* into pcfs_freevfs.
*/
return (0);
}
/*
* find root of pcfs
*/
static int
pcfs_root(
struct vfs *vfsp,
struct vnode **vpp)
{
struct pcfs *fsp;
struct pcnode *pcp;
int error;
fsp = VFSTOPCFS(vfsp);
if (error = pc_lockfs(fsp, 0, 0))
return (error);
pcp = pc_getnode(fsp, (daddr_t)0, 0, (struct pcdir *)0);
pc_unlockfs(fsp);
*vpp = PCTOV(pcp);
pcp->pc_flags |= PC_EXTERNAL;
return (0);
}
/*
* Get file system statistics.
*/
static int
pcfs_statvfs(
struct vfs *vfsp,
struct statvfs64 *sp)
{
struct pcfs *fsp;
int error;
dev32_t d32;
fsp = VFSTOPCFS(vfsp);
error = pc_getfat(fsp);
if (error)
return (error);
bzero(sp, sizeof (*sp));
sp->f_bsize = sp->f_frsize = fsp->pcfs_clsize;
sp->f_blocks = (fsblkcnt64_t)fsp->pcfs_ncluster;
sp->f_bavail = sp->f_bfree = (fsblkcnt64_t)pc_freeclusters(fsp);
sp->f_files = (fsfilcnt64_t)-1;
sp->f_ffree = (fsfilcnt64_t)-1;
sp->f_favail = (fsfilcnt64_t)-1;
#ifdef notdef
(void) cmpldev(&d32, fsp->pcfs_devvp->v_rdev);
#endif /* notdef */
(void) cmpldev(&d32, vfsp->vfs_dev);
sp->f_fsid = d32;
(void) strcpy(sp->f_basetype, vfssw[vfsp->vfs_fstype].vsw_name);
sp->f_flag = vf_to_stf(vfsp->vfs_flag);
sp->f_namemax = PCMAXNAMLEN;
return (0);
}
static int
pc_syncfsnodes(struct pcfs *fsp)
{
struct pchead *hp;
struct pcnode *pcp;
int error;
if (error = pc_lockfs(fsp, 0, 0))
return (error);
if (!(error = pc_syncfat(fsp))) {
hp = pcfhead;
while (hp < & pcfhead [ NPCHASH ]) {
rw_enter(&pcnodes_lock, RW_READER);
pcp = hp->pch_forw;
while (pcp != (struct pcnode *)hp) {
if (VFSTOPCFS(PCTOV(pcp) -> v_vfsp) == fsp)
if (error = pc_nodesync(pcp))
break;
pcp = pcp -> pc_forw;
}
rw_exit(&pcnodes_lock);
if (error)
break;
hp++;
}
}
pc_unlockfs(fsp);
return (error);
}
/*
* Flush any pending I/O.
*/
/*ARGSUSED*/
static int
pcfs_sync(
struct vfs *vfsp,
short flag,
struct cred *cr)
{
struct pcfs *fsp;
int error = 0;
/* this prevents the filesystem from being umounted. */
mutex_enter(&pcfslock);
if (vfsp != NULL) {
fsp = VFSTOPCFS(vfsp);
if (!(fsp->pcfs_flags & PCFS_IRRECOV)) {
error = pc_syncfsnodes(fsp);
} else {
rw_enter(&pcnodes_lock, RW_WRITER);
pc_diskchanged(fsp);
rw_exit(&pcnodes_lock);
error = EIO;
}
} else {
fsp = pc_mounttab;
while (fsp != NULL) {
if (fsp->pcfs_flags & PCFS_IRRECOV) {
rw_enter(&pcnodes_lock, RW_WRITER);
pc_diskchanged(fsp);
rw_exit(&pcnodes_lock);
error = EIO;
break;
}
error = pc_syncfsnodes(fsp);
if (error) break;
fsp = fsp->pcfs_nxt;
}
}
mutex_exit(&pcfslock);
return (error);
}
int
pc_lockfs(struct pcfs *fsp, int diskchanged, int releasing)
{
int err;
if ((fsp->pcfs_flags & PCFS_IRRECOV) && !releasing)
return (EIO);
if ((fsp->pcfs_flags & PCFS_LOCKED) && (fsp->pcfs_owner == curthread)) {
fsp->pcfs_count++;
} else {
mutex_enter(&fsp->pcfs_lock);
if (fsp->pcfs_flags & PCFS_LOCKED)
panic("pc_lockfs");
/*
* We check the IRRECOV bit again just in case somebody
* snuck past the initial check but then got held up before
* they could grab the lock. (And in the meantime someone
* had grabbed the lock and set the bit)
*/
if (!diskchanged && !(fsp->pcfs_flags & PCFS_IRRECOV)) {
if ((err = pc_getfat(fsp))) {
mutex_exit(&fsp->pcfs_lock);
return (err);
}
}
fsp->pcfs_flags |= PCFS_LOCKED;
fsp->pcfs_owner = curthread;
fsp->pcfs_count++;
}
return (0);
}
void
pc_unlockfs(struct pcfs *fsp)
{
if ((fsp->pcfs_flags & PCFS_LOCKED) == 0)
panic("pc_unlockfs");
if (--fsp->pcfs_count < 0)
panic("pc_unlockfs: count");
if (fsp->pcfs_count == 0) {
fsp->pcfs_flags &= ~PCFS_LOCKED;
fsp->pcfs_owner = 0;
mutex_exit(&fsp->pcfs_lock);
}
}
int
pc_syncfat(struct pcfs *fsp)
{
struct buf *bp;
int nfat;
int error = 0;
struct fat_od_fsi *fsinfo_disk;
if ((fsp->pcfs_fatp == (uchar_t *)0) ||
!(fsp->pcfs_flags & PCFS_FATMOD))
return (0);
/*
* write out all copies of FATs
*/
fsp->pcfs_flags &= ~PCFS_FATMOD;
fsp->pcfs_fattime = gethrestime_sec() + PCFS_DISKTIMEOUT;
for (nfat = 0; nfat < fsp->pcfs_numfat; nfat++) {
error = pc_writefat(fsp, pc_dbdaddr(fsp,
fsp->pcfs_fatstart + nfat * fsp->pcfs_fatsec));
if (error) {
pc_mark_irrecov(fsp);
return (EIO);
}
}
pc_clear_fatchanges(fsp);
/*
* Write out fsinfo sector.
*/
if (IS_FAT32(fsp)) {
bp = bread(fsp->pcfs_xdev,
pc_dbdaddr(fsp, fsp->pcfs_fsistart), fsp->pcfs_secsize);
if (bp->b_flags & (B_ERROR | B_STALE)) {
error = geterror(bp);
}
fsinfo_disk = (fat_od_fsi_t *)(bp->b_un.b_addr);
if (!error && FSISIG_OK(fsinfo_disk)) {
fsinfo_disk->fsi_incore.fs_free_clusters =
LE_32(fsp->pcfs_fsinfo.fs_free_clusters);
fsinfo_disk->fsi_incore.fs_next_free =
LE_32(FSINFO_UNKNOWN);
bwrite2(bp);
error = geterror(bp);
}
brelse(bp);
if (error) {
pc_mark_irrecov(fsp);
return (EIO);
}
}
return (0);
}
void
pc_invalfat(struct pcfs *fsp)
{
struct pcfs *xfsp;
int mount_cnt = 0;
if (fsp->pcfs_fatp == (uchar_t *)0)
panic("pc_invalfat");
/*
* Release FAT
*/
kmem_free(fsp->pcfs_fatp, fsp->pcfs_fatsec * fsp->pcfs_secsize);
fsp->pcfs_fatp = NULL;
kmem_free(fsp->pcfs_fat_changemap, fsp->pcfs_fat_changemapsize);
fsp->pcfs_fat_changemap = NULL;
/*
* Invalidate all the blocks associated with the device.
* Not needed if stateless.
