ufs_inode.h revision 5b024a5b76c96ebbaf36ba7803ba4dbe959f7219
/*
* 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 2006 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
/* Copyright (c) 1984, 1986, 1987, 1988, 1989 AT&T */
/* All Rights Reserved */
/*
* University Copyright- Copyright (c) 1982, 1986, 1988
* The Regents of the University of California
* All Rights Reserved
*
* University Acknowledgment- Portions of this document are derived from
* software developed by the University of California, Berkeley, and its
* contributors.
*/
#ifndef _SYS_FS_UFS_INODE_H
#define _SYS_FS_UFS_INODE_H
#pragma ident "%Z%%M% %I% %E% SMI"
#include <sys/isa_defs.h>
#include <sys/fbuf.h>
#include <sys/fdbuffer.h>
#include <sys/fcntl.h>
#include <sys/uio.h>
#include <sys/t_lock.h>
#include <sys/thread.h>
#include <sys/cred.h>
#include <sys/time.h>
#include <sys/types32.h>
#include <sys/fs/ufs_fs.h>
#include <sys/fs/ufs_lockfs.h>
#include <sys/fs/ufs_trans.h>
#include <sys/kstat.h>
#include <sys/fs/ufs_acl.h>
#include <sys/fs/ufs_panic.h>
#include <sys/dnlc.h>
#ifdef __cplusplus
extern "C" {
#endif
/*
* The I node is the focus of all local file activity in UNIX.
* There is a unique inode allocated for each active file,
* each current directory, each mounted-on file, each mapping,
* and the root. An inode is `named' by its dev/inumber pair.
* Data in icommon is read in from permanent inode on volume.
*
* Each inode has 5 locks associated with it:
* i_rwlock: Serializes ufs_write and ufs_setattr request
* and allows ufs_read requests to proceed in parallel.
* Serializes reads/updates to directories.
* vfs_dqrwlock: Manages quota sub-system quiescence. See below.
* i_contents: Protects almost all of the fields in the inode
* except for those listed below. When held
* in writer mode also protects those fields
* listed under i_tlock.
* i_tlock: When i_tlock is held with the i_contents reader
* lock the i_atime, i_mtime, i_ctime,
* i_delayoff, i_delaylen, i_nextrio, i_writes, i_flag
* i_seq, i_writer & i_mapcnt fields are protected.
* For more i_flag locking info see below.
* ih_lock: Protects inode hash chain buckets
* ifree_lock: Protects inode freelist
*
* Lock ordering:
* i_rwlock > i_contents > i_tlock
* i_rwlock > vfs_dqrwlock > i_contents(writer) > i_tlock
* i_contents > i_tlock
* vfs_dqrwlock > i_contents(writer) > i_tlock
* ih_lock > i_contents > i_tlock
*
* Making major changes to quota sub-system state, while the file
* system is mounted required the addition of another lock. The
* primary lock in the quota sub-system is vfs_dqrwlock in the ufsvfs
* structure. This lock is used to manage quota sub-system quiescence
* for a particular file system. Major changes to quota sub-system
* state (disabling quotas, enabling quotas, and setting new quota
* limits) all require the file system to be quiescent and grabbing
* vfs_dqrwlock as writer accomplishes this. On the other hand,
* grabbing vfs_dqrwlock as reader makes the quota sub-system
* non-quiescent and lets the quota sub-system know that now is not a
* good time to change major quota sub-system state. Typically
* vfs_dqrwlock is grabbed for reading before i_contents is grabbed for
* writing. However, there are cases where vfs_dqrwlock is grabbed for
* reading without a corresponding i_contents write grab because there
* is no relevant inode. There are also cases where i_contents is
* grabbed for writing when a vfs_dqrwlock read grab is not needed
* because the inode changes do not affect quotas.
*
* Unfortunately, performance considerations have required that we be more
* intelligent about using i_tlock when updating i_flag. Ideally, we would
* have simply separated out several of the bits in i_flag into their own
* ints to avoid problems. But, instead, we have implemented the following
* rules:
*
* o You can update any i_flag field while holding the writer-contents,
* or by holding the reader-contents AND holding i_tlock.
* You can only call ITIMES_NOLOCK while holding the writer-contents,
* or by holding the reader-contents AND holding i_tlock.
*
* o For a directory, holding the reader-rw_lock is sufficient for setting
* IACC.
*
* o Races with IREF are avoided by holding the reader contents lock
* and by holding i_tlock in ufs_rmidle, ufs_putapage, and ufs_getpage.
* And by holding the writer-contents in ufs_iinactive.
*
* o The callers are no longer required to handle the calls to ITIMES
* and ITIMES_NOLOCK. The functions that set the i_flag bits are
* responsible for managing those calls. The exceptions are the
* bmap routines.
*
* SVR4 Extended Fundamental Type (EFT) support:
* The inode structure has been enhanced to support
* 32-bit user-id, 32-bit group-id, and 32-bit device number.
* Standard SVR4 ufs also supports 32-bit mode field. For the reason
* of backward compatibility with the previous ufs disk format,
* 32-bit mode field is not supported.
*
* The current inode structure is 100% backward compatible with
* the previous inode structure if no user-id or group-id exceeds
* USHRT_MAX, and no major or minor number of a device number
* stored in an inode exceeds 255.
