/*
* 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.
*/
#ifndef _SYS_FS_PC_FS_H
#define _SYS_FS_PC_FS_H
#include <sys/thread.h>
#include <sys/ksynch.h>
#include <sys/sysmacros.h>
#include <sys/byteorder.h>
#ifdef __cplusplus
extern "C" {
#endif
typedef uint16_t pc_cluster16_t;
typedef uint32_t pc_cluster32_t;
/*
* PC (MSDOS) compatible virtual file system.
*
* A main goal of the implementation was to maintain statelessness
* except while files are open. Thus mounting and unmounting merely
* declared the file system name. The user may change disks at almost
* any time without concern (just like the PC). It is assumed that when
* files are open for writing the disk access light will be on, as a
* warning not to change disks. The implementation must, however, detect
* disk change and recover gracefully. It does this by comparing the
* in core entry for a directory to the on disk entry whenever a directory
* is searched. If a discrepancy is found active directories become root and
* active files are marked invalid.
*
* There are only two type of nodes on the PC file system; files and
* directories. These are represented by two separate vnode op vectors,
* and they are kept in two separate tables. Files are known by the
* disk block number and block (cluster) offset of the files directory
* entry. Directories are known by the starting cluster number.
*
* The file system is locked for during each user operation. This is
* done to simplify disk verification error conditions.
*
* Notes on FAT32 support
* ----------------------
* The basic difference between FAT32 and FAT16 is that cluster numbers are now
* 32-bit instead of 16-bit. The FAT is thus an array of 32-bit cluster numbers,
* and because of this the cluster size can be much smaller on a large disk
* (4k, say, on a 1 Gig drive instead of 16k). Unfortunately, the FAT is not
* the only place cluster numbers are stored - the starting cluster is stored
* in the directory entry for a file, and of course it's only 16-bit. Luckily,
* there's a 16-bit OS/2 Extended Attribute field that is now used to store the
* upper 16-bits of the starting cluster number.
*
* Most of the FAT32 changes to pcfs are under 'if it's FAT32' to minimize the
* effect on non-FAT32 filesystems (and still share the code), except for the
* starting cluster changes. It seemed easier to make common functions to
* handle that.
*
* Other changes:
*
* 1. FAT32 partitions are indicated by partition types 0xB and 0xC.
* 2. The boot sector is now 2 sectors, to make room for FAT32 extensions.
* 3. The root directory is no longer stored in a fixed location. Its'
* starting cluster is stored in the extended boot sector.
* 4. "Summary information" is now stored and we need to (at least) maintain
* the number of free clusters or scandisk will be upset. Though the
* sector this info is in is pointed to by the extensions in the boot
* sector, the magic offset of this information is just that so
* far - magic. 0x1e0.
* 5. FAT32 can use the alternate FAT. But we don't.
*
* FAT32 also exposed a latent bug: we bread() each copy of the FAT in one
* big chunk. This is not good on a large FAT32 drive, such as a 1 Gig
* Jaz drive that has 4k clusters, since the FAT becomes 1 Meg in size and
* bread blocks forever. So now we read the FAT in chunks.
*/
/*
* The FAT bootsector uses little-endian multibyte values not aligned at
* a 'native' wordsize. Instead of defining a strange data structure and
* odd accessor methods for some members while using standard C accesses
* for others, we don't bother and just define the structure offsets, and
* a common set of misaligned-littleendian accessor macros.
*
* The "bootsec" and "fat32_bootsec" structures are only provided for
* compatibility with old code including <sys/fs/pc_fs.h> but not used
* by the PCFS kernel driver anymore.