*/
for (xfsp = pc_mounttab; xfsp; xfsp = xfsp->pcfs_nxt)
if (xfsp != fsp && xfsp->pcfs_xdev == fsp->pcfs_xdev)
mount_cnt++;
if (!mount_cnt)
binval(fsp->pcfs_xdev);
/*
* close mounted device
*/
(void) VOP_CLOSE(fsp->pcfs_devvp,
(PCFSTOVFS(fsp)->vfs_flag & VFS_RDONLY) ? FREAD : FREAD|FWRITE,
1, (offset_t)0, CRED(), NULL);
}
void
pc_badfs(struct pcfs *fsp)
{
cmn_err(CE_WARN, "corrupted PC file system on dev (%x.%x):%d\n",
getmajor(fsp->pcfs_devvp->v_rdev),
getminor(fsp->pcfs_devvp->v_rdev), fsp->pcfs_ldrive);
}
/*
* The problem with supporting NFS on the PCFS filesystem is that there
* is no good place to keep the generation number. The only possible
* place is inside a directory entry. There are a few words that we
* don't use - they store NT & OS/2 attributes, and the creation/last access
* time of the file - but it seems wrong to use them. In addition, directory
* entries come and go. If a directory is removed completely, its directory
* blocks are freed and the generation numbers are lost. Whereas in ufs,
* inode blocks are dedicated for inodes, so the generation numbers are
* permanently kept on the disk.
*/
static int
pcfs_vget(struct vfs *vfsp, struct vnode **vpp, struct fid *fidp)
{
struct pcnode *pcp;
struct pc_fid *pcfid;
struct pcfs *fsp;
struct pcdir *ep;
daddr_t eblkno;
int eoffset;
struct buf *bp;
int error;
pc_cluster32_t cn;
pcfid = (struct pc_fid *)fidp;
fsp = VFSTOPCFS(vfsp);
error = pc_lockfs(fsp, 0, 0);
if (error) {
*vpp = NULL;
return (error);
}
if (pcfid->pcfid_block == 0) {
pcp = pc_getnode(fsp, (daddr_t)0, 0, (struct pcdir *)0);
pcp->pc_flags |= PC_EXTERNAL;
*vpp = PCTOV(pcp);
pc_unlockfs(fsp);
return (0);
}
eblkno = pcfid->pcfid_block;
eoffset = pcfid->pcfid_offset;
if ((pc_dbtocl(fsp,
eblkno - fsp->pcfs_dosstart) >= fsp->pcfs_ncluster) ||
(eoffset > fsp->pcfs_clsize)) {
pc_unlockfs(fsp);
*vpp = NULL;
return (EINVAL);
}
if (eblkno >= fsp->pcfs_datastart || (eblkno - fsp->pcfs_rdirstart)
< (fsp->pcfs_rdirsec & ~(fsp->pcfs_spcl - 1))) {
bp = bread(fsp->pcfs_xdev, pc_dbdaddr(fsp, eblkno),
fsp->pcfs_clsize);
} else {
/*
* This is an access "backwards" into the FAT12/FAT16
* root directory. A better code structure would
* significantly improve maintainability here ...
*/
bp = bread(fsp->pcfs_xdev, pc_dbdaddr(fsp, eblkno),
(int)(fsp->pcfs_datastart - eblkno) * fsp->pcfs_secsize);
}
if (bp->b_flags & (B_ERROR | B_STALE)) {
error = geterror(bp);
brelse(bp);
if (error)
pc_mark_irrecov(fsp);
*vpp = NULL;
pc_unlockfs(fsp);
return (error);
}
ep = (struct pcdir *)(bp->b_un.b_addr + eoffset);
/*
* Ok, if this is a valid file handle that we gave out,
* then simply ensuring that the creation time matches,
* the entry has not been deleted, and it has a valid first
* character should be enough.
*
* Unfortunately, verifying that the <blkno, offset> _still_
* refers to a directory entry is not easy, since we'd have
* to search _all_ directories starting from root to find it.
* That's a high price to pay just in case somebody is forging
* file handles. So instead we verify that as much of the
* entry is valid as we can:
*
* 1. The starting cluster is 0 (unallocated) or valid
* 2. It is not an LFN entry
* 3. It is not hidden (unless mounted as such)
* 4. It is not the label
*/
cn = pc_getstartcluster(fsp, ep);
/*
* if the starting cluster is valid, but not valid according
* to pc_validcl(), force it to be to simplify the following if.
*/
if (cn == 0)
cn = PCF_FIRSTCLUSTER;
if (IS_FAT32(fsp)) {
if (cn >= PCF_LASTCLUSTER32)
cn = PCF_FIRSTCLUSTER;
} else {
if (cn >= PCF_LASTCLUSTER)
cn = PCF_FIRSTCLUSTER;
}
if ((!pc_validcl(fsp, cn)) ||
(PCDL_IS_LFN(ep)) ||
(PCA_IS_HIDDEN(fsp, ep->pcd_attr)) ||
((ep->pcd_attr & PCA_LABEL) == PCA_LABEL)) {
bp->b_flags |= B_STALE | B_AGE;
brelse(bp);
pc_unlockfs(fsp);
return (EINVAL);
}
if ((ep->pcd_crtime.pct_time == pcfid->pcfid_ctime) &&
(ep->pcd_filename[0] != PCD_ERASED) &&
(pc_validchar(ep->pcd_filename[0]) ||
(ep->pcd_filename[0] == '.' && ep->pcd_filename[1] == '.'))) {
pcp = pc_getnode(fsp, eblkno, eoffset, ep);
pcp->pc_flags |= PC_EXTERNAL;
*vpp = PCTOV(pcp);
} else {
*vpp = NULL;
}
bp->b_flags |= B_STALE | B_AGE;
brelse(bp);
pc_unlockfs(fsp);
return (0);
}
/*
* Unfortunately, FAT32 fat's can be pretty big (On a 1 gig jaz drive, about
* a meg), so we can't bread() it all in at once. This routine reads a
* fat a chunk at a time.
*/
static int
pc_readfat(struct pcfs *fsp, uchar_t *fatp)
{
struct buf *bp;
size_t off;
size_t readsize;
daddr_t diskblk;
size_t fatsize = fsp->pcfs_fatsec * fsp->pcfs_secsize;
daddr_t start = fsp->pcfs_fatstart;
readsize = fsp->pcfs_clsize;
for (off = 0; off < fatsize; off += readsize, fatp += readsize) {
if (readsize > (fatsize - off))
readsize = fatsize - off;
diskblk = pc_dbdaddr(fsp, start +
pc_cltodb(fsp, pc_lblkno(fsp, off)));
bp = bread(fsp->pcfs_xdev, diskblk, readsize);
if (bp->b_flags & (B_ERROR | B_STALE)) {
brelse(bp);
return (EIO);
}
bp->b_flags |= B_STALE | B_AGE;
bcopy(bp->b_un.b_addr, fatp, readsize);
brelse(bp);
}
return (0);
}
/*
* We write the FAT out a _lot_, in order to make sure that it
* is up-to-date. But on a FAT32 system (large drive, small clusters)
* the FAT might be a couple of megabytes, and writing it all out just
* because we created or deleted a small file is painful (especially
* since we do it for each alternate FAT too). So instead, for FAT16 and
* FAT32 we only write out the bit that has changed. We don't clear
* the 'updated' fields here because the caller might be writing out
* several FATs, so the caller must use pc_clear_fatchanges() after
* all FATs have been updated.
* This function doesn't take "start" from fsp->pcfs_dosstart because
* callers can use it to write either the primary or any of the alternate
* FAT tables.
*/
static int
pc_writefat(struct pcfs *fsp, daddr_t start)
{
struct buf *bp;
size_t off;
size_t writesize;
int error;
uchar_t *fatp = fsp->pcfs_fatp;
size_t fatsize = fsp->pcfs_fatsec * fsp->pcfs_secsize;
writesize = fsp->pcfs_clsize;
for (off = 0; off < fatsize; off += writesize, fatp += writesize) {
if (writesize > (fatsize - off))
writesize = fatsize - off;
if (!pc_fat_is_changed(fsp, pc_lblkno(fsp, off))) {
continue;
}
bp = ngeteblk(writesize);
bp->b_edev = fsp->pcfs_xdev;
bp->b_dev = cmpdev(bp->b_edev);
bp->b_blkno = pc_dbdaddr(fsp, start +
pc_cltodb(fsp, pc_lblkno(fsp, off)));
bcopy(fatp, bp->b_un.b_addr, writesize);
bwrite2(bp);
error = geterror(bp);
brelse(bp);
if (error) {
return (error);
}
}
return (0);
}
/*
* Mark the FAT cluster that 'cn' is stored in as modified.