*
* Rules for managing i_seq:
* o i_seq is locked under the same rules as i_flag
* o The i_ctime or i_mtime MUST never change without increasing
* the value of i_seq.
* o You may increase the value of i_seq without the timestamps
* changing, this may decrease the callers performance but will
* be functionally correct.
* o The common case is when IUPD or ICHG is set, increase i_seq
* and immediately call ITIMES* or ufs_iupdat to create a new timestamp.
* o A less common case is the setting of IUPD or ICHG and while still
* holding the correct lock defer the timestamp and i_seq update
* until later, but it must still be done before the lock is released.
* bmap_write is an example of this, where the caller does the update.
* o If multiple changes are being made with the timestamps being
* updated only at the end, a single increase of i_seq is allowed.
* o If changes are made with IUPD or ICHG being set, but
* the controlling lock is being dropped before the timestamp is
* updated, there is a risk that another thread will also change
* the file, update i_flag, and push just one timestamp update.
* There is also the risk that another thread calls ITIMES or
* ufs_iupdat without setting IUPD|ICHG and thus not changing i_seq,
* this will cause ufs_imark to change the timestamps without changing
* i_seq. If the controlling lock is dropped, ISEQ must be set to
* force i_seq to be increased on next ufs_imark, but i_seq MUST still
* be increased by the original setting thread before its deferred
* call to ITIMES to insure it is increased the correct number of times.
*/
#define UID_LONG (o_uid_t)65535
/* flag value to indicate uid is 32-bit long */
#define GID_LONG (o_uid_t)65535
/* flag value to indicate gid is 32-bit long */
#define NDADDR 12 /* direct addresses in inode */
#define NIADDR 3 /* indirect addresses in inode */
#define FSL_SIZE (NDADDR + NIADDR - 1) * sizeof (daddr32_t)
/* max fast symbolic name length is 56 */
#define i_fs i_ufsvfs->vfs_bufp->b_un.b_fs
#define i_vfs i_vnode->v_vfsp
struct icommon {
o_mode_t ic_smode; /* 0: mode and type of file */
short ic_nlink; /* 2: number of links to file */
o_uid_t ic_suid; /* 4: owner's user id */
o_gid_t ic_sgid; /* 6: owner's group id */
u_offset_t ic_lsize; /* 8: number of bytes in file */
#ifdef _KERNEL
struct timeval32 ic_atime; /* 16: time last accessed */
struct timeval32 ic_mtime; /* 24: time last modified */
struct timeval32 ic_ctime; /* 32: last time inode changed */
#else
time32_t ic_atime; /* 16: time last accessed */
int32_t ic_atspare;
time32_t ic_mtime; /* 24: time last modified */
int32_t ic_mtspare;
time32_t ic_ctime; /* 32: last time inode changed */
int32_t ic_ctspare;
#endif
daddr32_t ic_db[NDADDR]; /* 40: disk block addresses */
daddr32_t ic_ib[NIADDR]; /* 88: indirect blocks */
int32_t ic_flags; /* 100: cflags */
int32_t ic_blocks; /* 104: 512 byte blocks actually held */
int32_t ic_gen; /* 108: generation number */
int32_t ic_shadow; /* 112: shadow inode */
uid_t ic_uid; /* 116: long EFT version of uid */
gid_t ic_gid; /* 120: long EFT version of gid */
uint32_t ic_oeftflag; /* 124: extended attr directory ino, 0 = none */
};
/*
* Large directories can be cached. Directory caching can take the following
* states:
*/
typedef enum {
CD_DISABLED_NOMEM = -2,
CD_DISABLED_TOOBIG,
CD_DISABLED,
CD_ENABLED
} cachedir_t;
/*
* Large Files: Note we use the inline functions load_double, store_double
* to load and store the long long values of i_size. Therefore the
* address of i_size must be eight byte aligned. Kmem_alloc of incore
* inode structure makes sure that the structure is 8-byte aligned.
* XX64 - reorder this structure?