*/
struct bootsec {
uchar_t instr[3];
uchar_t version[8];
uchar_t bps[2]; /* bytes per sector */
uchar_t spcl; /* sectors per allocation unit */
uchar_t res_sec[2]; /* reserved sectors, starting at 0 */
uchar_t nfat; /* number of FATs */
uchar_t rdirents[2]; /* number of root directory entries */
uchar_t numsect[2]; /* old total sectors in logical image */
uchar_t mediadesriptor; /* media descriptor byte */
ushort_t fatsec; /* number of sectors per FAT */
ushort_t spt; /* sectors per track */
ushort_t nhead; /* number of heads */
uint_t hiddensec; /* number of hidden sectors */
uint_t totalsec; /* total sectors in logical image */
};
/*
* FAT32 volumes have a bigger boot sector. They include the normal
* boot sector.
*/
struct fat32_bootsec {
struct bootsec f_bs;
uint32_t f_fatlength; /* size of FAT */
uint16_t f_flags;
uint8_t f_major; /* major filesystem version #? */
uint8_t f_minor; /* minor filesystem version #? */
uint32_t f_rootcluster; /* first cluster in root directory */
uint16_t f_infosector; /* where summary info is */
uint16_t f_backupboot; /* backup boot sector */
uint16_t f_reserved2[6];
};
#define OFF_JMPBOOT 0
#define OFF_OEMNAME 3
#define OFF_BYTESPERSEC 11
#define OFF_SECPERCLUS 13
#define OFF_RSVDSECCNT 14
#define OFF_NUMFATS 16
#define OFF_ROOTENTCNT 17
#define OFF_TOTSEC16 19
#define OFF_MEDIA 21
#define OFF_FATSZ16 22
#define OFF_SECPERTRK 24
#define OFF_NUMHEADS 26
#define OFF_HIDDSEC 28
#define OFF_TOTSEC32 32
#define OFF_BPBSIG 510
#define OFF_DRVNUM16 36
#define OFF_BOOTSIG16 38
#define OFF_VOLID16 39
#define OFF_VOLLAB16 43
#define OFF_FILSYSTYP16 54
#define OFF_FATSZ32 36
#define OFF_EXTFLAGS32 40
#define OFF_FSVER32 42
#define OFF_ROOTCLUS32 44
#define OFF_FSINFO32 48
#define OFF_BKBOOTSEC32 50
#define OFF_DRVNUM32 64
#define OFF_BOOTSIG32 66
#define OFF_VOLID32 67
#define OFF_VOLLAB32 71
#define OFF_FILSYSTYP32 82
#define LE_16_NA(addr) \
(((uint16_t)*((uint8_t *)(addr))) + \
((uint16_t)*((uint8_t *)(addr) + 1) << 8))
#define LE_32_NA(addr) \
(((uint32_t)*((uint8_t *)(addr))) + \
((uint32_t)*((uint8_t *)(addr) + 1) << 8) + \
((uint32_t)*((uint8_t *)(addr) + 2) << 16) + \
((uint32_t)*((uint8_t *)(addr) + 3) << 24))
/*
* Generic FAT BPB fields
*/
#define bpb_jmpBoot(bpb) ((unsigned char *)(bpb))
#define bpb_OEMName(bpb) ((char *)(bpb) + OFF_OEMNAME)
#define bpb_get_BytesPerSec(bpb) LE_16_NA((bpb) + OFF_BYTESPERSEC)
#define bpb_get_SecPerClus(bpb) (((uint8_t *)(bpb))[OFF_SECPERCLUS])
#define bpb_get_RsvdSecCnt(bpb) LE_16_NA((bpb) + OFF_RSVDSECCNT)
#define bpb_get_NumFATs(bpb) (((uint8_t *)(bpb))[OFF_NUMFATS])
#define bpb_get_RootEntCnt(bpb) LE_16_NA((bpb) + OFF_ROOTENTCNT)