*/
void
pc_mark_fat_updated(struct pcfs *fsp, pc_cluster32_t cn)
{
pc_cluster32_t bn;
size_t size;
/* which fat block is the cluster number stored in? */
if (IS_FAT32(fsp)) {
size = sizeof (pc_cluster32_t);
bn = pc_lblkno(fsp, cn * size);
fsp->pcfs_fat_changemap[bn] = 1;
} else if (IS_FAT16(fsp)) {
size = sizeof (pc_cluster16_t);
bn = pc_lblkno(fsp, cn * size);
fsp->pcfs_fat_changemap[bn] = 1;
} else {
offset_t off;
pc_cluster32_t nbn;
ASSERT(IS_FAT12(fsp));
off = cn + (cn >> 1);
bn = pc_lblkno(fsp, off);
fsp->pcfs_fat_changemap[bn] = 1;
/* does this field wrap into the next fat cluster? */
nbn = pc_lblkno(fsp, off + 1);
if (nbn != bn) {
fsp->pcfs_fat_changemap[nbn] = 1;
}
}
}
/*
* return whether the FAT cluster 'bn' is updated and needs to
* be written out.
*/
int
pc_fat_is_changed(struct pcfs *fsp, pc_cluster32_t bn)
{
return (fsp->pcfs_fat_changemap[bn] == 1);
}
/*
* Implementation of VFS_FREEVFS() to support forced umounts.
* This is called by the vfs framework after umount, to trigger
* the release of any resources still associated with the given
* vfs_t once the need to keep them has gone away.
*/
void
pcfs_freevfs(vfs_t *vfsp)
{
struct pcfs *fsp = VFSTOPCFS(vfsp);
mutex_enter(&pcfslock);
/*
* Purging the FAT closes the device - can't do any more
* I/O after this.
*/
if (fsp->pcfs_fatp != (uchar_t *)0)
pc_invalfat(fsp);
mutex_exit(&pcfslock);
VN_RELE(fsp->pcfs_devvp);
mutex_destroy(&fsp->pcfs_lock);
kmem_free(fsp, sizeof (*fsp));
/*
* Allow _fini() to succeed now, if so desired.
*/
atomic_dec_32(&pcfs_mountcount);
}
/*
* PC-style partition parsing and FAT BPB identification/validation code.
* The partition parsers here assume:
* - a FAT filesystem will be in a partition that has one of a set of
* recognized partition IDs
* - the user wants the 'numbering' (C:, D:, ...) that one would get
* on MSDOS 6.x.
* That means any non-FAT partition type (NTFS, HPFS, or any Linux fs)
* will not factor in the enumeration.
* These days, such assumptions should be revisited. FAT is no longer the
* only game in 'PC town'.
*/
/*
* isDosDrive()
* Boolean function. Give it the systid field for an fdisk partition
* and it decides if that's a systid that describes a DOS drive. We
* use systid values defined in sys/dktp/fdisk.h.
*/
static int
isDosDrive(uchar_t checkMe)
{
return ((checkMe == DOSOS12) || (checkMe == DOSOS16) ||
(checkMe == DOSHUGE) || (checkMe == FDISK_WINDOWS) ||
(checkMe == FDISK_EXT_WIN) || (checkMe == FDISK_FAT95) ||
(checkMe == DIAGPART));
}
/*
* isDosExtended()
* Boolean function. Give it the systid field for an fdisk partition
* and it decides if that's a systid that describes an extended DOS
* partition.
*/
static int
isDosExtended(uchar_t checkMe)
{
return ((checkMe == EXTDOS) || (checkMe == FDISK_EXTLBA));
}
/*
* isBootPart()
* Boolean function. Give it the systid field for an fdisk partition
* and it decides if that's a systid that describes a Solaris boot
* partition.
*/
static int
isBootPart(uchar_t checkMe)
{
return (checkMe == X86BOOT);
}
/*
* noLogicalDrive()
* Display error message about not being able to find a logical
* drive.
*/
static void
noLogicalDrive(int ldrive)
{
if (ldrive == BOOT_PARTITION_DRIVE) {
cmn_err(CE_NOTE, "!pcfs: no boot partition");
} else {
cmn_err(CE_NOTE, "!pcfs: %d: no such logical drive", ldrive);
}
}
/*
* findTheDrive()
* Discover offset of the requested logical drive, and return
* that offset (startSector), the systid of that drive (sysid),
* and a buffer pointer (bp), with the buffer contents being
* the first sector of the logical drive (i.e., the sector that
* contains the BPB for that drive).
*
* Note: this code is not capable of addressing >2TB disks, as it uses
* daddr_t not diskaddr_t, some of the calculations would overflow
*/
#define COPY_PTBL(mbr, ptblp) \
bcopy(&(((struct mboot *)(mbr))->parts), (ptblp), \
FD_NUMPART * sizeof (struct ipart))
static int
findTheDrive(struct pcfs *fsp, buf_t **bp)
{
int ldrive = fsp->pcfs_ldrive;
dev_t dev = fsp->pcfs_devvp->v_rdev;
struct ipart dosp[FD_NUMPART]; /* incore fdisk partition structure */
daddr_t lastseek = 0; /* Disk block we sought previously */
daddr_t diskblk = 0; /* Disk block to get */
daddr_t xstartsect; /* base of Extended DOS partition */
int logicalDriveCount = 0; /* Count of logical drives seen */
int extendedPart = -1; /* index of extended dos partition */
int primaryPart = -1; /* index of primary dos partition */
int bootPart = -1; /* index of a Solaris boot partition */
uint32_t xnumsect = 0; /* length of extended DOS partition */
int driveIndex; /* computed FDISK table index */
daddr_t startsec;
len_t mediasize;
int i;
/*
* Count of drives in the current extended partition's
* FDISK table, and indexes of the drives themselves.
*/
int extndDrives[FD_NUMPART];
int numDrives = 0;
/*
* Count of drives (beyond primary) in master boot record's
* FDISK table, and indexes of the drives themselves.
*/
int extraDrives[FD_NUMPART];
int numExtraDrives = 0;
/*
* "ldrive == 0" should never happen, as this is a request to
* mount the physical device (and ignore partitioning). The code
* in pcfs_mount() should have made sure that a logical drive number
* is at least 1, meaning we're looking for drive "C:". It is not
* safe (and a bug in the callers of this function) to request logical
* drive number 0; we could ASSERT() but a graceful EIO is a more
* polite way.
*/
if (ldrive == 0) {
cmn_err(CE_NOTE, "!pcfs: request for logical partition zero");
noLogicalDrive(ldrive);
return (EIO);
}
/*
* Copy from disk block into memory aligned structure for fdisk usage.
*/
COPY_PTBL((*bp)->b_un.b_addr, dosp);
/*
* This check is ok because a FAT BPB and a master boot record (MBB)
* have the same signature, in the same position within the block.
*/
if (bpb_get_BPBSig((*bp)->b_un.b_addr) != MBB_MAGIC) {
cmn_err(CE_NOTE, "!pcfs: MBR partition table signature err, "
"device (%x.%x):%d\n",
getmajor(dev), getminor(dev), ldrive);
return (EINVAL);
}
/*
* Get a summary of what is in the Master FDISK table.
* Normally we expect to find one partition marked as a DOS drive.
* This partition is the one Windows calls the primary dos partition.
* If the machine has any logical drives then we also expect
* to find a partition marked as an extended DOS partition.
*
* Sometimes we'll find multiple partitions marked as DOS drives.
* The Solaris fdisk program allows these partitions
* to be created, but Windows fdisk no longer does. We still need
* to support these, though, since Windows does. We also need to fix
* our fdisk to behave like the Windows version.
*
* It turns out that some off-the-shelf media have *only* an
* Extended partition, so we need to deal with that case as well.
*
* Only a single (the first) Extended or Boot Partition will
* be recognized. Any others will be ignored.