*/
typedef struct inode {
struct inode *i_chain[2]; /* must be first */
struct inode *i_freef; /* free list forward - must be before i_ic */
struct inode *i_freeb; /* free list back - must be before i_ic */
struct icommon i_ic; /* Must be here */
struct vnode *i_vnode; /* vnode associated with this inode */
struct vnode *i_devvp; /* vnode for block I/O */
dev_t i_dev; /* device where inode resides */
ino_t i_number; /* i number, 1-to-1 with device address */
off_t i_diroff; /* offset in dir, where we found last entry */
/* just a hint - no locking needed */
struct ufsvfs *i_ufsvfs; /* incore fs associated with inode */
struct dquot *i_dquot; /* quota structure controlling this file */
krwlock_t i_rwlock; /* serializes write/setattr requests */
krwlock_t i_contents; /* protects (most of) inode contents */
kmutex_t i_tlock; /* protects time fields, i_flag */
offset_t i_nextr; /* */
/* next byte read offset (read-ahead) */
/* No lock required */
/* */
uint_t i_flag; /* inode flags */
uint_t i_seq; /* modification sequence number */
cachedir_t i_cachedir; /* Cache this directory on next lookup */
/* - no locking needed */
long i_mapcnt; /* mappings to file pages */
int *i_map; /* block list for the corresponding file */
dev_t i_rdev; /* INCORE rdev from i_oldrdev by ufs_iget */
size_t i_delaylen; /* delayed writes, units=bytes */
offset_t i_delayoff; /* where we started delaying */
offset_t i_nextrio; /* where to start the next clust */
long i_writes; /* number of outstanding bytes in write q */
kcondvar_t i_wrcv; /* sleep/wakeup for write throttle */
offset_t i_doff; /* dinode byte offset in file system */
si_t *i_ufs_acl; /* pointer to acl entry */
dcanchor_t i_danchor; /* directory cache anchor */
kthread_t *i_writer; /* thread which is in window in wrip() */
} inode_t;
struct dinode {
union {
struct icommon di_icom;
char di_size[128];
} di_un;
};
#define i_mode i_ic.ic_smode
#define i_nlink i_ic.ic_nlink
#define i_uid i_ic.ic_uid
#define i_gid i_ic.ic_gid
#define i_smode i_ic.ic_smode
#define i_suid i_ic.ic_suid
#define i_sgid i_ic.ic_sgid
#define i_size i_ic.ic_lsize
#define i_db i_ic.ic_db
#define i_ib i_ic.ic_ib
#define i_atime i_ic.ic_atime
#define i_mtime i_ic.ic_mtime
#define i_ctime i_ic.ic_ctime
#define i_shadow i_ic.ic_shadow
#define i_oeftflag i_ic.ic_oeftflag
#define i_blocks i_ic.ic_blocks
#define i_cflags i_ic.ic_flags
#ifdef _LITTLE_ENDIAN
/*
* Originally done on x86, but carried on to all other little
* architectures, which provides for file system compatibility.
*/
#define i_ordev i_ic.ic_db[1] /* USL SVR4 compatibility */
#else
#define i_ordev i_ic.ic_db[0] /* was i_oldrdev */
#endif
#define i_gen i_ic.ic_gen
#define i_forw i_chain[0]
#define i_back i_chain[1]
/* EFT transition aids - obsolete */
#define oEFT_MAGIC 0x90909090
#define di_oeftflag di_ic.ic_oeftflag
#define di_ic di_un.di_icom
#define di_mode di_ic.ic_smode
#define di_nlink di_ic.ic_nlink
#define di_uid di_ic.ic_uid
#define di_gid di_ic.ic_gid
#define di_smode di_ic.ic_smode
#define di_suid di_ic.ic_suid
#define di_sgid di_ic.ic_sgid
#define di_size di_ic.ic_lsize
#define di_db di_ic.ic_db
#define di_ib di_ic.ic_ib
#define di_atime di_ic.ic_atime
#define di_mtime di_ic.ic_mtime
#define di_ctime di_ic.ic_ctime
#define di_cflags di_ic.ic_flags
#ifdef _LITTLE_ENDIAN
#define di_ordev di_ic.ic_db[1]
#else
#define di_ordev di_ic.ic_db[0]
#endif
#define di_shadow di_ic.ic_shadow
#define di_blocks di_ic.ic_blocks
#define di_gen di_ic.ic_gen
/* flags */
#define IUPD 0x0001 /* file has been modified */
#define IACC 0x0002 /* inode access time to be updated */
#define IMOD 0x0004 /* inode has been modified */
#define ICHG 0x0008 /* inode has been changed */
#define INOACC 0x0010 /* no access time update in getpage */
#define IMODTIME 0x0020 /* mod time already set */
#define IREF 0x0040 /* inode is being referenced */
#define ISYNC 0x0080 /* do all allocation synchronously */
#define IFASTSYMLNK 0x0100 /* fast symbolic link */
#define IMODACC 0x0200 /* only access time changed; */
/* filesystem won't become active */
#define IATTCHG 0x0400 /* only size/blocks have changed */
#define IBDWRITE 0x0800 /* the inode has been scheduled for */
/* write operation asynchronously */
#define ISTALE 0x1000 /* inode couldn't be read from disk */
#define IDEL 0x2000 /* inode is being deleted */
#define IDIRECTIO 0x4000 /* attempt directio */
#define ISEQ 0x8000 /* deferred i_seq increase */
#define IJUNKIQ 0x10000 /* on junk idle queue */
#define IQUIET 0x20000 /* No file system full messages */
/* cflags */
#define IXATTR 0x0001 /* extended attribute */
#define IFALLOCATE 0x0002 /* fallocate'd file */
/* modes */
#define IFMT 0170000 /* type of file */
#define IFIFO 0010000 /* named pipe (fifo) */
#define IFCHR 0020000 /* character special */
#define IFDIR 0040000 /* directory */
#define IFBLK 0060000 /* block special */
#define IFREG 0100000 /* regular */
#define IFLNK 0120000 /* symbolic link */
#define IFSHAD 0130000 /* shadow indode */
#define IFSOCK 0140000 /* socket */
#define IFATTRDIR 0160000 /* Attribute directory */
#define ISUID 04000 /* set user id on execution */
#define ISGID 02000 /* set group id on execution */
#define ISVTX 01000 /* save swapped text even after use */
#define IREAD 0400 /* read, write, execute permissions */
#define IWRITE 0200
#define IEXEC 0100
/* specify how the inode info is written in ufs_syncip() */
#define I_SYNC 1 /* wait for the inode written to disk */
#define I_DSYNC 2 /* wait for the inode written to disk */
/* only if IATTCHG is set */
#define I_ASYNC 0 /* don't wait for the inode written */
/* flags passed to ufs_itrunc(), indirtrunc(), and free() */
#define I_FREE 0x00000001 /* inode is being freed */
#define I_DIR 0x00000002 /* inode is a directory */
#define I_IBLK 0x00000004 /* indirect block */
#define I_CHEAP 0x00000008 /* cheap free */
#define I_SHAD 0x00000010 /* inode is a shadow inode */
#define I_QUOTA 0x00000020 /* quota file */
#define I_NOCANCEL 0x40 /* Don't cancel these fragments */
#define I_ACCT 0x00000080 /* Update ufsvfs' unreclaimed_blocks */
/*
* If ufs_dircheckforname() fails to find an entry with the given name,
* this "slot" structure holds state for ufs_direnter_*() as to where
* there is space to put an entry with that name.