#define bpb_get_TotSec16(bpb) LE_16_NA((bpb) + OFF_TOTSEC16)
#define bpb_get_Media(bpb) (((uint8_t *)(bpb))[OFF_MEDIA])
#define bpb_get_FatSz16(bpb) LE_16_NA((bpb) + OFF_FATSZ16)
#define bpb_get_SecPerTrk(bpb) LE_16_NA((bpb) + OFF_SECPERTRK)
#define bpb_get_NumHeads(bpb) LE_16_NA((bpb) + OFF_NUMHEADS)
#define bpb_get_HiddSec(bpb) LE_32_NA((bpb) + OFF_HIDDSEC)
#define bpb_get_TotSec32(bpb) LE_32_NA((bpb) + OFF_TOTSEC32)
#define bpb_get_BPBSig(bpb) LE_16_NA((bpb) + OFF_BPBSIG)
/*
* FAT12/16 extended BPB fields
*/
#define bpb_get_DrvNum16(bpb) (((uint8_t *)(bpb))[OFF_DRVNUM16])
#define bpb_get_BootSig16(bpb) (((uint8_t *)(bpb))[OFF_BOOTSIG16])
#define bpb_VolLab16(bpb) ((char *)(bpb) + OFF_VOLLAB16)
#define bpb_FilSysType16(bpb) ((char *)(bpb) + OFF_FILSYSTYP16)
#define bpb_get_VolID16(bpb) LE_32_NA((bpb) + OFF_VOLID16)
/*
* FAT32 extended BPB fields
*/
#define bpb_get_FatSz32(bpb) LE_32_NA((bpb) + OFF_FATSZ32)
#define bpb_get_ExtFlags32(bpb) LE_16_NA((bpb) + OFF_EXTFLAGS32)
#define bpb_get_FSVer32(bpb) LE_16_NA((bpb) + OFF_FSVER32)
#define bpb_get_RootClus32(bpb) LE_32_NA((bpb) + OFF_ROOTCLUS32)
#define bpb_get_FSInfo32(bpb) LE_16_NA((bpb) + OFF_FSINFO32)
#define bpb_get_BkBootSec32(bpb) LE_16_NA((bpb) + OFF_BKBOOTSEC32)
#define bpb_get_DrvNum32(bpb) (((uint8_t *)(bpb))[OFF_DRVNUM32])
#define bpb_get_BootSig32(bpb) (((uint8_t *)(bpb))[OFF_BOOTSIG32])
#define bpb_get_VolID32(bpb) LE_32_NA((bpb) + OFF_VOLID32)
#define bpb_VolLab32(bpb) ((char *)(bpb) + OFF_VOLLAB32)
#define bpb_FilSysType32(bpb) ((char *)(bpb) + OFF_FILSYSTYP32)
/*
* Validators
*/
#define VALID_SECSIZE(s) \
(s == 512 || s == 1024 || s == 2048 || s == 4096)
#define VALID_SPCL(s) (ISP2((s)) && (unsigned int)(s) <= 128)
#define VALID_CLSIZE(s) (ISP2((s)) && (unsigned int)(s) <= (64 * 1024))
#define VALID_NUMFATS(n) ((n) > 0 && (n) < 8)
#define VALID_RSVDSEC(s) ((s) > 0)
#define VALID_BPBSIG(sig) ((sig) == MBB_MAGIC)
#define VALID_BOOTSIG(sig) ((sig) == 0x29)
#define VALID_MEDIA(m) ((m) == 0xF0 || ((m) >= 0xF8 && (m) <= 0xFF))
/*
* this might require a change for codepage support. In particular,
* pc_validchar() cannot be a macro anymore if codepages get involved.
*/
#define VALID_VOLLAB(l) ( \
pc_validchar((l)[0]) && pc_validchar((l)[1]) && \
pc_validchar((l)[2]) && pc_validchar((l)[3]) && \
pc_validchar((l)[4]) && pc_validchar((l)[5]) && \
pc_validchar((l)[6]) && pc_validchar((l)[7]) && \
pc_validchar((l)[8]) && pc_validchar((l)[9]) && \
pc_validchar((l)[10]))
/*
* We might actually use the 'validchar' checks as well; it only needs
* to be printable. Should this ever caused failed media recognition,
* we can change it. Many ISVs put different strings into the "oemname"
* field.