*/
for (i = 0; i < FD_NUMPART; i++) {
DTRACE_PROBE4(primarypart, struct pcfs *, fsp,
uint_t, (uint_t)dosp[i].systid,
uint_t, LE_32(dosp[i].relsect),
uint_t, LE_32(dosp[i].numsect));
if (isDosDrive(dosp[i].systid)) {
if (primaryPart < 0) {
logicalDriveCount++;
primaryPart = i;
} else {
extraDrives[numExtraDrives++] = i;
}
continue;
}
if ((extendedPart < 0) && isDosExtended(dosp[i].systid)) {
extendedPart = i;
continue;
}
if ((bootPart < 0) && isBootPart(dosp[i].systid)) {
bootPart = i;
continue;
}
}
if (ldrive == BOOT_PARTITION_DRIVE) {
if (bootPart < 0) {
noLogicalDrive(ldrive);
return (EINVAL);
}
startsec = LE_32(dosp[bootPart].relsect);
mediasize = LE_32(dosp[bootPart].numsect);
goto found;
}
if (ldrive == PRIMARY_DOS_DRIVE && primaryPart >= 0) {
startsec = LE_32(dosp[primaryPart].relsect);
mediasize = LE_32(dosp[primaryPart].numsect);
goto found;
}
/*
* We are not looking for the C: drive (or the primary drive
* was not found), so we had better have an extended partition
* or extra drives in the Master FDISK table.
*/
if ((extendedPart < 0) && (numExtraDrives == 0)) {
cmn_err(CE_NOTE, "!pcfs: no extended dos partition");
noLogicalDrive(ldrive);
return (EINVAL);
}
if (extendedPart >= 0) {
diskblk = xstartsect = LE_32(dosp[extendedPart].relsect);
xnumsect = LE_32(dosp[extendedPart].numsect);
do {
/*
* If the seek would not cause us to change
* position on the drive, then we're out of
* extended partitions to examine.
*/
if (diskblk == lastseek)
break;
logicalDriveCount += numDrives;
/*
* Seek the next extended partition, and find
* logical drives within it.
*/
brelse(*bp);
/*
* bread() block numbers are multiples of DEV_BSIZE
* but the device sector size (the unit of partitioning)
* might be larger than that; pcfs_get_device_info()
* has calculated the multiplicator for us.
*/
*bp = bread(dev,
pc_dbdaddr(fsp, diskblk), fsp->pcfs_secsize);
if ((*bp)->b_flags & B_ERROR) {
return (EIO);
}
lastseek = diskblk;
COPY_PTBL((*bp)->b_un.b_addr, dosp);
if (bpb_get_BPBSig((*bp)->b_un.b_addr) != MBB_MAGIC) {
cmn_err(CE_NOTE, "!pcfs: "
"extended partition table signature err, "
"device (%x.%x):%d, LBA %u",
getmajor(dev), getminor(dev), ldrive,
(uint_t)pc_dbdaddr(fsp, diskblk));
return (EINVAL);
}
/*
* Count up drives, and track where the next
* extended partition is in case we need it. We
* are expecting only one extended partition. If
* there is more than one we'll only go to the
* first one we see, but warn about ignoring.
*/
numDrives = 0;
for (i = 0; i < FD_NUMPART; i++) {
DTRACE_PROBE4(extendedpart,
struct pcfs *, fsp,
uint_t, (uint_t)dosp[i].systid,
uint_t, LE_32(dosp[i].relsect),
uint_t, LE_32(dosp[i].numsect));
if (isDosDrive(dosp[i].systid)) {
extndDrives[numDrives++] = i;
} else if (isDosExtended(dosp[i].systid)) {
if (diskblk != lastseek) {
/*
* Already found an extended
* partition in this table.
*/
cmn_err(CE_NOTE,
"!pcfs: ignoring unexpected"
" additional extended"
" partition");
} else {
diskblk = xstartsect +
LE_32(dosp[i].relsect);
}
}
}
} while (ldrive > logicalDriveCount + numDrives);
ASSERT(numDrives <= FD_NUMPART);
if (ldrive <= logicalDriveCount + numDrives) {
/*
* The number of logical drives we've found thus
* far is enough to get us to the one we were
* searching for.
*/
driveIndex = logicalDriveCount + numDrives - ldrive;
mediasize =
LE_32(dosp[extndDrives[driveIndex]].numsect);
startsec =
LE_32(dosp[extndDrives[driveIndex]].relsect) +
lastseek;
if (startsec > (xstartsect + xnumsect)) {
cmn_err(CE_NOTE, "!pcfs: extended partition "
"values bad");
return (EINVAL);
}
goto found;
} else {
/*
* We ran out of extended dos partition
* drives. The only hope now is to go
* back to extra drives defined in the master
* fdisk table. But we overwrote that table
* already, so we must load it in again.
*/
logicalDriveCount += numDrives;
brelse(*bp);
ASSERT(fsp->pcfs_dosstart == 0);
*bp = bread(dev, pc_dbdaddr(fsp, fsp->pcfs_dosstart),
fsp->pcfs_secsize);
if ((*bp)->b_flags & B_ERROR) {
return (EIO);
}
COPY_PTBL((*bp)->b_un.b_addr, dosp);
}
}
/*
* Still haven't found the drive, is it an extra
* drive defined in the main FDISK table?
*/
if (ldrive <= logicalDriveCount + numExtraDrives) {
driveIndex = logicalDriveCount + numExtraDrives - ldrive;
ASSERT(driveIndex < MIN(numExtraDrives, FD_NUMPART));
mediasize = LE_32(dosp[extraDrives[driveIndex]].numsect);
startsec = LE_32(dosp[extraDrives[driveIndex]].relsect);
goto found;
}
/*
* Still haven't found the drive, and there is
* nowhere else to look.
*/
noLogicalDrive(ldrive);
return (EINVAL);
found:
/*
* We need this value in units of sectorsize, because PCFS' internal
* offset calculations go haywire for > 512Byte sectors unless all
* pcfs_.*start values are in units of sectors.
* So, assign before the capacity check (that's done in DEV_BSIZE)
*/
fsp->pcfs_dosstart = startsec;
/*
* convert from device sectors to proper units:
* - starting sector: DEV_BSIZE (as argument to bread())
* - media size: Bytes
*/
startsec = pc_dbdaddr(fsp, startsec);
mediasize *= fsp->pcfs_secsize;
/*
* some additional validation / warnings in case the partition table
* and the actual media capacity are not in accordance ...
*/
if (fsp->pcfs_mediasize != 0) {
diskaddr_t startoff =
(diskaddr_t)startsec * (diskaddr_t)DEV_BSIZE;
if (startoff >= fsp->pcfs_mediasize ||
startoff + mediasize > fsp->pcfs_mediasize) {
cmn_err(CE_WARN,
"!pcfs: partition size (LBA start %u, %lld bytes, "
"device (%x.%x):%d) smaller than "
"mediasize (%lld bytes).\n"
"filesystem may be truncated, access errors "
"may result.\n",
(uint_t)startsec, (long long)mediasize,
getmajor(fsp->pcfs_xdev), getminor(fsp->pcfs_xdev),
fsp->pcfs_ldrive, (long long)fsp->pcfs_mediasize);
}
} else {
fsp->pcfs_mediasize = mediasize;
}
return (0);
}
static fattype_t
secondaryBPBChecks(struct pcfs *fsp, uchar_t *bpb, size_t secsize)
{
uint32_t ncl = fsp->pcfs_ncluster;
if (ncl <= 4096) {
if (bpb_get_FatSz16(bpb) == 0)
return (FAT_UNKNOWN);
if (bpb_get_FatSz16(bpb) * secsize < ncl * 2 &&
bpb_get_FatSz16(bpb) * secsize >= (3 * ncl / 2))
return (FAT12);
if (bcmp(bpb_FilSysType16(bpb), "FAT12", 5) == 0)
return (FAT12);
if (bcmp(bpb_FilSysType16(bpb), "FAT16", 5) == 0)
return (FAT16);
switch (bpb_get_Media(bpb)) {
case SS8SPT:
case DS8SPT:
case SS9SPT:
case DS9SPT:
case DS18SPT:
case DS9_15SPT:
/*
* Is this reliable - all floppies are FAT12 ?
*/
return (FAT12);
case MD_FIXED:
/*
* Is this reliable - disks are always FAT16 ?
*/
return (FAT16);
default:
break;
}
} else if (ncl <= 65536) {
if (bpb_get_FatSz16(bpb) == 0 && bpb_get_FatSz32(bpb) > 0)
return (FAT32);
if (VALID_BOOTSIG(bpb_get_BootSig32(bpb)))
return (FAT32);
if (VALID_FSTYPSTR32(bpb_FilSysType32(bpb)))
return (FAT32);
if (VALID_BOOTSIG(bpb_get_BootSig16(bpb)))
return (FAT16);
if (bpb_get_FatSz16(bpb) * secsize < ncl * 4)
return (FAT16);
}
/*
* We don't know
*/
return (FAT_UNKNOWN);
}
/*
* Check to see if the BPB we found is correct.