* If ufs_dircheckforname() finds an entry with the given name, this structure
* holds state for ufs_dirrename() and ufs_dirremove() as to where the
* entry is. "status" indicates what ufs_dircheckforname() found:
* NONE name not found, large enough free slot not found,
* FOUND name not found, large enough free slot found
* EXIST name found
* If ufs_dircheckforname() fails due to an error, this structure is not
* filled in.
*
* After ufs_dircheckforname() succeeds the values are:
* status offset size fbp, ep
* ------ ------ ---- -------
* NONE end of dir needed not valid
* FOUND start of entry of ent both valid if fbp != NULL
* EXIST start of entry of prev ent valid
*
* "endoff" is set to 0 if the an entry with the given name is found, or if no
* free slot could be found or made; this means that the directory should not
* be truncated. If the entry was found, the search terminates so
* ufs_dircheckforname() didn't find out where the last valid entry in the
* directory was, so it doesn't know where to cut the directory off; if no free
* slot could be found or made, the directory has to be extended to make room
* for the new entry, so there's nothing to cut off.
* Otherwise, "endoff" is set to the larger of the offset of the last
* non-empty entry in the directory, or the offset at which the new entry will
* be placed, whichever is larger. This is used by ufs_diraddentry(); if a new
* entry is to be added to the directory, any complete directory blocks at the
* end of the directory that contain no non-empty entries are lopped off the
* end, thus shrinking the directory dynamically.
*/
typedef enum {NONE, FOUND, EXIST} slotstat_t;
struct ufs_slot {
struct direct *ep; /* pointer to slot */
struct fbuf *fbp; /* dir buf where slot is */
off_t offset; /* offset of area with free space */
off_t endoff; /* last useful location found in search */
slotstat_t status; /* status of slot */
int size; /* size of area at slotoffset */
int cached; /* cached directory */
};
/*
* Statistics on inodes
* Not protected by locks
*/
struct instats {
kstat_named_t in_size; /* current cache size */
kstat_named_t in_maxsize; /* maximum cache size */
kstat_named_t in_hits; /* cache hits */
kstat_named_t in_misses; /* cache misses */
kstat_named_t in_malloc; /* kmem_alloce'd */
kstat_named_t in_mfree; /* kmem_free'd */
kstat_named_t in_maxreached; /* Largest size reached by cache */
kstat_named_t in_frfront; /* # put at front of freelist */
kstat_named_t in_frback; /* # put at back of freelist */
kstat_named_t in_qfree; /* q's to delete thread */
kstat_named_t in_scan; /* # inodes scanned */
kstat_named_t in_tidles; /* # inodes idled by idle thread */
kstat_named_t in_lidles; /* # inodes idled by ufs_lookup */
kstat_named_t in_vidles; /* # inodes idled by ufs_vget */
kstat_named_t in_kcalloc; /* # inodes kmem_cache_alloced */
kstat_named_t in_kcfree; /* # inodes kmem_cache_freed */
kstat_named_t in_poc; /* # push-on-close's */
};
#ifdef _KERNEL
/*
* Extended attributes
*/
#define XATTR_DIR_NAME "/@/"
extern int ufs_ninode; /* high-water mark for inode cache */
extern struct vnodeops *ufs_vnodeops; /* vnode operations for ufs */
extern const struct fs_operation_def ufs_vnodeops_template[];
/*
* Convert between inode pointers and vnode pointers
*/
#define VTOI(VP) ((struct inode *)(VP)->v_data)
#define ITOV(IP) ((struct vnode *)(IP)->i_vnode)
/*
* convert to fs
*/
#define ITOF(IP) ((struct fs *)(IP)->i_fs)
/*
* Convert between vnode types and inode formats
*/
extern enum vtype iftovt_tab[];
#ifdef notneeded
/* Look at sys/mode.h and os/vnode.c */
extern int vttoif_tab[];
#endif
/*
* Mark an inode with the current (unique) timestamp.
* (Note that UFS's concept of time only keeps 32 bits of seconds
* in the on-disk format).