*/
#define VALID_OEMNAME(nm) ( \
bcmp((nm), "MSDOS", 5) == 0 || bcmp((nm), "MSWIN", 5) == 0)
#define VALID_FSTYPSTR16(typ) (bcmp((typ), "FAT", 3) == 0)
#define VALID_FSTYPSTR32(typ) (bcmp((typ), "FAT32", 5) == 0)
#define VALID_JMPBOOT(b) ( \
((b)[0] == 0xeb && (b)[2] == 0x90) || (b)[0] == 0xe9)
#define VALID_FSVER32(v) ((v) == PCFS_SUPPORTED_FSVER)
/*
* Can we check this properly somehow ? There should be a better way.
* The FAT spec doesn't mention reserved bits need to be zero ...
*/
#define VALID_EXTFLAGS(flags) (((flags) & 0x8f) == (flags))
/*
* Validation results
*/
#define BPB_SECSIZE_OK (1 << 0) /* ok: 512/1024/2048/4096 */
#define BPB_OEMNAME_OK (1 << 1) /* "MSDOS" or "MSWIN" */
#define BPB_JMPBOOT_OK (1 << 2) /* 16bit "jmp" / "call" */
#define BPB_SECPERCLUS_OK (1 << 3) /* power of 2, [1 .. 128] */
#define BPB_RSVDSECCNT_OK (1 << 4) /* cannot be zero */
#define BPB_NUMFAT_OK (1 << 5) /* >= 1, <= 8 */
#define BPB_ROOTENTCNT_OK (1 << 6) /* 0 on FAT32, != 0 else */
#define BPB_TOTSEC_OK (1 << 7) /* smaller than volume */
#define BPB_TOTSEC16_OK (1 << 8) /* 0 on FAT32, != 0 on FAT12 */
#define BPB_TOTSEC32_OK (1 << 9) /* 0 on FAT12, != 0 on FAT32 */
#define BPB_MEDIADESC_OK (1 << 10) /* 0xf0 or 0xf8..0xff */
#define BPB_FATSZ_OK (1 << 11) /* [nclusters], no smaller */
#define BPB_FATSZ16_OK (1 << 12) /* 0 on FAT32, != 0 else */
#define BPB_FATSZ32_OK (1 << 13) /* non-zero on FAT32 */
#define BPB_BPBSIG_OK (1 << 14) /* 0x55, 0xAA */
#define BPB_BOOTSIG16_OK (1 << 15) /* 0x29 - if present */
#define BPB_BOOTSIG32_OK (1 << 16) /* 0x29 - unless SYSLINUX2.x */
#define BPB_FSTYPSTR16_OK (1 << 17) /* At least "FAT" */
#define BPB_FSTYPSTR32_OK (1 << 18) /* "FAT32" */
#define BPB_EXTFLAGS_OK (1 << 19) /* reserved bits should be 0 */
#define BPB_FSVER_OK (1 << 20) /* must be 0 */
#define BPB_ROOTCLUSTER_OK (1 << 21) /* must be != 0 and valid */
#define BPB_FSISEC_OK (1 << 22) /* != 0, <= reserved */
#define BPB_BKBOOTSEC_OK (1 << 23) /* != 0, <= reserved, != fsi */
#define BPB_VOLLAB16_OK (1 << 24) /* passes pc_validchar() */
#define BPB_VOLLAB32_OK (1 << 25) /* passes pc_validchar() */
#define BPB_NCLUSTERS_OK (1 << 26) /* from FAT spec */
#define BPB_CLSIZE_OK (1 << 27) /* cluster size */
#define BPB_MEDIASZ_OK (1 << 28) /* filesystem fits on device */
#define FAT12_VALIDMSK \
(BPB_SECSIZE_OK | BPB_SECPERCLUS_OK | BPB_CLSIZE_OK | \
BPB_RSVDSECCNT_OK | BPB_NUMFAT_OK | BPB_ROOTENTCNT_OK | \
BPB_TOTSEC_OK | BPB_TOTSEC16_OK | \
BPB_FATSZ_OK | BPB_FATSZ16_OK | BPB_BPBSIG_OK)
#define FAT16_VALIDMSK \
(BPB_SECSIZE_OK | BPB_SECPERCLUS_OK | BPB_CLSIZE_OK | \
BPB_RSVDSECCNT_OK | BPB_NUMFAT_OK | BPB_ROOTENTCNT_OK | \
BPB_TOTSEC_OK | BPB_TOTSEC16_OK | BPB_TOTSEC32_OK | \
BPB_FATSZ_OK | BPB_FATSZ16_OK | BPB_BPBSIG_OK)
/*
* A note on FAT32: According to the FAT spec, FAT32 _must_ have a valid
* extended BPB and therefore, as a proof of its existance, the FAT32
* boot signature (offset 66) must be valid as well. Why don't we check
* for BPB_BOOTSIG32_OK then ?