*
* This looks far more complicated that it needs to be for pure structural
* validation. The reason for this is that parseBPB() is also used for
* debugging purposes (mdb dcmd) and we therefore want a bitmap of which
* BPB fields (do not) have 'known good' values, even if we (do not) reject
* the BPB when attempting to mount the filesystem.
*
* Real-world usage of FAT shows there are a lot of corner-case situations
* and, following the specification strictly, invalid filesystems out there.
* Known are situations such as:
* - FAT12/FAT16 filesystems with garbage in either totsec16/32
* instead of the zero in one of the fields mandated by the spec
* - filesystems that claim to be larger than the partition they're in
* - filesystems without valid media descriptor
* - FAT32 filesystems with RootEntCnt != 0
* - FAT32 filesystems with less than 65526 clusters
* - FAT32 filesystems without valid FSI sector
* - FAT32 filesystems with FAT size in fatsec16 instead of fatsec32
*
* Such filesystems are accessible by PCFS - if it'd know to start with that
* the filesystem should be treated as a specific FAT type. Before S10, it
* relied on the PC/fdisk partition type for the purpose and almost completely
* ignored the BPB; now it ignores the partition type for anything else but
* logical drive enumeration, which can result in rejection of (invalid)
* FAT32 - if the partition ID says FAT32, but the filesystem, for example
* has less than 65526 clusters.
*
* Without a "force this fs as FAT{12,16,32}" tunable or mount option, it's
* not possible to allow all such mostly-compliant filesystems in unless one
* accepts false positives (definitely invalid filesystems that cause problems
* later). This at least allows to pinpoint why the mount failed.
*
* Due to the use of FAT on removeable media, all relaxations of the rules
* here need to be carefully evaluated wrt. to potential effects on PCFS
* resilience. A faulty/"mis-crafted" filesystem must not cause a panic, so
* beware.
*/
static int
parseBPB(struct pcfs *fsp, uchar_t *bpb, int *valid)
{
fattype_t type;
uint32_t ncl; /* number of clusters in file area */
uint32_t rec;
uint32_t reserved;
uint32_t fsisec, bkbootsec;
blkcnt_t totsec, totsec16, totsec32, datasec;
size_t fatsec, fatsec16, fatsec32, rdirsec;
size_t secsize;
len_t mediasize;
uint64_t validflags = 0;
if (VALID_BPBSIG(bpb_get_BPBSig(bpb)))
validflags |= BPB_BPBSIG_OK;
rec = bpb_get_RootEntCnt(bpb);
reserved = bpb_get_RsvdSecCnt(bpb);
fsisec = bpb_get_FSInfo32(bpb);
bkbootsec = bpb_get_BkBootSec32(bpb);
totsec16 = (blkcnt_t)bpb_get_TotSec16(bpb);
totsec32 = (blkcnt_t)bpb_get_TotSec32(bpb);
fatsec16 = bpb_get_FatSz16(bpb);
fatsec32 = bpb_get_FatSz32(bpb);
totsec = totsec16 ? totsec16 : totsec32;
fatsec = fatsec16 ? fatsec16 : fatsec32;
secsize = bpb_get_BytesPerSec(bpb);
if (!VALID_SECSIZE(secsize))
secsize = fsp->pcfs_secsize;
if (secsize != fsp->pcfs_secsize) {
PC_DPRINTF3(3, "!pcfs: parseBPB, device (%x.%x):%d:\n",
getmajor(fsp->pcfs_xdev),
getminor(fsp->pcfs_xdev), fsp->pcfs_ldrive);
PC_DPRINTF2(3, "!BPB secsize %d != "
"autodetected media block size %d\n",
(int)secsize, (int)fsp->pcfs_secsize);
if (fsp->pcfs_ldrive) {
/*
* We've already attempted to parse the partition
* table. If the block size used for that don't match
* the PCFS sector size, we're hosed one way or the
* other. Just try what happens.
*/
secsize = fsp->pcfs_secsize;
PC_DPRINTF1(3,
"!pcfs: Using autodetected secsize %d\n",
(int)secsize);
} else {
/*
* This allows mounting lofi images of PCFS partitions
* with sectorsize != DEV_BSIZE. We can't parse the
* partition table on whole-disk images unless the
* (undocumented) "secsize=..." mount option is used,
* but at least this allows us to mount if we have
* an image of a partition.
*/
PC_DPRINTF1(3,
"!pcfs: Using BPB secsize %d\n", (int)secsize);
}
}
if (fsp->pcfs_mediasize == 0) {
mediasize = (len_t)totsec * (len_t)secsize;
/*
* This is not an error because not all devices support the
* dkio(7i) mediasize queries, and/or not all devices are
* partitioned. If we have not been able to figure out the
* size of the underlaying medium, we have to trust the BPB.
*/
PC_DPRINTF4(3, "!pcfs: parseBPB: mediasize autodetect failed "
"on device (%x.%x):%d, trusting BPB totsec (%lld Bytes)\n",
getmajor(fsp->pcfs_xdev), getminor(fsp->pcfs_xdev),
fsp->pcfs_ldrive, (long long)fsp->pcfs_mediasize);
} else if ((len_t)totsec * (len_t)secsize > fsp->pcfs_mediasize) {
cmn_err(CE_WARN,
"!pcfs: autodetected mediasize (%lld Bytes) smaller than "
"FAT BPB mediasize (%lld Bytes).\n"
"truncated filesystem on device (%x.%x):%d, access errors "
"possible.\n",
(long long)fsp->pcfs_mediasize,
(long long)(totsec * (blkcnt_t)secsize),
getmajor(fsp->pcfs_xdev), getminor(fsp->pcfs_xdev),
fsp->pcfs_ldrive);
mediasize = fsp->pcfs_mediasize;
} else {
/*
* This is actually ok. A FAT needs not occupy the maximum
* space available in its partition, it can be shorter.
*/
mediasize = (len_t)totsec * (len_t)secsize;
}
/*
* Since we let just about anything pass through this function,
* fence against divide-by-zero here.
*/
if (secsize)
rdirsec = roundup(rec * 32, secsize) / secsize;
else
rdirsec = 0;
/*
* This assignment is necessary before pc_dbdaddr() can first be
* used. Must initialize the value here.
*/
fsp->pcfs_secsize = secsize;
fsp->pcfs_sdshift = ddi_ffs(secsize / DEV_BSIZE) - 1;
fsp->pcfs_mediasize = mediasize;
fsp->pcfs_spcl = bpb_get_SecPerClus(bpb);
fsp->pcfs_numfat = bpb_get_NumFATs(bpb);
fsp->pcfs_mediadesc = bpb_get_Media(bpb);
fsp->pcfs_clsize = secsize * fsp->pcfs_spcl;
fsp->pcfs_rdirsec = rdirsec;
/*
* Remember: All PCFS offset calculations in sectors. Before I/O
* is done, convert to DEV_BSIZE units via pc_dbdaddr(). This is
* necessary so that media with > 512Byte sector sizes work correctly.
*/
fsp->pcfs_fatstart = fsp->pcfs_dosstart + reserved;
fsp->pcfs_rdirstart = fsp->pcfs_fatstart + fsp->pcfs_numfat * fatsec;
fsp->pcfs_datastart = fsp->pcfs_rdirstart + rdirsec;
datasec = totsec -
(blkcnt_t)fatsec * fsp->pcfs_numfat -
(blkcnt_t)rdirsec -
(blkcnt_t)reserved;
DTRACE_PROBE4(fatgeometry,
blkcnt_t, totsec, size_t, fatsec,
size_t, rdirsec, blkcnt_t, datasec);
/*
* 'totsec' is taken directly from the BPB and guaranteed to fit
* into a 32bit unsigned integer. The calculation of 'datasec',
* on the other hand, could underflow for incorrect values in
* rdirsec/reserved/fatsec. Check for that.
* We also check that the BPB conforms to the FAT specification's
* requirement that either of the 16/32bit total sector counts
* must be zero.
