freebsd-nq/sys/ufs/lfs/lfs.h
Justin T. Gibbs 471e5fa096 John Dyson's patches (and a few from me too) to LFS to use a different
buffering scheme and make it more in tune with FreeBSD's vfs_bio
implementation.  The filesystem seems fairly stable, but I wouldn't recommend
it to anyone not willing to experience problems.  This is very green code and
has the limitation that YOU CAN ONLY HAVE ONE LFS PARTITION MOUNTED AT A TIME.

What LFS is good for:

	Non fsynced writes	FASTER THAN FFS
	Large deletions		Increadibly fast

Reads are a little bit slower than FFS right now, but that is a factor of
how under optimized this code is.  LFS should in theory perform at least as
well as FFS under fsync (iozone) type loads, and this is what I'm currently
working on.

Reviewed by:	Justin Gibbs
Submitted by:	John Dyson
Obtained from:
1994-11-17 01:30:53 +00:00

368 lines
14 KiB
C

/*-
* Copyright (c) 1991, 1993
* The Regents of the University of California. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* @(#)lfs.h 8.3 (Berkeley) 9/23/93
* $Id: lfs.h,v 1.4 1994/10/10 01:04:47 phk Exp $
*/
#ifndef _UFS_LFS_LFS_H_
#define _UFS_LFS_LFS_H_
#define LFS_LABELPAD 8192 /* LFS label size */
#define LFS_SBPAD 8192 /* LFS superblock size */
/*
* XXX
* This is a kluge and NEEDS to go away.
*
* Right now, ufs code handles most of the calls for directory operations
* such as create, mkdir, link, etc. As a result VOP_UPDATE is being
* called with waitfor set (since ffs does these things synchronously).
* Since LFS does not want to do these synchronously, we treat the last
* argument to lfs_update as a set of flags. If LFS_SYNC is set, then
* the update should be synchronous, if not, do it asynchronously.
* Unfortunately, this means that LFS won't work with NFS yet because
* NFS goes through paths that will make normal calls to ufs which will
* call lfs with a last argument of 1.
*/
#define LFS_SYNC 0x02
/* On-disk and in-memory checkpoint segment usage structure. */
typedef struct segusage SEGUSE;
struct segusage {
u_long su_nbytes; /* number of live bytes */
u_long su_lastmod; /* SEGUSE last modified timestamp */
u_short su_nsums; /* number of summaries in segment */
u_short su_ninos; /* number of inode blocks in seg */
#define SEGUSE_ACTIVE 0x1 /* segment is currently being written */
#define SEGUSE_DIRTY 0x2 /* segment has data in it */
#define SEGUSE_SUPERBLOCK 0x4 /* segment contains a superblock */
u_long su_flags;
};
#define SEGUPB(fs) (1 << (fs)->lfs_sushift)
#define SEGTABSIZE_SU(fs) \
(((fs)->lfs_nseg + SEGUPB(fs) - 1) >> (fs)->lfs_sushift)
/* On-disk file information. One per file with data blocks in the segment. */
typedef struct finfo FINFO;
struct finfo {
u_long fi_nblocks; /* number of blocks */
u_long fi_version; /* version number */
u_long fi_ino; /* inode number */
long fi_blocks[1]; /* array of logical block numbers */
};
/* On-disk and in-memory super block. */
struct lfs {
#define LFS_MAGIC 0x070162
u_long lfs_magic; /* magic number */
#define LFS_VERSION 1
u_long lfs_version; /* version number */
u_long lfs_size; /* number of blocks in fs */
u_long lfs_ssize; /* number of blocks per segment */
u_long lfs_dsize; /* number of disk blocks in fs */
u_long lfs_bsize; /* file system block size */
u_long lfs_fsize; /* size of frag blocks in fs */