*
* We don't test for this here first-pass, because there are media out
* there that are valid FAT32 structurally but don't have a valid sig.
* This happens if older versions of the SYSLINUX bootloader (below 3.x)
* are installed on a media with a FAT32 on it. SYSLINUX 2.x and lower
* overwrite the BPB past the end of the FAT12/16 extension with its
* bootloader code - and the FAT16 extended BPB is 62 Bytes...
* All structurally relevant fields of the FAT32 BPB are within the first
* 52 Bytes, so the filesystem is accessible - but the signature check
* would reject it.
*/
#define FAT32_VALIDMSK \
(BPB_SECSIZE_OK | BPB_SECPERCLUS_OK | BPB_CLSIZE_OK | \
BPB_RSVDSECCNT_OK | BPB_NUMFAT_OK | BPB_ROOTENTCNT_OK | \
BPB_TOTSEC_OK | BPB_TOTSEC16_OK | BPB_TOTSEC32_OK | \
BPB_FATSZ_OK | BPB_FATSZ16_OK | BPB_FATSZ32_OK | \
BPB_EXTFLAGS_OK | BPB_FSVER_OK | BPB_ROOTCLUSTER_OK | \
BPB_BPBSIG_OK)
/*
* FAT32 BPB allows 'versioning' via FSVer32. We follow the 'NULL' spec.
*/
#define PCFS_SUPPORTED_FSVER 0
/*
* Filesystem summary information (introduced originally for FAT32 volumes).
* We need to maintain fs_free_clusters or Microsoft Scandisk will be upset.
* We keep these values in-core even for FAT12/FAT16 but will never attempt
* to write them out to disk then.
*/
typedef struct fat_fsinfo {
uint32_t fs_free_clusters; /* # free clusters. -1 if unknown */
uint32_t fs_next_free; /* search next free after this cn */
} fat_fsi_t;
/*
* On-disk FSI. All values in little endian. Only FAT32 has this.