*/
struct timeval32 iuniqtime;
extern kmutex_t ufs_iuniqtime_lock;
#define ITIMES_NOLOCK(ip) ufs_itimes_nolock(ip)
#define ITIMES(ip) { \
mutex_enter(&(ip)->i_tlock); \
ITIMES_NOLOCK(ip); \
mutex_exit(&(ip)->i_tlock); \
}
/*
* The following interfaces are used to do atomic loads and stores
* of an inode's i_size, which is a long long data type.
*
* For LP64, we just to a load or a store - atomicity and alignment
* are 8-byte guaranteed. For x86 there are no such instructions,
* so we grab i_contents as reader to get the size; we already hold
* it as writer when we're setting the size.
*/
#ifdef _LP64
#define UFS_GET_ISIZE(resultp, ip) *(resultp) = (ip)->i_size
#define UFS_SET_ISIZE(value, ip) (ip)->i_size = (value)
#else /* _LP64 */
#define UFS_GET_ISIZE(resultp, ip) \
{ \
rw_enter(&(ip)->i_contents, RW_READER); \
*(resultp) = (ip)->i_size; \
rw_exit(&(ip)->i_contents); \
}
#define UFS_SET_ISIZE(value, ip) \
{ \
ASSERT(RW_WRITE_HELD(&(ip)->i_contents)); \
(ip)->i_size = (value); \
}
#endif /* _LP64 */
/*
* Allocate the specified block in the inode
* and make sure any in-core pages are initialized.
*/
#define BMAPALLOC(ip, off, size, cr) \
bmap_write((ip), (u_offset_t)(off), (size), BI_NORMAL, NULL, cr)
#define ESAME (-1) /* trying to rename linked files (special) */
#define UFS_HOLE (daddr32_t)-1 /* value used when no block allocated */
/*
* enums
*/
/* direnter ops */
enum de_op { DE_CREATE, DE_MKDIR, DE_LINK, DE_RENAME, DE_SYMLINK, DE_ATTRDIR};
/* dirremove ops */
enum dr_op { DR_REMOVE, DR_RMDIR, DR_RENAME };
/*
* block initialization type for bmap_write
*
* BI_NORMAL - allocate and zero fill pages in memory
* BI_ALLOC_ONLY - only allocate the block, do not zero out pages in mem
* BI_FALLOCATE - allocate only, do not zero out pages, and store as negative
* block number in inode block list
*/
enum bi_type { BI_NORMAL, BI_ALLOC_ONLY, BI_FALLOCATE };
/*
* This overlays the fid structure (see vfs.h)
*
* LP64 note: we use int32_t instead of ino_t since UFS does not use
* inode numbers larger than 32-bits and ufid's are passed to NFS
* which expects them to not grow in size beyond 10 bytes (12 including
* the length).
*/
struct ufid {
ushort_t ufid_len;
ushort_t ufid_flags;
int32_t ufid_ino;
int32_t ufid_gen;
};
/*
* each ufs thread (see ufs_thread.c) is managed by this struct
*/
struct ufs_q {
union uq_head {
void *_uq_generic; /* first entry on q */
struct inode *_uq_i;
ufs_failure_t *_uq_uf;
} _uq_head;
int uq_ne; /* # of entries/failures found */
int uq_lowat; /* thread runs when ne == lowat */
int uq_hiwat; /* synchronous idle if ne >= hiwat */
ushort_t uq_flags; /* flags (see below) */
kcondvar_t uq_cv; /* for sleep/wakeup */
kthread_id_t uq_threadp; /* thread managing this q */
kmutex_t uq_mutex; /* protects this struct */
};
#define uq_head _uq_head._uq_generic
#define uq_ihead _uq_head._uq_i
#define uq_ufhead _uq_head._uq_uf
/*
* uq_flags
*/
#define UQ_EXIT (0x0001) /* q server exits at its convenience */
#define UQ_WAIT (0x0002) /* thread is waiting on q server */
#define UQ_SUSPEND (0x0004) /* request for suspension */
#define UQ_SUSPENDED (0x0008) /* thread has suspended itself */
#define UQ_FASTCLIENTS (0x0010) /* fast clients in ufs_delq_info */
/*
* When logging is enabled, statvfs must account for blocks and files that
* may be on the delete queue. Protected by ufsvfsp->vfs_delete.uq_mutex
*/
struct ufs_delq_info {
kcondvar_t delq_fast_cv; /* for fast-operating clients */
u_offset_t delq_unreclaimed_blocks;
ulong_t delq_unreclaimed_files;
};
/*
* global idle queues
* The queues are sized dynamically in proportion to ufs_ninode
* which, unless overridden, scales with the amount of memory.
* The idle queue is halved whenever it hits the low water mark
* (1/4 of ufs_ninode), but can burst to sizes much larger. The number
* of hash queues is currently maintained to give on average IQHASHQLEN
* entries when the idle queue is at the low water mark.
* Note, we do not need to search along the hash queues, but use them
* in order to batch together geographically local inodes to allow
* their updates (via the log or buffer cache) to require less disk seeks.
* This gives an incredible performance boost for logging and a boost for
* non logging file systems.