u_long lfs_frag; /* number of frags in a block in fs */
/* Checkpoint region. */
ino_t lfs_free; /* start of the free list */
u_long lfs_bfree; /* number of free disk blocks */
u_long lfs_nfiles; /* number of allocated inodes */
long lfs_avail; /* blocks available for writing */
u_long lfs_uinodes; /* inodes in cache not yet on disk */
daddr_t lfs_idaddr; /* inode file disk address */
ino_t lfs_ifile; /* inode file inode number */
daddr_t lfs_lastseg; /* address of last segment written */
daddr_t lfs_nextseg; /* address of next segment to write */
daddr_t lfs_curseg; /* current segment being written */
daddr_t lfs_offset; /* offset in curseg for next partial */
daddr_t lfs_lastpseg; /* address of last partial written */
u_long lfs_tstamp; /* time stamp */
long lfs_maxsymlinklen; /* max length of an internal symlink */
/* These are configuration parameters. */
u_long lfs_minfree; /* minimum percentage of free blocks */
/* These fields can be computed from the others. */
u_quad_t lfs_maxfilesize; /* maximum representable file size */
u_long lfs_dbpseg; /* disk blocks per segment */
u_long lfs_inopb; /* inodes per block */
u_long lfs_ifpb; /* IFILE entries per block */
u_long lfs_sepb; /* SEGUSE entries per block */
u_long lfs_nindir; /* indirect pointers per block */
u_long lfs_nseg; /* number of segments */
u_long lfs_nspf; /* number of sectors per fragment */
u_long lfs_cleansz; /* cleaner info size in blocks */
u_long lfs_segtabsz; /* segment table size in blocks */
u_long lfs_segmask; /* calculate offset within a segment */
u_long lfs_segshift; /* fast mult/div for segments */
u_long lfs_bmask; /* calc block offset from file offset */
u_long lfs_bshift; /* calc block number from file offset */
u_long lfs_ffmask; /* calc frag offset from file offset */
u_long lfs_ffshift; /* fast mult/div for frag from file */
u_long lfs_fbmask; /* calc frag offset from block offset */
u_long lfs_fbshift; /* fast mult/div for frag from block */
u_long lfs_fsbtodb; /* fsbtodb and dbtofsb shift constant */
u_long lfs_sushift; /* fast mult/div for segusage table */
#define LFS_MIN_SBINTERVAL 5 /* minimum superblock segment spacing */
#define LFS_MAXNUMSB 10 /* superblock disk offsets */
daddr_t lfs_sboffs[LFS_MAXNUMSB];
/* These fields are set at mount time and are meaningless on disk. */
struct segment *lfs_sp; /* current segment being written */
struct vnode *lfs_ivnode; /* vnode for the ifile */
u_long lfs_seglock; /* single-thread the segment writer */
pid_t lfs_lockpid; /* pid of lock holder */
u_long lfs_iocount; /* number of ios pending */
u_long lfs_writer; /* don't allow any dirops to start */
u_long lfs_dirops; /* count of active directory ops */
u_long lfs_doifile; /* Write ifile blocks on next write */
u_long lfs_nactive; /* Number of segments since last ckp */
u_char lfs_fmod; /* super block modified flag */
u_char lfs_clean; /* file system is clean flag */
u_char lfs_ronly; /* mounted read-only flag */
u_char lfs_flags; /* currently unused flag */
u_char lfs_fsmnt[MNAMELEN]; /* name mounted on */
u_char pad[3]; /* long-align */
u_char pad2[156]; /* Block align */
/* Checksum; valid on disk. */
u_long lfs_cksum; /* checksum for superblock checking */
};
/*
* Inode 0 is the out-of-band inode number, inode 1 is the inode number for
* the IFILE, the root inode is 2 and the lost+found inode is 3.