*/
typedef struct fat_od_fsi {
uint32_t fsi_leadsig; /* 0x41615252 */
char fsi_reserved1[480];
uint32_t fsi_strucsig; /* 0x61417272 */
fat_fsi_t fsi_incore; /* free/nextfree */
char fsi_reserved2[12];
uint32_t fsi_trailsig; /* 0xaa550000 */
} fat_od_fsi_t;
#define FSI_LEADSIG LE_32(0x41615252)
#define FSI_STRUCSIG LE_32(0x61417272)
#define FSI_TRAILSIG LE_32(0xaa550000) /* same as MBB_MAGIC */
#define FSISIG_OK(fsi) ( \
((fat_od_fsi_t *)(fsi))->fsi_leadsig == FSI_LEADSIG && \
((fat_od_fsi_t *)(fsi))->fsi_strucsig == FSI_STRUCSIG && \
((fat_od_fsi_t *)(fsi))->fsi_trailsig == FSI_TRAILSIG)
#define FSINFO_UNKNOWN ((uint32_t)(-1)) /* free/next not valid */
typedef enum { FAT12, FAT16, FAT32, FAT_UNKNOWN, FAT_QUESTIONABLE } fattype_t;
struct pcfs {
struct vfs *pcfs_vfs; /* vfs for this fs */
int pcfs_flags; /* flags */
int pcfs_ldrive; /* logical DOS drive number */
fattype_t pcfs_fattype;
dev_t pcfs_xdev; /* actual device that is mounted */
struct vnode *pcfs_devvp; /* and a vnode for it */
int pcfs_secsize; /* sector size in bytes */
int pcfs_spcl; /* sectors per cluster */
int pcfs_spt; /* sectors per track */
int pcfs_sdshift; /* shift to convert sector into */
/* DEV_BSIZE "sectors"; assume */
/* pcfs_secsize is 2**n times of */
/* DEV_BSIZE */
int pcfs_fatsec; /* number of sec per FAT */
int pcfs_numfat; /* number of FAT copies */
int pcfs_rdirsec; /* number of sec in root dir */
daddr_t pcfs_dosstart; /* start blkno of DOS partition */
daddr_t pcfs_fsistart; /* start blkno of FSI sector */
daddr_t pcfs_fatstart; /* start blkno of first FAT */
daddr_t pcfs_rdirstart; /* start blkno of root dir */
daddr_t pcfs_datastart; /* start blkno of data area */
int pcfs_clsize; /* cluster size in bytes */
int pcfs_ncluster; /* number of clusters in fs */
int pcfs_nrefs; /* number of active pcnodes */
int pcfs_frefs; /* number of active file pcnodes */
int pcfs_nxfrecls; /* next free cluster */
uchar_t *pcfs_fatp; /* ptr to FAT data */
uchar_t *pcfs_fat_changemap; /* map of changed fat data */
int pcfs_fat_changemapsize; /* size of FAT changemap */
time_t pcfs_fattime; /* time FAT becomes invalid */
time_t pcfs_verifytime; /* time to reverify disk */
kmutex_t pcfs_lock; /* per filesystem lock */
kthread_id_t pcfs_owner; /* id of thread locking pcfs */
int pcfs_count; /* # of pcfs locks for pcfs_owner */
struct fat_fsinfo pcfs_fsinfo; /* in-core fsinfo */
struct pcfs *pcfs_nxt; /* linked list of all mounts */
int pcfs_fatjustread; /* Used to flag a freshly found FAT */
struct vnode *pcfs_root; /* vnode for the root dir of the fs */
int pcfs_secondswest; /* recording timezone for this fs */
len_t pcfs_mediasize;
int pcfs_rootblksize;
int pcfs_mediadesc; /* media descriptor */
pc_cluster32_t pcfs_lastclmark;
pc_cluster32_t pcfs_rootclnum;
timestruc_t pcfs_mounttime; /* timestamp for "/" */
};
/*
* flags
*/
#define PCFS_FATMOD 0x01 /* FAT has been modified */
#define PCFS_LOCKED 0x02 /* fs is locked */
#define PCFS_WANTED 0x04 /* locked fs is wanted */
#define PCFS_NOCHK 0x800 /* don't resync fat on error */
#define PCFS_BOOTPART 0x1000 /* boot partition type */
#define PCFS_HIDDEN 0x2000 /* show hidden files */
#define PCFS_PCMCIA_NO_CIS 0x4000 /* PCMCIA psuedo floppy */
#define PCFS_FOLDCASE 0x8000 /* fold filenames to lowercase */
#define PCFS_FSINFO_OK 0x10000 /* valid FAT32 fsinfo sector */
#define PCFS_IRRECOV 0x20000 /* FS was messed with during write */
#define PCFS_NOCLAMPTIME 0x40000 /* expose full FAT timestamp range */
#define PCFS_NOATIME 0x80000 /* disable atime updates */
#define IS_FAT12(PCFS) ((PCFS)->pcfs_fattype == FAT12)
#define IS_FAT16(PCFS) ((PCFS)->pcfs_fattype == FAT16)
#define IS_FAT32(PCFS) ((PCFS)->pcfs_fattype == FAT32)
/* for compatibility */
struct old_pcfs_args {
int secondswest; /* seconds west of Greenwich */
int dsttime; /* type of dst correction */
};
struct pcfs_args {
int secondswest; /* seconds west of Greenwich */
int dsttime; /* type of dst correction */
int flags;
};
/*
* pcfs mount options.
