/*- * 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 */ #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 */ /* 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 */ /* 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; \ if (_e = bread((F)->lfs_ivnode, \ ((IN) >> (F)->lfs_sushift) + (F)->lfs_cleansz, \ (F)->lfs_bsize, NOCRED, &(BP))) \ panic("lfs: ifile read: %d", _e); \ (SP) = (SEGUSE *)(BP)->b_data + ((IN) & (F)->lfs_sepb - 1); \ } /* * 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