*/
typedef struct {
inode_t *i_chain[2]; /* must match inode_t, but unused */
inode_t *i_freef; /* must match inode_t, idle list forward */
inode_t *i_freeb; /* must match inode_t, idle list back */
} iqhead_t;
extern struct ufs_q ufs_idle_q; /* used by global ufs idle thread */
extern iqhead_t *ufs_junk_iq; /* junk idle queues */
extern iqhead_t *ufs_useful_iq; /* useful idle queues */
extern int ufs_njunk_iq; /* number of entries in junk iq */
extern int ufs_nuseful_iq; /* number of entries in useful iq */
extern int ufs_niqhash; /* number of iq hash qs - power of 2 */
extern int ufs_iqhashmask; /* iq hash mask = ufs_niqhash - 1 */
#define IQHASHQLEN 32 /* see comments above */
#define INOCGSHIFT 7 /* 128 inodes per cylinder group */
#define IQHASH(ip) (((ip)->i_number >> INOCGSHIFT) & ufs_iqhashmask)
#define IQNEXT(i) ((i) + 1) & ufs_iqhashmask /* next idle queue */
extern struct ufs_q ufs_hlock; /* used by global ufs hlock thread */
/*
* vfs_lfflags flags
*/
#define UFS_LARGEFILES ((ushort_t)0x1) /* set if mount allows largefiles */
/*
* vfs_dfritime flags
*/
#define UFS_DFRATIME 0x1 /* deferred access time */
/*
* UFS VFS private data.
*
* UFS file system instances may be linked on several lists.
*
* - The vfs_next field chains together every extant ufs instance; this
* list is rooted at ufs_instances and should be used in preference to
* the overall vfs list (which is properly the province of the generic
* file system code, not of file system implementations). This same list
* link is used during forcible unmounts to chain together instances that
* can't yet be completely dismantled,
*
* - The vfs_wnext field is used within ufs_update to form a work list of
* UFS instances to be synced out.
*/
typedef struct ufsvfs {
struct vfs *vfs_vfs; /* back link */
struct ufsvfs *vfs_next; /* instance list link */
struct ufsvfs *vfs_wnext; /* work list link */
struct vnode *vfs_root; /* root vnode */
struct buf *vfs_bufp; /* buffer containing superblock */
struct vnode *vfs_devvp; /* block device vnode */
ushort_t vfs_lfflags; /* Large files (set by mount) */
ushort_t vfs_qflags; /* QUOTA: filesystem flags */
struct inode *vfs_qinod; /* QUOTA: pointer to quota file */
uint_t vfs_btimelimit; /* QUOTA: block time limit */
uint_t vfs_ftimelimit; /* QUOTA: file time limit */
krwlock_t vfs_dqrwlock; /* QUOTA: protects quota fields */
/*
* some fs local threads
*/
struct ufs_q vfs_delete; /* delayed inode delete */
struct ufs_q vfs_reclaim; /* reclaim open, deleted files */
/*
* This is copied from the super block at mount time.
*/
int vfs_nrpos; /* # rotational positions */
/*
* This lock protects cg's and super block pointed at by
* vfs_bufp->b_fs. Locks contents of fs and cg's and contents
* of vfs_dio.
*/
kmutex_t vfs_lock;
struct ulockfs vfs_ulockfs; /* ufs lockfs support */
uint_t vfs_dio; /* delayed io (_FIODIO) */
uint_t vfs_nointr; /* disallow lockfs interrupts */
uint_t vfs_nosetsec; /* disallow ufs_setsecattr */
uint_t vfs_syncdir; /* synchronous local directory ops */
uint_t vfs_dontblock; /* don't block on forced umount */
/*
* trans (logging ufs) stuff
*/
uint_t vfs_domatamap; /* set if matamap enabled */
ulong_t vfs_maxacl; /* transaction stuff - max acl size */
ulong_t vfs_dirsize; /* logspace for directory creation */
ulong_t vfs_avgbfree; /* average free blks in cg (blkpref) */
/*
* Some useful constants
*/
int vfs_nindirshift; /* calc. from fs_nindir */
int vfs_nindiroffset; /* calc. from fs_ninidr */
int vfs_ioclustsz; /* bytes in read/write cluster */
int vfs_iotransz; /* max device i/o transfer size */
vfs_ufsfx_t vfs_fsfx; /* lock/fix-on-panic support */
/*
* More useful constants
*/
int vfs_minfrags; /* calc. from fs_minfree */
/*
* Force DirectIO on all files
*/
uint_t vfs_forcedirectio;
/*
* Deferred inode time related fields
*/
clock_t vfs_iotstamp; /* last I/O timestamp */
uint_t vfs_dfritime; /* deferred inode time flags */
/*
* Some more useful info
*/
dev_t vfs_dev; /* device mounted from */
struct ml_unit *vfs_log; /* pointer to embedded log struct */
uint_t vfs_noatime; /* disable inode atime updates */
/*
* snapshot stuff
*/
void *vfs_snapshot; /* snapshot handle */
/*
* Controls logging "file system full" messages to messages file