*/
#define MNTOPT_PCFS_HIDDEN "hidden"
#define MNTOPT_PCFS_NOHIDDEN "nohidden"
#define MNTOPT_PCFS_FOLDCASE "foldcase"
#define MNTOPT_PCFS_NOFOLDCASE "nofoldcase"
#define MNTOPT_PCFS_CLAMPTIME "clamptime"
#define MNTOPT_PCFS_NOCLAMPTIME "noclamptime"
#define MNTOPT_PCFS_TIMEZONE "timezone"
#define MNTOPT_PCFS_SECSIZE "secsize"
/*
* Disk timeout value in sec.
* This is used to time out the in core FAT and to re-verify the disk.
* This should be less than the time it takes to change floppys
*/
#define PCFS_DISKTIMEOUT 2
#define PCFS_MAXOFFSET_T UINT32_MAX /* PCFS max file size */
#define VFSTOPCFS(VFSP) ((struct pcfs *)((VFSP)->vfs_data))
#define PCFSTOVFS(FSP) ((FSP)->pcfs_vfs)
/*
* special cluster numbers in FAT
*/
#define PCF_FREECLUSTER 0x00 /* cluster is available */
#define PCF_ERRORCLUSTER 0x01 /* error occurred allocating cluster */
#define PCF_12BCLUSTER 0xFF0 /* 12-bit version of reserved cluster */
#define PCF_RESCLUSTER 0xFFF0 /* 16-bit version of reserved cluster */
#define PCF_RESCLUSTER32 0xFFFFFF0 /* 32-bit version */
#define PCF_BADCLUSTER 0xFFF7 /* bad cluster, do not use */
#define PCF_BADCLUSTER32 0xFFFFFF7 /* 32-bit version */
#define PCF_LASTCLUSTER 0xFFF8 /* >= means last cluster in file */
#define PCF_LASTCLUSTER32 0xFFFFFF8 /* 32-bit version */
#define PCF_LASTCLUSTERMARK 0xFFFF /* value used to mark last cluster */
#define PCF_LASTCLUSTERMARK32 0xFFFFFFF /* 32-bit version */
#define PCF_FIRSTCLUSTER 2 /* first valid cluster number */
/*
* file system constants
*/
#define PC_MAXFATSEC 256 /* maximum number of sectors in FAT */
/*
* file system parameter macros
*/
#define pc_clear_fatchanges(PCFS) \
bzero((PCFS)->pcfs_fat_changemap, (PCFS)->pcfs_fat_changemapsize)
#define pc_blksize(PCFS, PCP, OFF) /* file system block size */ \
(((PCTOV(PCP)->v_flag & VROOT) && !IS_FAT32(PCFS)) ? \
((OFF) >= \
((PCFS)->pcfs_rdirsec & \
~((PCFS)->pcfs_spcl - 1)) * ((PCFS)->pcfs_secsize)? \
((PCFS)->pcfs_rdirsec & \
((PCFS)->pcfs_spcl - 1)) * ((PCFS)->pcfs_secsize): \
(PCFS)->pcfs_clsize): \
(PCFS)->pcfs_clsize)
#define pc_blkoff(PCFS, OFF) /* offset within block */ \
((int)((OFF) & ((PCFS)->pcfs_clsize - 1)))
#define pc_lblkno(PCFS, OFF) /* logical block (cluster) no */ \
((daddr_t)((OFF) / (PCFS)->pcfs_clsize))
#define pc_dbtocl(PCFS, DB) /* disk blks to clusters */ \
((int)((DB) / (PCFS)->pcfs_spcl))