*/
/* Fixed inode numbers. */
#define LFS_UNUSED_INUM 0 /* out of band inode number */
#define LFS_IFILE_INUM 1 /* IFILE inode number */
#define LOSTFOUNDINO 3 /* lost+found inode number */
#define LFS_FIRST_INUM 4 /* first free inode number */
/* Address calculations for metadata located in the inode */
#define S_INDIR(fs) -NDADDR
#define D_INDIR(fs) (S_INDIR(fs) - NINDIR(fs) - 1)
#define T_INDIR(fs) (D_INDIR(fs) - NINDIR(fs) * NINDIR(fs) - 1)
/* Unassigned disk address. */
#define UNASSIGNED -1
/* Unused logical block number */
#define LFS_UNUSED_LBN -1
typedef struct ifile IFILE;
struct ifile {
u_long if_version; /* inode version number */
#define LFS_UNUSED_DADDR 0 /* out-of-band daddr */
daddr_t if_daddr; /* inode disk address */
ino_t if_nextfree; /* next-unallocated inode */
};
/*
* Cleaner information structure. This resides in the ifile and is used
* to pass information between the cleaner and the kernel.
*/
typedef struct _cleanerinfo {
u_long clean; /* K: number of clean segments */
u_long dirty; /* K: number of dirty segments */
} CLEANERINFO;
#define CLEANSIZE_SU(fs) \
((sizeof(CLEANERINFO) + (fs)->lfs_bsize - 1) >> (fs)->lfs_bshift)
/*
* All summary blocks are the same size, so we can always read a summary
* block easily from a segment.
*/
#define LFS_SUMMARY_SIZE 512
/* On-disk segment summary information */
typedef struct segsum SEGSUM;
struct segsum {
u_long ss_sumsum; /* check sum of summary block */
u_long ss_datasum; /* check sum of data */
daddr_t ss_next; /* next segment */
u_long ss_create; /* creation time stamp */
u_short ss_nfinfo; /* number of file info structures */
u_short ss_ninos; /* number of inodes in summary */
#define SS_DIROP 0x01 /* segment begins a dirop */
#define SS_CONT 0x02 /* more partials to finish this write*/
u_short ss_flags; /* used for directory operations */
u_short ss_pad; /* extra space */
/* FINFO's and inode daddr's... */
};
/* NINDIR is the number of indirects in a file system block. */
#define NINDIR(fs) ((fs)->lfs_nindir)
/* INOPB is the number of inodes in a secondary storage block. */
#define INOPB(fs) ((fs)->lfs_inopb)
#define blksize(fs) ((fs)->lfs_bsize)
#define blkoff(fs, loc) ((loc) & (fs)->lfs_bmask)
#define fsbtodb(fs, b) ((b) << (fs)->lfs_fsbtodb)
#define dbtofsb(fs, b) ((b) >> (fs)->lfs_fsbtodb)
#define lblkno(fs, loc) ((loc) >> (fs)->lfs_bshift)
#define lblktosize(fs, blk) ((blk) << (fs)->lfs_bshift)
#define numfrags(fs, loc) /* calculates (loc / fs->fs_fsize) */ \
((loc) >> (fs)->lfs_bshift)
#define datosn(fs, daddr) /* disk address to segment number */ \
(((daddr) - (fs)->lfs_sboffs[0]) / fsbtodb((fs), (fs)->lfs_ssize))
#define sntoda(fs, sn) /* segment number to disk address */ \
((daddr_t)((sn) * ((fs)->lfs_ssize << (fs)->lfs_fsbtodb) + \
(fs)->lfs_sboffs[0]))
/* Read in the block with the cleaner info from the ifile. */
#define LFS_CLEANERINFO(CP, F, BP) { \
VTOI((F)->lfs_ivnode)->i_flag |= IN_ACCESS; \
if (bread((F)->lfs_ivnode, \
(daddr_t)0, (F)->lfs_bsize, NOCRED, &(BP))) \
panic("lfs: ifile read"); \
(CP) = (CLEANERINFO *)(BP)->b_data; \
}
/* Read in the block with a specific inode from the ifile. */
#define LFS_IENTRY(IP, F, IN, BP) { \
int _e; \
VTOI((F)->lfs_ivnode)->i_flag |= IN_ACCESS; \
if (_e = bread((F)->lfs_ivnode, \
(IN) / (F)->lfs_ifpb + (F)->lfs_cleansz + (F)->lfs_segtabsz,\
(F)->lfs_bsize, NOCRED, &(BP))) \
panic("lfs: ifile read %d", _e); \
(IP) = (IFILE *)(BP)->b_data + (IN) % (F)->lfs_ifpb; \
}
/* Read in the block with a specific segment usage entry from the ifile. */
#define LFS_SEGENTRY(SP, F, IN, BP) { \
int _e; \
VTOI((F)->lfs_ivnode)->i_flag |= IN_ACCESS; \
_e = bread((F)->lfs_ivnode, \
((IN) >> (F)->lfs_sushift) + (F)->lfs_cleansz, \
(F)->lfs_bsize, NOCRED, &(BP)); \
if (_e) \
panic("lfs: ifile read: %d", _e); \
(SP) = (SEGUSE *)(BP)->b_data + ((IN) & (F)->lfs_sepb - 1); \
}
#ifdef CC_WALL
/* The above ^^^^^^^^^^^^^^^^^^^^^^^^^^^
* looks like a potential bug to me.