*/
clock_t vfs_lastwhinetime;
int vfs_nolog_si; /* not logging summary info */
int vfs_validfs; /* indicates mounted fs */
/*
* Additional information about vfs_delete above
*/
struct ufs_delq_info vfs_delete_info; /* what's on the delete queue */
} ufsvfs_t;
#define vfs_fs vfs_bufp->b_un.b_fs
/*
* values for vfs_validfs
*/
#define UT_UNMOUNTED 0
#define UT_MOUNTED 1
#define UT_HLOCKING 2
/* inohsz is guaranteed to be a power of 2 */
#define INOHASH(ino) (((int)ino) & (inohsz - 1))
#define ISFALLOCBLK(ip, bn) \
(((bn) < 0) && ((bn) % ip->i_fs->fs_bsize == 0) && \
((ip)->i_cflags & IFALLOCATE && (bn) != UFS_HOLE))
union ihead {
union ihead *ih_head[2];
struct inode *ih_chain[2];
};
extern union ihead *ihead;
extern kmutex_t *ih_lock;
extern int *ih_ne;
extern int inohsz;
extern clock_t ufs_iowait;
#endif /* _KERNEL */
/*
* ufs function prototypes
*/
#if defined(_KERNEL) && !defined(_BOOT)
extern void ufs_iinit(void);
extern int ufs_iget(struct vfs *, ino_t, struct inode **, cred_t *);
extern int ufs_iget_alloced(struct vfs *, ino_t, struct inode **,
cred_t *);
extern void ufs_reset_vnode(vnode_t *);
extern void ufs_iinactive(struct inode *);
extern void ufs_iupdat(struct inode *, int);
extern int ufs_rmidle(struct inode *);
extern int ufs_itrunc(struct inode *, u_offset_t, int, cred_t *);
extern int ufs_iaccess(void *, int, cred_t *);
extern int rdip(struct inode *, struct uio *, int, struct cred *);
extern int wrip(struct inode *, struct uio *, int, struct cred *);
extern void ufs_imark(struct inode *);
extern void ufs_itimes_nolock(struct inode *);
extern int ufs_dirlook(struct inode *, char *, struct inode **,
cred_t *, int);
extern int ufs_direnter_cm(struct inode *, char *, enum de_op,
struct vattr *, struct inode **, cred_t *, int);
extern int ufs_direnter_lr(struct inode *, char *, enum de_op,
struct inode *, struct inode *, cred_t *, vnode_t **);
extern int ufs_dircheckpath(ino_t, struct inode *, struct inode *,
struct cred *);
extern int ufs_dirmakeinode(struct inode *, struct inode **,
struct vattr *, enum de_op, cred_t *);
extern int ufs_dirremove(struct inode *, char *, struct inode *,
vnode_t *, enum dr_op, cred_t *, vnode_t **);
extern int ufs_dircheckforname(struct inode *, char *, int,
struct ufs_slot *, struct inode **, struct cred *, int);
extern int ufs_xattrdirempty(struct inode *, ino_t, cred_t *);
extern int blkatoff(struct inode *, off_t, char **, struct fbuf **);
extern void sbupdate(struct vfs *);
extern int ufs_ialloc(struct inode *, ino_t, mode_t, struct inode **,
cred_t *);
extern void ufs_ifree(struct inode *, ino_t, mode_t);
extern void free(struct inode *, daddr_t, off_t, int);
extern int alloc(struct inode *, daddr_t, int, daddr_t *, cred_t *);
extern int realloccg(struct inode *, daddr_t, daddr_t, int, int,
daddr_t *, cred_t *);
extern int ufs_allocsp(struct vnode *, struct flock64 *, cred_t *);
extern int ufs_freesp(struct vnode *, struct flock64 *, int, cred_t *);
extern ino_t dirpref(inode_t *);
extern daddr_t blkpref(struct inode *, daddr_t, int, daddr32_t *);
extern daddr_t contigpref(ufsvfs_t *, size_t);
extern int ufs_rdwri(enum uio_rw, int, struct inode *, caddr_t, ssize_t,
offset_t, enum uio_seg, int *, cred_t *);
extern int bmap_read(struct inode *, u_offset_t, daddr_t *, int *);
extern int bmap_write(struct inode *, u_offset_t, int, enum bi_type,
daddr_t *, struct cred *);
extern int bmap_has_holes(struct inode *);
extern int bmap_find(struct inode *, boolean_t, u_offset_t *);
extern int bmap_set_bn(struct vnode *, u_offset_t, daddr32_t);
extern void ufs_vfs_add(struct ufsvfs *);
extern void ufs_vfs_remove(struct ufsvfs *);
extern void ufs_sbwrite(struct ufsvfs *);
extern void ufs_update(int);
extern int ufs_getsummaryinfo(dev_t, struct ufsvfs *, struct fs *);
extern int ufs_putsummaryinfo(dev_t, struct ufsvfs *, struct fs *);
extern int ufs_syncip(struct inode *, int, int, top_t);
extern int ufs_sync_indir(struct inode *);
extern int ufs_indirblk_sync(struct inode *, offset_t);
extern int ufs_badblock(struct inode *, daddr_t);
extern int ufs_indir_badblock(struct inode *, daddr32_t *);
extern void ufs_notclean(struct ufsvfs *);
extern void ufs_checkclean(struct vfs *);