#define pc_cltodb(PCFS, CL) /* clusters to disk blks */ \
((daddr_t)((CL) * (PCFS)->pcfs_spcl))
#define pc_dbdaddr(PCFS, DB) /* sector to DEV_BSIZE "sector" addr */ \
((DB) << (PCFS)->pcfs_sdshift)
#define pc_daddrdb(PCFS, DADDR) /* DEV_BSIZE "sector" addr to sector addr */ \
((DADDR) >> (PCFS)->pcfs_sdshift)
#define pc_cldaddr(PCFS, CL) /* DEV_BSIZE "sector" addr for cluster */ \
pc_dbdaddr(PCFS, ((daddr_t)((PCFS)->pcfs_datastart + \
pc_cltodb(PCFS, (CL) - PCF_FIRSTCLUSTER))))
#define pc_daddrcl(PCFS, DADDR) /* cluster for disk address */ \
((int)(PCF_FIRSTCLUSTER + \
pc_dbtocl(pc_daddrdb(PCFS, DADDR) - (PCFS)->pcfs_datastart)))
/*
* Number of directory entries per sector / cluster
*/
#define pc_direntpersec(PCFS) \
((int)((PCFS)->pcfs_secsize / sizeof (struct pcdir)))
#define pc_direntpercl(PCFS) \
((int)((PCFS)->pcfs_clsize / sizeof (struct pcdir)))
/*
* out-of-range check for cluster numbers.
*/
#define pc_validcl(PCFS, CL) /* check that cluster no is legit */ \
((int)(CL) >= PCF_FIRSTCLUSTER && \
(int)(CL) < (PCFS)->pcfs_ncluster + PCF_FIRSTCLUSTER)
/*
* external routines.
*/
extern int pc_lockfs(struct pcfs *, int, int); /* lock fs and get fat */
extern void pc_unlockfs(struct pcfs *); /* ulock the fs */
extern int pc_getfat(struct pcfs *); /* get fat from disk */
extern void pc_invalfat(struct pcfs *); /* invalidate incore fat */
extern int pc_syncfat(struct pcfs *); /* sync fat to disk */
extern int pc_freeclusters(struct pcfs *); /* num free clusters in fs */
extern pc_cluster32_t pc_alloccluster(struct pcfs *, int);
extern void pc_setcluster(struct pcfs *, pc_cluster32_t, pc_cluster32_t);
extern void pc_mark_fat_updated(struct pcfs *fsp, pc_cluster32_t cn);
extern int pc_fat_is_changed(struct pcfs *fsp, pc_cluster32_t bn);
/*
* debugging
*/
extern int pcfsdebuglevel;
#define PC_DPRINTF0(level, A) \
if (pcfsdebuglevel >= level) \
cmn_err(CE_CONT, (A))
#define PC_DPRINTF1(level, A, B) \
if (pcfsdebuglevel >= level) \
cmn_err(CE_CONT, (A), (B))
#define PC_DPRINTF2(level, A, B, C) \
if (pcfsdebuglevel >= level) \
cmn_err(CE_CONT, (A), (B), (C))
#define PC_DPRINTF3(level, A, B, C, D) \
if (pcfsdebuglevel >= level) \
cmn_err(CE_CONT, (A), (B), (C), (D))
#define PC_DPRINTF4(level, A, B, C, D, E) \
if (pcfsdebuglevel >= level) \
cmn_err(CE_CONT, (A), (B), (C), (D), (E))
#ifdef __cplusplus
}
#endif
#endif /* _SYS_FS_PC_FS_H */