*/
#endif
/*
* Determine if there is enough room currently available to write db
* disk blocks. We need enough blocks for the new blocks, the current,
* inode blocks, a summary block, plus potentially the ifile inode and
* the segment usage table, plus an ifile page.
*/
#define LFS_FITS(fs, db) \
((long)((db + ((fs)->lfs_uinodes + INOPB((fs))) / INOPB((fs)) + \
fsbtodb(fs, 1) + LFS_SUMMARY_SIZE / DEV_BSIZE + \
(fs)->lfs_segtabsz)) < (fs)->lfs_avail)
/* Determine if a buffer belongs to the ifile */
#define IS_IFILE(bp) (VTOI(bp->b_vp)->i_number == LFS_IFILE_INUM)
/*
* Structures used by lfs_bmapv and lfs_markv to communicate information
* about inodes and data blocks.
*/
typedef struct block_info {
ino_t bi_inode; /* inode # */
daddr_t bi_lbn; /* logical block w/in file */
daddr_t bi_daddr; /* disk address of block */
time_t bi_segcreate; /* origin segment create time */
int bi_version; /* file version number */
void *bi_bp; /* data buffer */
} BLOCK_INFO;
/* In-memory description of a segment about to be written. */
struct segment {
struct lfs *fs; /* file system pointer */
struct buf **bpp; /* pointer to buffer array */
struct buf **cbpp; /* pointer to next available bp */
struct buf **start_bpp; /* pointer to first bp in this set */
struct buf *ibp; /* buffer pointer to inode page */
struct finfo *fip; /* current fileinfo pointer */
struct vnode *vp; /* vnode being gathered */
void *segsum; /* segment summary info */
u_long ninodes; /* number of inodes in this segment */
u_long seg_bytes_left; /* bytes left in segment */
u_long sum_bytes_left; /* bytes left in summary block */
u_long seg_number; /* number of this segment */
daddr_t *start_lbp; /* beginning lbn for this set */
#define SEGM_CKP 0x01 /* doing a checkpoint */
#define SEGM_CLEAN 0x02 /* cleaner call; don't sort */
#define SEGM_SYNC 0x04 /* wait for segment */
u_long seg_flags; /* run-time flags for this segment */
};
#define ISSPACE(F, BB, C) \
(((C)->cr_uid == 0 && (F)->lfs_bfree >= (BB)) || \
((C)->cr_uid != 0 && IS_FREESPACE(F, BB)))
#define IS_FREESPACE(F, BB) \
((F)->lfs_bfree > ((F)->lfs_dsize * (F)->lfs_minfree / 100 + (BB)))
#define ISSPACE_XXX(F, BB) \
((F)->lfs_bfree >= (BB))
#define DOSTATS
#ifdef DOSTATS
/* Statistics Counters */
struct lfs_stats {
int segsused;
int psegwrites;
int psyncwrites;
int pcleanwrites;
int blocktot;
int cleanblocks;
int ncheckpoints;
int nwrites;
int nsync_writes;
int wait_exceeded;
int write_exceeded;
int flush_invoked;
};
extern struct lfs_stats lfs_stats;
#endif
#endif