*/
if (totsec != 0 &&
(totsec16 == totsec32 || totsec16 == 0 || totsec32 == 0) &&
datasec < totsec && datasec <= UINT32_MAX)
validflags |= BPB_TOTSEC_OK;
if ((len_t)totsec * (len_t)secsize <= mediasize)
validflags |= BPB_MEDIASZ_OK;
if (VALID_SECSIZE(secsize))
validflags |= BPB_SECSIZE_OK;
if (VALID_SPCL(fsp->pcfs_spcl))
validflags |= BPB_SECPERCLUS_OK;
if (VALID_CLSIZE(fsp->pcfs_clsize))
validflags |= BPB_CLSIZE_OK;
if (VALID_NUMFATS(fsp->pcfs_numfat))
validflags |= BPB_NUMFAT_OK;
if (VALID_RSVDSEC(reserved) && reserved < totsec)
validflags |= BPB_RSVDSECCNT_OK;
if (VALID_MEDIA(fsp->pcfs_mediadesc))
validflags |= BPB_MEDIADESC_OK;
if (VALID_BOOTSIG(bpb_get_BootSig16(bpb)))
validflags |= BPB_BOOTSIG16_OK;
if (VALID_BOOTSIG(bpb_get_BootSig32(bpb)))
validflags |= BPB_BOOTSIG32_OK;
if (VALID_FSTYPSTR16(bpb_FilSysType16(bpb)))
validflags |= BPB_FSTYPSTR16_OK;
if (VALID_FSTYPSTR32(bpb_FilSysType32(bpb)))
validflags |= BPB_FSTYPSTR32_OK;
if (VALID_OEMNAME(bpb_OEMName(bpb)))
validflags |= BPB_OEMNAME_OK;
if (bkbootsec > 0 && bkbootsec <= reserved && fsisec != bkbootsec)
validflags |= BPB_BKBOOTSEC_OK;
if (fsisec > 0 && fsisec <= reserved)
validflags |= BPB_FSISEC_OK;
if (VALID_JMPBOOT(bpb_jmpBoot(bpb)))
validflags |= BPB_JMPBOOT_OK;
if (VALID_FSVER32(bpb_get_FSVer32(bpb)))
validflags |= BPB_FSVER_OK;
if (VALID_VOLLAB(bpb_VolLab16(bpb)))
validflags |= BPB_VOLLAB16_OK;
if (VALID_VOLLAB(bpb_VolLab32(bpb)))
validflags |= BPB_VOLLAB32_OK;
if (VALID_EXTFLAGS(bpb_get_ExtFlags32(bpb)))
validflags |= BPB_EXTFLAGS_OK;
/*
* Try to determine which FAT format to use.
*
* Calculate the number of clusters in order to determine
* the type of FAT we are looking at. This is the only
* recommended way of determining FAT type, though there
* are other hints in the data, this is the best way.
*
* Since we let just about "anything" pass through this function
* without early exits, fence against divide-by-zero here.
*
* datasec was already validated against UINT32_MAX so we know
* the result will not overflow the 32bit calculation.
*/
if (fsp->pcfs_spcl)
ncl = (uint32_t)datasec / fsp->pcfs_spcl;
else
ncl = 0;
fsp->pcfs_ncluster = ncl;
/*
* From the Microsoft FAT specification:
* In the following example, when it says <, it does not mean <=.
* Note also that the numbers are correct. The first number for
* FAT12 is 4085; the second number for FAT16 is 65525. These numbers
* and the '<' signs are not wrong.
*
* We "specialdetect" the corner cases, and use at least one "extra"
* criterion to decide whether it's FAT16 or FAT32 if the cluster
* count is dangerously close to the boundaries.
*/
if (ncl <= PCF_FIRSTCLUSTER) {
type = FAT_UNKNOWN;
} else if (ncl < 4085) {
type = FAT12;
} else if (ncl <= 4096) {
type = FAT_QUESTIONABLE;
} else if (ncl < 65525) {
type = FAT16;
} else if (ncl <= 65536) {
type = FAT_QUESTIONABLE;
} else if (ncl < PCF_LASTCLUSTER32) {
type = FAT32;
} else {
type = FAT_UNKNOWN;
}
DTRACE_PROBE4(parseBPB__initial,
struct pcfs *, fsp, unsigned char *, bpb,
int, validflags, fattype_t, type);
recheck:
fsp->pcfs_fatsec = fatsec;
/* Do some final sanity checks for each specific type of FAT */
switch (type) {
case FAT12:
if (rec != 0)
validflags |= BPB_ROOTENTCNT_OK;
if ((blkcnt_t)bpb_get_TotSec16(bpb) == totsec ||
bpb_get_TotSec16(bpb) == 0)
validflags |= BPB_TOTSEC16_OK;
if ((blkcnt_t)bpb_get_TotSec32(bpb) == totsec ||
bpb_get_TotSec32(bpb) == 0)
validflags |= BPB_TOTSEC32_OK;
if (bpb_get_FatSz16(bpb) == fatsec)
validflags |= BPB_FATSZ16_OK;
if (fatsec * secsize >= (ncl + PCF_FIRSTCLUSTER)
* 3 / 2)
validflags |= BPB_FATSZ_OK;
if (ncl < 4085)
validflags |= BPB_NCLUSTERS_OK;
fsp->pcfs_lastclmark = (PCF_LASTCLUSTER & 0xfff);
fsp->pcfs_rootblksize =
fsp->pcfs_rdirsec * secsize;
fsp->pcfs_fsistart = 0;
if ((validflags & FAT12_VALIDMSK) != FAT12_VALIDMSK)
type = FAT_UNKNOWN;
break;
case FAT16:
if (rec != 0)
validflags |= BPB_ROOTENTCNT_OK;
if ((blkcnt_t)bpb_get_TotSec16(bpb) == totsec ||
bpb_get_TotSec16(bpb) == 0)
validflags |= BPB_TOTSEC16_OK;
if ((blkcnt_t)bpb_get_TotSec32(bpb) == totsec ||
bpb_get_TotSec32(bpb) == 0)
validflags |= BPB_TOTSEC32_OK;
if (bpb_get_FatSz16(bpb) == fatsec)
validflags |= BPB_FATSZ16_OK;
if (fatsec * secsize >= (ncl + PCF_FIRSTCLUSTER) * 2)
validflags |= BPB_FATSZ_OK;
if (ncl >= 4085 && ncl < 65525)
validflags |= BPB_NCLUSTERS_OK;
fsp->pcfs_lastclmark = PCF_LASTCLUSTER;
fsp->pcfs_rootblksize =
fsp->pcfs_rdirsec * secsize;
fsp->pcfs_fsistart = 0;
if ((validflags & FAT16_VALIDMSK) != FAT16_VALIDMSK)
type = FAT_UNKNOWN;
break;
case FAT32:
if (rec == 0)
validflags |= BPB_ROOTENTCNT_OK;
if (bpb_get_TotSec16(bpb) == 0)
validflags |= BPB_TOTSEC16_OK;
if ((blkcnt_t)bpb_get_TotSec32(bpb) == totsec)
validflags |= BPB_TOTSEC32_OK;
if (bpb_get_FatSz16(bpb) == 0)
validflags |= BPB_FATSZ16_OK;
if (bpb_get_FatSz32(bpb) == fatsec)
validflags |= BPB_FATSZ32_OK;
if (fatsec * secsize >= (ncl + PCF_FIRSTCLUSTER) * 4)
validflags |= BPB_FATSZ_OK;
if (ncl >= 65525 && ncl < PCF_LASTCLUSTER32)
validflags |= BPB_NCLUSTERS_OK;
fsp->pcfs_lastclmark = PCF_LASTCLUSTER32;
fsp->pcfs_rootblksize = fsp->pcfs_clsize;
fsp->pcfs_fsistart = fsp->pcfs_dosstart + fsisec;
if (validflags & BPB_FSISEC_OK)
fsp->pcfs_flags |= PCFS_FSINFO_OK;
fsp->pcfs_rootclnum = bpb_get_RootClus32(bpb);
if (pc_validcl(fsp, fsp->pcfs_rootclnum))
validflags |= BPB_ROOTCLUSTER_OK;
/*
* Current PCFS code only works if 'pcfs_rdirstart'
* contains the root cluster number on FAT32.
* That's a mis-use and would better be changed.