extern int isblock(struct fs *, uchar_t *, daddr_t);
extern void setblock(struct fs *, uchar_t *, daddr_t);
extern void clrblock(struct fs *, uchar_t *, daddr_t);
extern int isclrblock(struct fs *, uchar_t *, daddr_t);
extern void fragacct(struct fs *, int, int32_t *, int);
extern int skpc(char, uint_t, char *);
extern int ufs_fbwrite(struct fbuf *, struct inode *);
extern int ufs_fbiwrite(struct fbuf *, struct inode *, daddr_t, long);
extern int ufs_putapage(struct vnode *, struct page *, u_offset_t *,
size_t *, int, struct cred *);
extern inode_t *ufs_alloc_inode(ufsvfs_t *, ino_t);
extern void ufs_free_inode(inode_t *);
/*
* special stuff
*/
extern void ufs_setreclaim(struct inode *);
extern int ufs_scan_inodes(int, int (*)(struct inode *, void *), void *,
struct ufsvfs *);
extern int ufs_sync_inode(struct inode *, void *);
extern int ufs_sticky_remove_access(struct inode *, struct inode *,
struct cred *);
/*
* quota
*/
extern int chkiq(struct ufsvfs *, int, struct inode *, uid_t, int,
struct cred *, char **errp, size_t *lenp);
/*
* ufs thread stuff
*/
extern void ufs_thread_delete(struct vfs *);
extern void ufs_delete_drain(struct vfs *, int, int);
extern void ufs_delete(struct ufsvfs *, struct inode *, int);
extern void ufs_inode_cache_reclaim(void *);
extern void ufs_idle_drain(struct vfs *);
extern void ufs_idle_some(int);
extern void ufs_thread_idle(void);
extern void ufs_thread_reclaim(struct vfs *);
extern void ufs_thread_init(struct ufs_q *, int);
extern void ufs_thread_start(struct ufs_q *, void (*)(), struct vfs *);
extern void ufs_thread_exit(struct ufs_q *);
extern void ufs_thread_suspend(struct ufs_q *);
extern void ufs_thread_continue(struct ufs_q *);
extern void ufs_thread_hlock(void *);
extern void ufs_delete_init(struct ufsvfs *, int);
extern void ufs_delete_adjust_stats(struct ufsvfs *, struct statvfs64 *);
extern void ufs_delete_drain_wait(struct ufsvfs *, int);
/*
* ufs lockfs stuff
*/
struct seg;
extern int ufs_reconcile_fs(struct vfs *, struct ufsvfs *, int);
extern int ufs_quiesce(struct ulockfs *);
extern int ufs_flush(struct vfs *);
extern int ufs_fiolfs(struct vnode *, struct lockfs *, int);
extern int ufs__fiolfs(struct vnode *, struct lockfs *, int, int);
extern int ufs_fiolfss(struct vnode *, struct lockfs *);
extern int ufs_fioffs(struct vnode *, char *, struct cred *);
extern int ufs_check_lockfs(struct ufsvfs *, struct ulockfs *, ulong_t);
extern int ufs_lockfs_begin(struct ufsvfs *, struct ulockfs **, ulong_t);
extern int ufs_lockfs_begin_getpage(struct ufsvfs *, struct ulockfs **,
struct seg *, int, uint_t *);
extern void ufs_lockfs_end(struct ulockfs *);
/*
* ufs acl stuff
*/
extern int ufs_si_inherit(struct inode *, struct inode *, o_mode_t, cred_t *);
extern void si_cache_init(void);
extern int ufs_si_load(struct inode *, cred_t *);
extern void ufs_si_del(struct inode *);
extern int ufs_acl_access(struct inode *, int, cred_t *);
extern void ufs_si_cache_flush(dev_t);
extern int ufs_si_free(si_t *, struct vfs *, cred_t *);
extern int ufs_acl_setattr(struct inode *, struct vattr *, cred_t *);
extern int ufs_acl_get(struct inode *, vsecattr_t *, int, cred_t *);
extern int ufs_acl_set(struct inode *, vsecattr_t *, int, cred_t *);
/*
* ufs directio stuff
*/
extern void ufs_directio_init();
extern int ufs_directio_write(struct inode *, uio_t *, int, int, cred_t *,
int *);
extern int ufs_directio_read(struct inode *, uio_t *, cred_t *, int *);
#define DIRECTIO_FAILURE (0)
#define DIRECTIO_SUCCESS (1)
/*
* ufs extensions for PXFS
*/
int ufs_rdwr_data(vnode_t *vp, u_offset_t offset, size_t len, fdbuffer_t *fdb,
int flags, cred_t *cr);
int ufs_alloc_data(vnode_t *vp, u_offset_t offset, size_t *len, fdbuffer_t *fdb,
int flags, cred_t *cr);
/*
* prototypes to support the forced unmount
*/
void ufs_freeze(struct ulockfs *, struct lockfs *);
int ufs_thaw(struct vfs *, struct ufsvfs *, struct ulockfs *);
/*
* extended attributes
*/
int ufs_xattrmkdir(inode_t *, inode_t **, int, struct cred *);
int ufs_xattr_getattrdir(vnode_t *, inode_t **, int, struct cred *);
void ufs_unhook_shadow(inode_t *, inode_t *);
#endif /* defined(_KERNEL) && !defined(_BOOT) */
#ifdef __cplusplus
}
#endif
#endif /* _SYS_FS_UFS_INODE_H */