*/
fsp->pcfs_rdirstart = (daddr_t)fsp->pcfs_rootclnum;
if ((validflags & FAT32_VALIDMSK) != FAT32_VALIDMSK)
type = FAT_UNKNOWN;
break;
case FAT_QUESTIONABLE:
type = secondaryBPBChecks(fsp, bpb, secsize);
goto recheck;
default:
ASSERT(type == FAT_UNKNOWN);
break;
}
ASSERT(type != FAT_QUESTIONABLE);
fsp->pcfs_fattype = type;
if (valid)
*valid = validflags;
DTRACE_PROBE4(parseBPB__final,
struct pcfs *, fsp, unsigned char *, bpb,
int, validflags, fattype_t, type);
if (type != FAT_UNKNOWN) {
ASSERT((secsize & (DEV_BSIZE - 1)) == 0);
ASSERT(ISP2(secsize / DEV_BSIZE));
return (1);
}
return (0);
}
/*
* Detect the device's native block size (sector size).
*
* Test whether the device is:
* - a floppy device from a known controller type via DKIOCINFO
* - a real floppy using the fd(7d) driver and capable of fdio(7I) ioctls
* - a USB floppy drive (identified by drive geometry)
*
* Detecting a floppy will make PCFS metadata updates on such media synchronous,
* to minimize risks due to slow I/O and user hotplugging / device ejection.
*
* This might be a bit wasteful on kernel stack space; if anyone's
* bothered by this, kmem_alloc/kmem_free the ioctl arguments...
*/
static void
pcfs_device_getinfo(struct pcfs *fsp)
{
dev_t rdev = fsp->pcfs_xdev;
int error;
union {
struct dk_minfo mi;
struct dk_cinfo ci;
struct dk_geom gi;
struct fd_char fc;
} arg; /* save stackspace ... */
intptr_t argp = (intptr_t)&arg;
ldi_handle_t lh;
ldi_ident_t li;
int isfloppy, isremoveable, ishotpluggable;
cred_t *cr = CRED();
if (ldi_ident_from_dev(rdev, &li))
goto out;
error = ldi_open_by_dev(&rdev, OTYP_CHR, FREAD, cr, &lh, li);
ldi_ident_release(li);
if (error)
goto out;
/*
* Not sure if this could possibly happen. It'd be a bit like
* VOP_OPEN() changing the passed-in vnode ptr. We're just not
* expecting it, needs some thought if triggered ...
*/
ASSERT(fsp->pcfs_xdev == rdev);
/*
* Check for removeable/hotpluggable media.
*/
if (ldi_ioctl(lh, DKIOCREMOVABLE,
(intptr_t)&isremoveable, FKIOCTL, cr, NULL)) {
isremoveable = 0;
}
if (ldi_ioctl(lh, DKIOCHOTPLUGGABLE,
(intptr_t)&ishotpluggable, FKIOCTL, cr, NULL)) {
ishotpluggable = 0;
}
/*
* Make sure we don't use "half-initialized" values if the ioctls fail.
*/
if (ldi_ioctl(lh, DKIOCGMEDIAINFO, argp, FKIOCTL, cr, NULL)) {
bzero(&arg, sizeof (arg));
fsp->pcfs_mediasize = 0;
} else {
fsp->pcfs_mediasize =
(len_t)arg.mi.dki_lbsize *
(len_t)arg.mi.dki_capacity;
}
if (VALID_SECSIZE(arg.mi.dki_lbsize)) {
if (fsp->pcfs_secsize == 0) {
fsp->pcfs_secsize = arg.mi.dki_lbsize;
fsp->pcfs_sdshift =
ddi_ffs(arg.mi.dki_lbsize / DEV_BSIZE) - 1;
} else {
PC_DPRINTF4(1, "!pcfs: autodetected media block size "
"%d, device (%x.%x), different from user-provided "
"%d. User override - ignoring autodetect result.\n",
arg.mi.dki_lbsize,
getmajor(fsp->pcfs_xdev), getminor(fsp->pcfs_xdev),
fsp->pcfs_secsize);
}
} else if (arg.mi.dki_lbsize) {
PC_DPRINTF3(1, "!pcfs: autodetected media block size "
"%d, device (%x.%x), invalid (not 512, 1024, 2048, 4096). "
"Ignoring autodetect result.\n",
arg.mi.dki_lbsize,
getmajor(fsp->pcfs_xdev), getminor(fsp->pcfs_xdev));
}
/*
* We treat the following media types as a floppy by default.
*/
isfloppy =
(arg.mi.dki_media_type == DK_FLOPPY ||
arg.mi.dki_media_type == DK_ZIP ||
arg.mi.dki_media_type == DK_JAZ);
/*
* if this device understands fdio(7I) requests it's
* obviously a floppy drive.
*/
if (!isfloppy &&
!ldi_ioctl(lh, FDIOGCHAR, argp, FKIOCTL, cr, NULL))
isfloppy = 1;
/*
* some devices we like to treat as floppies, but they don't
* understand fdio(7I) requests.
*/
if (!isfloppy &&
!ldi_ioctl(lh, DKIOCINFO, argp, FKIOCTL, cr, NULL) &&
(arg.ci.dki_ctype == DKC_WDC2880 ||
arg.ci.dki_ctype == DKC_NCRFLOPPY ||
arg.ci.dki_ctype == DKC_SMSFLOPPY ||
arg.ci.dki_ctype == DKC_INTEL82077))
isfloppy = 1;
/*
* This is the "final fallback" test - media with
* 2 heads and 80 cylinders are assumed to be floppies.
* This is normally true for USB floppy drives ...
*/
if (!isfloppy &&
!ldi_ioctl(lh, DKIOCGGEOM, argp, FKIOCTL, cr, NULL) &&
(arg.gi.dkg_ncyl == 80 && arg.gi.dkg_nhead == 2))
isfloppy = 1;
/*
* This is similar to the "old" PCFS code that sets this flag
* just based on the media descriptor being 0xf8 (MD_FIXED).
* Should be re-worked. We really need some specialcasing for
* removeable media.
*/
if (!isfloppy) {
fsp->pcfs_flags |= PCFS_NOCHK;
}
/*
* We automatically disable access time updates if the medium is
* removeable and/or hotpluggable, and the admin did not explicitly
* request access time updates (via the "atime" mount option).
* The majority of flash-based media should fit this category.
* Minimizing write access extends the lifetime of your memory stick !
*/
if (!vfs_optionisset(fsp->pcfs_vfs, MNTOPT_ATIME, NULL) &&
(isremoveable || ishotpluggable | isfloppy)) {
fsp->pcfs_flags |= PCFS_NOATIME;
}
(void) ldi_close(lh, FREAD, cr);
out:
if (fsp->pcfs_secsize == 0) {
PC_DPRINTF3(1, "!pcfs: media block size autodetection "
"device (%x.%x) failed, no user-provided fallback. "
"Using %d bytes.\n",
getmajor(fsp->pcfs_xdev), getminor(fsp->pcfs_xdev),
DEV_BSIZE);
fsp->pcfs_secsize = DEV_BSIZE;
fsp->pcfs_sdshift = 0;
}
ASSERT(fsp->pcfs_secsize % DEV_BSIZE == 0);
ASSERT(VALID_SECSIZE(fsp->pcfs_secsize));
}
/*
* Get the FAT type for the DOS medium.
*
* -------------------------
* According to Microsoft:
* The FAT type one of FAT12, FAT16, or FAT32 is determined by the
* count of clusters on the volume and nothing else.
* -------------------------
*
*/
static int
pc_getfattype(struct pcfs *fsp)
{
int error = 0;
buf_t *bp = NULL;
struct vnode *devvp = fsp->pcfs_devvp;
dev_t dev = devvp->v_rdev;
/*
* Detect the native block size of the medium, and attempt to
* detect whether the medium is removeable.
* We do treat removable media (floppies, USB and FireWire disks)
* differently wrt. to the frequency and synchronicity of FAT updates.
* We need to know the media block size in order to be able to
* parse the partition table.
*/
pcfs_device_getinfo(fsp);
/*
* Unpartitioned media (floppies and some removeable devices)
* don't have a partition table, the FAT BPB is at disk block 0.
* Start out by reading block 0.
*/
fsp->pcfs_dosstart = 0;
bp = bread(dev, pc_dbdaddr(fsp, fsp->pcfs_dosstart), fsp->pcfs_secsize);
if (error = geterror(bp))
goto out;
/*
* If a logical drive number is requested, parse the partition table
* and attempt to locate it. Otherwise, proceed immediately to the
* BPB check. findTheDrive(), if successful, returns the disk block
* number where the requested partition starts in "startsec".
*/
if (fsp->pcfs_ldrive != 0) {
PC_DPRINTF3(5, "!pcfs: pc_getfattype: using FDISK table on "
"device (%x,%x):%d to find BPB\n",
getmajor(dev), getminor(dev), fsp->pcfs_ldrive);
if (error = findTheDrive(fsp, &bp))
goto out;
ASSERT(fsp->pcfs_dosstart != 0);
brelse(bp);
bp = bread(dev, pc_dbdaddr(fsp, fsp->pcfs_dosstart),
fsp->pcfs_secsize);
if (error = geterror(bp))
goto out;
}
/*
* Validate the BPB and fill in the instance structure.
*/
if (!parseBPB(fsp, (uchar_t *)bp->b_un.b_addr, NULL)) {
PC_DPRINTF4(1, "!pcfs: pc_getfattype: No FAT BPB on "
"device (%x.%x):%d, disk LBA %u\n",
getmajor(dev), getminor(dev), fsp->pcfs_ldrive,
(uint_t)pc_dbdaddr(fsp, fsp->pcfs_dosstart));
error = EINVAL;
goto out;
}
ASSERT(fsp->pcfs_fattype != FAT_UNKNOWN);
out:
/*
* Release the buffer used
*/
if (bp != NULL)
brelse(bp);
return (error);
}
/*
* Get the file allocation table.
* If there is an old FAT, invalidate it.
*/
int
pc_getfat(struct pcfs *fsp)
{
struct buf *bp = NULL;
uchar_t *fatp = NULL;
uchar_t *fat_changemap = NULL;
int error;
int fat_changemapsize;
int flags = 0;
int nfat;
int altfat_mustmatch = 0;
int fatsize = fsp->pcfs_fatsec * fsp->pcfs_secsize;
if (fsp->pcfs_fatp) {
/*
* There is a FAT in core.
* If there are open file pcnodes or we have modified it or
* it hasn't timed out yet use the in core FAT.
* Otherwise invalidate it and get a new one
*/
#ifdef notdef
if (fsp->pcfs_frefs ||
(fsp->pcfs_flags & PCFS_FATMOD) ||
(gethrestime_sec() < fsp->pcfs_fattime)) {
return (0);
} else {
mutex_enter(&pcfslock);
pc_invalfat(fsp);
mutex_exit(&pcfslock);
}
#endif /* notdef */
return (0);
}
/*
* Get FAT and check it for validity
*/
fatp = kmem_alloc(fatsize, KM_SLEEP);
error = pc_readfat(fsp, fatp);
if (error) {
flags = B_ERROR;
goto out;
}
fat_changemapsize = (fatsize / fsp->pcfs_clsize) + 1;
fat_changemap = kmem_zalloc(fat_changemapsize, KM_SLEEP);
fsp->pcfs_fatp = fatp;
fsp->pcfs_fat_changemapsize = fat_changemapsize;
fsp->pcfs_fat_changemap = fat_changemap;
/*
* The only definite signature check is that the
* media descriptor byte should match the first byte
* of the FAT block.
*/
if (fatp[0] != fsp->pcfs_mediadesc) {
cmn_err(CE_NOTE, "!pcfs: FAT signature mismatch, "
"media descriptor %x, FAT[0] lowbyte %x\n",
(uint32_t)fsp->pcfs_mediadesc, (uint32_t)fatp[0]);
cmn_err(CE_NOTE, "!pcfs: Enforcing alternate FAT validation\n");
altfat_mustmatch = 1;
}
/*
* Get alternate FATs and check for consistency
* This is an inlined version of pc_readfat().
* Since we're only comparing FAT and alternate FAT,
* there's no reason to let pc_readfat() copy data out
* of the buf. Instead, compare in-situ, one cluster
* at a time.
*/
for (nfat = 1; nfat < fsp->pcfs_numfat; nfat++) {
size_t startsec;
size_t off;
startsec = pc_dbdaddr(fsp,
fsp->pcfs_fatstart + nfat * fsp->pcfs_fatsec);
for (off = 0; off < fatsize; off += fsp->pcfs_clsize) {
daddr_t fatblk = startsec + pc_dbdaddr(fsp,
pc_cltodb(fsp, pc_lblkno(fsp, off)));
bp = bread(fsp->pcfs_xdev, fatblk,
MIN(fsp->pcfs_clsize, fatsize - off));
if (bp->b_flags & (B_ERROR | B_STALE)) {
cmn_err(CE_NOTE,
"!pcfs: alternate FAT #%d (start LBA %p)"
" read error at offset %ld on device"
" (%x.%x):%d",
nfat, (void *)(uintptr_t)startsec, off,
getmajor(fsp->pcfs_xdev),
getminor(fsp->pcfs_xdev),
fsp->pcfs_ldrive);
flags = B_ERROR;
error = EIO;
goto out;
}
bp->b_flags |= B_STALE | B_AGE;
if (bcmp(bp->b_un.b_addr, fatp + off,
MIN(fsp->pcfs_clsize, fatsize - off))) {
cmn_err(CE_NOTE,
"!pcfs: alternate FAT #%d (start LBA %p)"
" corrupted at offset %ld on device"
" (%x.%x):%d",
nfat, (void *)(uintptr_t)startsec, off,
getmajor(fsp->pcfs_xdev),
getminor(fsp->pcfs_xdev),
fsp->pcfs_ldrive);
if (altfat_mustmatch) {
flags = B_ERROR;
error = EIO;
goto out;
}
}
brelse(bp);
bp = NULL; /* prevent double release */
}
}
fsp->pcfs_fattime = gethrestime_sec() + PCFS_DISKTIMEOUT;
fsp->pcfs_fatjustread = 1;
/*
* Retrieve FAT32 fsinfo sector.
* A failure to read this is not fatal to accessing the volume.
* It simply means operations that count or search free blocks
* will have to do a full FAT walk, vs. a possibly quicker lookup
* of the summary information.
* Hence, we log a message but return success overall after this point.
*/
if (IS_FAT32(fsp) && (fsp->pcfs_flags & PCFS_FSINFO_OK)) {
struct fat_od_fsi *fsinfo_disk;
bp = bread(fsp->pcfs_xdev,
pc_dbdaddr(fsp, fsp->pcfs_fsistart), fsp->pcfs_secsize);
fsinfo_disk = (struct fat_od_fsi *)bp->b_un.b_addr;
if (bp->b_flags & (B_ERROR | B_STALE) ||
!FSISIG_OK(fsinfo_disk)) {
cmn_err(CE_NOTE,
"!pcfs: error reading fat32 fsinfo from "
"device (%x.%x):%d, block %lld",
getmajor(fsp->pcfs_xdev), getminor(fsp->pcfs_xdev),
fsp->pcfs_ldrive,
(long long)pc_dbdaddr(fsp, fsp->pcfs_fsistart));
fsp->pcfs_flags &= ~PCFS_FSINFO_OK;
fsp->pcfs_fsinfo.fs_free_clusters = FSINFO_UNKNOWN;
fsp->pcfs_fsinfo.fs_next_free = FSINFO_UNKNOWN;
} else {
bp->b_flags |= B_STALE | B_AGE;
fsinfo_disk = (fat_od_fsi_t *)(bp->b_un.b_addr);
fsp->pcfs_fsinfo.fs_free_clusters =
LE_32(fsinfo_disk->fsi_incore.fs_free_clusters);
fsp->pcfs_fsinfo.fs_next_free =
LE_32(fsinfo_disk->fsi_incore.fs_next_free);
}
brelse(bp);
bp = NULL;
}
if (pc_validcl(fsp, (pc_cluster32_t)fsp->pcfs_fsinfo.fs_next_free))
fsp->pcfs_nxfrecls = fsp->pcfs_fsinfo.fs_next_free;
else
fsp->pcfs_nxfrecls = PCF_FIRSTCLUSTER;
return (0);
out:
cmn_err(CE_NOTE, "!pcfs: illegal disk format");
if (bp)
brelse(bp);
if (fatp)
kmem_free(fatp, fatsize);
if (fat_changemap)
kmem_free(fat_changemap, fat_changemapsize);
if (flags) {
pc_mark_irrecov(fsp);
}
return (error);
}